Changes in the preserved heart that limit the length of preservation.

BACKGROUND: The variability in donor heart viability following preservation is well known and very dependent on the animal model used and the methods of preservation. Using hypothermia (2 to 4 degrees C) with the University of Wisconsin solution and microperfusion (3 microl/g/min) myocardial functional recovery after reperfusion is 50% to 60% after 18 hours of preservation. Many investigators have found the 18-hour preservation barrier for functional recovery of the heart with different experimental protocols. In previous studies, we have found in normothermic global ischemia that with necrosis there was a significant amount of apoptosis. It was therefore the purpose of this study to investigate the importance of apoptosis in heart preservation and determine if this cellular disruption plays a part in limiting heart viability during recovery from preservation. METHODS: Using a heterotopic heart transplant model, myocardial function (end-systolic elastance), high energy phosphate changes, metabolic substrate utilization, electron microscopy to determine degree of injury, and histologic changes that included apoptosis and lamin B(1) analyses were conducted on canine hearts preserved for 18 hours and reperfused for 6 hours. The changes were compared with a control group with no preservation. RESULTS: The 18-hour preserved heart regained approximately 50% to 60% of its original function, with significant decreases in adenosine triphosphate, no irreversible cellular changes (necrosis), and a 6% to 8% increase in apoptotic myocytes with a concomitant 8% decrease in lamin B(1). CONCLUSIONS: Preserved hearts can be maintained for approximately 12 hours with functional recovery near normal. However, approaching 18 hours, there is an attenuated functional response which may be related to the to development of apoptosis.     

A comparative study of Celsior and University of Wisconsin solutions based on 12-hr preservation followed by transplantation in canine models

BACKGROUND: Celsior is a recently developed extracellular-type preservation solution that is effective in organ preservation. This experimental study was designed to compare the effects of Celsior and University of Wisconsin (UW) solutions in myocardial protection, using 12-hour preservation followed by orthotopic transplantation. METHODS: Fourteen pairs of adult mongrel dogs were divided into 2 groups. In the UW group (n = 7), UW solution at 4 degrees C was used for coronary vascular washout and storage following cardiac arrest with glucose-insulin-potassium (GIK) solution. In the Celsior group (n = 7), Celsior solution was used to produce cardiac arrest, for coronary vascular washout, and for storage. After 12-hour cold preservation, orthotopic transplantation was performed under cardiopulmonary bypass (CPB). The rate of recovery (%) of cardiac function of donor hearts was compared 1 and 2 hours after weaning from CPB, and then the transplanted hearts were harvested for histological study. RESULTS: Hemodynamic parameters including cardiac output, left ventricular pressure (LVP), and the maximum rates of positive and negative increase of LVP after transplantation were significantly (p < 0.05) higher in the Celsior group than in the UW group 2 hours after weaning from CPB. The transmission electron microscopic study found that degeneration of the mitochondria in the Celsior group was less extensive than in the UW group. CONCLUSION: Celsior solution enhanced the cardiac function of hearts preserved for 12 hours prior to transplantation compared to UW solution. Our results indicate that Celsior solution is equivalent or superior to UW solution for cardiac preservation.     

Prolonged 24-hour subzero preservation of heterotopically transplanted rat hearts using antifreeze proteins derived from arctic fish

BACKGROUND: Arctic fish survive subzero temperatures by producing a family of antifreeze proteins (AFPs) that noncolligatively lower the freezing temperature of their body fluids. We report 24-hour storage of mammalian hearts for transplantation at subzero temperatures using AFPs derived from arctic fish. METHODS: Forty-two heterotopic transplantations were performed in isoimmune Sprague-Dawley rats. Harvested hearts were retrogradely infused with cold 4 degrees C University of Wisconsin (UW) solution and were preserved in a specialized cooling bath at two target temperatures, 4 degrees C and -1.3 degrees C for 12,18, and 24 hours (6 experiments/group). Preservation solutions were UW alone for the 4 degrees C group, and UW with 15 mg/mL AFP III for the -1.3 degrees C group. After hypothermic storage the hearts were heterotopically transplanted into isoimmune rats. Viability was assessed and graded on a scale of 0 to 6 (0 = no contractions to 6 = excellent contractions). Transplanted hearts were then fixed in vivo and were subject to electron microscopy and histopathologic examination. RESULTS: None of the hearts preserved at -1.3 degrees C in UW/AFP III solution froze. All control hearts preserved at -1.3 degrees C without AFP protection froze and died at reperfusion. Viability of hearts preserved at -1.3 degrees C in UW/AFP III solution was significantly better after 18 hours of preservation, 30 and 60 minutes after reperfusion (median, 5 versus 3 and 6 versus 3, respectively; p < 0.05) and after 24 hours of preservation 30 and 60 minutes after reperfusion (median, 4.5 versus 1.5 and 5 versus 2, respectively; p < 0.05). Histologic and electron microscopy studies demonstrated better myocyte structure and mitochondrial integrity preservation with UW/AFP III solution. CONCLUSIONS: Antifreeze proteins prevent freezing in subzero cryopreservation of mammalian hearts for transplantation. Subzero preservation prolongs ischemic times and improves posttransplant viability.     

A non-heart-beating donor model to evaluate functional and morphologic outcomes in resuscitated pig hearts.

A non-heart-beating donor model was considered to examine whether pig hearts from the abattoir could be resuscitated by whole blood reperfusion. For preservation, machine perfusion using University of Wisconsin (UW) solution was compared with storage on ice. Nineteen hearts from abattoir pigs, harvested 25 +/- 3 min after exsanguination, were harvested and transported to the laboratory. Controls (n = 7) were immediately reperfused with homologous whole pig blood in an isolated heart model for 60 min with monitoring of left ventricular developed pressure (LVDP), contractility, and coronary flow. UW solution hearts (UW, n = 6) were perfused for 4 h with 10 degrees C cold UW solution before blood reperfusion. In the cold storage group (CS, n = 6), the organs were stored for an additional 4 h on ice before blood reperfusion. In all hearts, histology was performed after 60 min of blood reperfusion to evaluate myocardial reperfusion injury. All three groups showed significant increases in LVDP (p <.001), although this functional recovery was earliest in the control group and latest in the UW group. Significant declines were observed for both LVDP and contractility from the peak values in each group to the end of blood reperfusion. Coronary flow increased steadily over the time course for the UW group, whereas in the control and CS groups flow increased during the first 15 min of blood reperfusion and then decreased. In the UW and CS groups, there were significant positive correlations between coronary flow and LVDP (p <.001). Microscopic examination revealed no differences between the three groups. Thus, hearts from an abattoir with 25 min of warm ischemic time can be resuscitated. For storage of these organs, continuous machine perfusion with UW solution is superior to cold storage on ice.     

Fate of hepatocyte and sinusoidal lining cell function and kinetics after extended cold preservation and transplantation of the rat liver

We investigated the chronological profile of graft damage and recovery after liver cold ischemia-reperfusion (I/R) injury, with particular attention to the role of apoptosis on hepatocyte and sinusoidal endothelial cell (SEC) damage. Male Lewis rats underwent rearterialized orthotopic liver transplantation using grafts subjected to a short (University of Wisconsin [UW] solution for 1 hour [UW1h]) and prolonged period (UW16h) of cold preservation. Experiments were performed immediately after preservation and 4 hours, 24 hours, 3 days, and 7 days after reperfusion. At each time, graft function, incidence of apoptotic cells, expression of the epitope recognized by a monoclonal antibody specific to rat SECs (SE-1), and incidence of proliferating cells were estimated. In the UW16h group, the proportion of apoptotic SECs was markedly elevated at 4 hours. The incidence of hepatocyte apoptosis was very low, although massive hepatocyte necrosis was evident at 24 hours. The incidence of proliferating hepatocytes and SECs peaked at 3 days, then returned to normal by 7 days. SE-1 expression was reduced immediately after preservation, followed by a marked reduction at 4 and 24 hours after reperfusion, and expression returned to normal by 7 days. Although SEC apoptosis was induced in the early phase of cold I/R injury, hepatocyte damage developed without the occurrence of apoptosis. Regeneration of both hepatocytes and SECs after cold I/R injury peaked at 3 days and was complete by 7 days, whereas functional recovery of these cell populations was complete 3 days after reperfusion. (Liver Transpl 2002;8:370-381.)     

A Non-Heart-Beating Donor Model to Evaluate Functional and Morphologic Outcomes in Resuscitated Pig Hearts

A non-heart-beating donor model was considered to examine whether pig hearts from the abattoir could be resuscitated by whole blood reperfusion. For preservation, machine perfusion using University of Wisconsin (UW) solution was compared with storage on ice. Nineteen hearts from abattoir pigs, harvested 25 &#45 3 min after exsanguination, were harvested and transported to the laboratory. Controls ( n = 7) were immediately reperfused with homologous whole pig blood in an isolated heart model for 60 min with monitoring of left ventricular developed pressure (LVDP), contractility, and coronary flow. UW solution hearts (UW, n = 6) were perfused for 4 h with 10°C cold UW solution before blood reperfusion. In the cold storage group (CS, n = 6), the organs were stored for an additional 4 h on ice before blood reperfusion. In all hearts, histology was performed after 60 min of blood reperfusion to evaluate myocardial reperfusion injury. All three groups showed significant increases in LVDP ( p < .001), although this functional recovery was earliest in the control group and latest in the UW group. Significant declines were observed for both LVDP and contractility from the peak values in each group to the end of blood reperfusion. Coronary flow increased steadily over the time course for the UW group, whereas in the control and CS groups flow increased during the first 15 min of blood reperfusion and then decreased. In the UW and CS groups, there were significant positive correlations between coronary flow and LVDP ( p < .001). Microscopic examination revealed no differences between the three groups. Thus, hearts from an abattoir with 25 min of warm ischemic time can be resuscitated. For storage of these organs, continuous machine perfusion with UW solution is superior to cold storage on ice.     

Heart preservation in HTK solution: role of coronary vasculature in recovery of cardiac function

BACKGROUND: Poor myocardial tolerance to prolonged cold ischemia remains a major concern in heart transplantation. In this study, we estimated superiority of Histidine-Tryptophan-Ketoglutarate (HTK) over University of Wisconsin (UW) as a cardiac preservation solution. METHODS: Isolated rat hearts were mounted on a Langendorff apparatus to estimate the baseline cardiac function. The hearts were arrested and stored at 4 degrees C in UW and HTK solution for 8 hours, and then reperfused. The aortic flow, coronary flow, cardiac output, rate pressure product, and left ventricular dp/dt in the HTK group recovered significantly more than the UW group. The values of myocardial total adenine nucleotides and the adenosine triphosphate to adenosine diphosphate ratio were higher in the HTK than in the UW group. We also examined coronary vascular responsiveness using left coronary arteries dissected from the rat hearts before flushing, before storage, after storage, and after reperfusion. RESULTS: The maximal relaxation response to acetylcholine was significantly higher in the HTK than in the UW group after reperfusion, although there were no significant differences at each stage before reperfusion. In addition, the endothelium-independent relaxation response to sodium nitroprusside in the HTK group was also well preserved after reperfusion. CONCLUSIONS: These results indicate that HTK is superior to UW solution for cardiac preservation. HTK protects coronary vasculature during preservation, which together with reperfusion might lead to improved functional cardiac recovery following preservation.     

Studies of controlled reperfusion after ischemia. XXIII. Deleterious effects of simulated thrombolysis preceding simulated coronary artery bypass grafting with controlled blood cardioplegic reperfusion

This study tests whether simulated thrombolysis before controlled reperfusion (i.e., simulated coronary artery bypass) causes reperfusion injury that obviates the benefits of subsequent controlled reperfusion and results in unnecessary ventricular arrhythmias. Fifteen dogs underwent acute occlusion of the left anterior descending coronary artery. In 10 dogs we simulated thrombolysis after 1 hour of ischemia (delivering 10% to 15% of control flow at 5 ml/min), followed 1 hour later by either normal blood reperfusion at systemic pressure (to simulate percutaneous transluminal coronary angioplasty) in five dogs or regionally controlled blood cardioplegic reperfusion on bypass in five others to simulate coronary bypass. In five dogs ischemia was prolonged to 2 hours, and the initial reperfusate was blood cardioplegic solution on total vented bypass (to simulate primary coronary bypass). All hearts receiving simulated thrombolysis (100%) after 1 hour of ischemia had reperfusion-induced ventricular fibrillation. All hearts treated by simulated angioplasty recovered regional contractility (56% of control systolic shortening), whereas there was no (0%) recovery of spontaneous contractility after subsequent blood cardioplegic reperfusion, and only two (40%) dogs had contractile reserve capacity (6% +/- 49%). Conversely, surgically controlled blood cardioplegic reperfusion without preceding low-flow normal blood reperfusion after 2 hours of ischemia resulted in no ventricular arrhythmias (0%; p less than 0.05 versus simulated coronary artery bypass after simulated thrombolysis), 72% +/- 7% (p less than 0.05 versus simulated coronary artery bypass after simulated thrombolysis) recovery of regional contractility (ultrasonic crystals), and 114% +/- 11% (p less than 0.05 versus simulated coronary artery bypass after simulated thrombolysis) recovery of contractile reserve with calcium chloride stimulation. We conclude that controlled reperfusion (simulating coronary artery bypass) with blood cardioplegic solution produces immediate functional recovery and avoids the ventricular fibrillation that follows simulated thrombolysis despite the need for prolonged ischemic time. Preceding controlled reperfusion by normal blood reperfusion (simulated thrombolysis) shortens the ischemic time but nullifies immediate functional recovery possible by simulated coronary bypass and produces unnecessary arrhythmias.     

Improved preservation of the rat liver for orthotopic liver transplantation: use of University of Wisconsin-lactobionate solution and retrograde reflushing

This study investigated cold preservation and reflushing before orthotopic liver transplantation by examining (1) new University of Wisconsin solution (UW) versus Euro-Collins solution (EC), (2) retrograde reflushing (RR) versus antegrade reflushing (AR), and (3) the addition of a platelet-activating inhibitor (PAF), superoxide disumatase (SOD), or SOD + catalase to UW. Syngeneic, male Lewis rats (200 to 400 gm) were used. Preservation for 9, 12, 18, or 24 hours in UW or EC with RR (through the inferior vena cava) was used. The 9- and 12-hour groups experienced a significant decrease in the weight of the grafts preserved in UW. The 3-week survival rate after 9 hours of preservation (n = 6) in UW was 66%, and the survival rate with EC was 0% (p less than 0.025). After 12 hours of preservation, recipient survival rate was 70% (n = 10) with UW versus 0% (n = 4) with EC (p less than 0.025). RR of the graft with cold lactated Ringer's solution immediately before reimplantation significantly improved 3-week survival in the 12-hour group to the level of the control group (no preservation time, 69%). Preservation for 12 hours in UW followed by AR yielded a 3-week survival of 14%; 3-week survival for the RR group was 70% (p less than 0.025). Furthermore, RR allowed a 3-week survival of 33% and 20% after 18 and 24 hours of UW preservation, respectively. In the 24-hour RR/UW group, donor pretreatment with SRI 63-441 (20 mg/kg, intravenously) and recipient treatment with SOD (15 mg/kg, intravenously) or SOD + catalase (15 mg/kg and 5000 units/kg, intravenously) produced a 3-week survival comparable to preservation in UW followed by RR alone. These studies show that UW is a profound improvement over EC for cold preservation of liver and that the new application of RR to rat orthotopic liver transplantation improves survival. However, the addition of free-radical scavengers or PAF does not improve organ function or recipient survival in this model.     

Lipid peroxidation in ischemia-reperfusion oxidative injury of the graft preserved in Celsior and University of Wisconsin solutions on a pig pancreas transplantation model

BACKGROUND: Graft pancreatitis (GP) is one the main technical problems associated with pancreas transplant (PT). It occurs in 20% of patients representing a risk factor for thrombosis and cause of graft loss. GP is related to oxidative effects from oxygen-derived free radicals (OFR) in ischemia-reperfusion injury. We evaluated lipid peroxidation by the OFR in the PT of pig organs preserved with either Celsior or Wisconsin solutions. METHODS: In Landrace pigs we performed 24 pancreas allografts, which were preserved 18 or 24 hours: 12 with Celsior solution (CS) and 12 with Wisconsin solution (UW). No immunosuppression was administered. The oxidative effects were determined by quantification of malondialdehyde (MDA) and 4-hydroxyalkenals (4-HDA) and of the carbonyl groups of proteins in our pancreatic tissue samples and measured at different times: (A) baseline in the donor, (B) after perfusion of the graft, (C) after the ischemia period, and (D) 30 minutes after ischemia-reperfusion of the graft. RESULTS: The MDA and 4-HDA values were similar in conditions A, B, and C, but showed an extraordinary increase after ischemia-reperfusion in D, among both the 18- or 24-hour preserved grafts and in the same proportion with CS and UW. The carbonyl groups of the proteins rose in conditions B and C (cold ischemia), but less so in state D (reperfusion). CONCLUSIONS: The oxidative injury of a pancreatic graft preserved for 18 or 24 hours occurs during reperfusion, with an extraordinary intensity, but similarly with CS and UW, an observation that may help to explain graft pancreatitis.     

Sodium–hydrogen inhibitor cariporide (HOE 642) improves in situ protection of hearts from non–heart-beating donors

BACKGROUND: Reperfusion injury is a vital problem in non-heart-beating donor (NHBD) organs. The sodium-hydrogen inhibitor cariporide is thought to improve cellular integrity after ischemia and reperfusion. Recently, we demonstrated the possibility of preserving hearts with in situ perfusion after circulatory death. The purpose of this study was to determine whether cariporide improves in situ heart protection. METHODS: We studied 20 pigs (18 +/- 2 kg). Hearts in the conventional group (CON, n = 6) underwent cardioplegic arrest with University of Wisconsin solution and then were explanted and stored for 150 minutes on ice. In the other groups, a catheter was placed in each ascending aorta and right atrium. After disconnecting the ventilator, hypoxia caused circulatory arrest within 7 +/- 2 minutes. The aorta was endoclamped, and continuous in situ perfusion of the aortic root was maintained for 60 minutes with University of Wisconsin solution (UW, n = 7) or with UW solution and cariporide (CAR, n = 7). After explantation, the hearts were stored on ice for 90 minutes. In all groups, hearts were reperfused with homologous, whole pig blood in an isolated working heart model for 45 minutes. We monitored stroke-work index on-line, intermittently measured troponin I and malondialdehyde, and compared light microscopic examinations among the groups. RESULTS: Stroke-work index was higher in the CAR group compared with the UW group during the last 20 minutes of reperfusion (10(3)dynes x cm x beats(-1)x gm(-1), 6.6 +/- 1.4 vs 4.5 +/- 2.0, p < 0.05), troponin I was lower in the CAR group compared with the UW group (161 +/- 32 ng/ml vs 277 +/- 35 ng/ml, p < 0.05). Results of malondialdehyde and light microscopic examinations were slightly better in the CAR group, without reaching statistical significance. CONCLUSION: Cariporide as an additive to UW solution improves functional recovery and decreases myocardial damage in hearts from NHBDs protected with an in situ perfusion technique.     

A novel bisindolylmaleimide derivative enhances functional recovery of heart after long-term hypothermic heart preservation

BACKGROUND: Functional recovery following heart transplantation mainly depends on the ability of preservative solution in providing the physical and biochemical environment so as to maintain the viability of the tissue during preservation and in reperfusion. Here we demonstrate the protective effects of a novel bisindolylmaleimide derivative, MS1, on enhancing the functional recovery of the heart following long-term hypothermic preservation when added to the preservative solution. METHODS: After anesthesia and artificial ventilation, the hearts were rapidly isolated and perfused with Kreb's Henseleit buffer at 37 degrees C in working mode. After 30 minutes of perfusion, the hearts were arrested with cardioplegic solution and preserved in University of Wisconsin solution with (UW-MS1 group) or without MS1 (UW-Vehicle group) for 12 h at 4 degrees C. After 12 hours, the hearts were reperfused for 60 minutes. RESULTS: MS1 treated hearts showed: a) significant recovery of cardiac functions (P<0.001), b) well-preserved myocardial ATP levels (P<0.001), c) less myocardial water content (P<0.01), d) reduced oxidative stress (P<0.001), e) less intracellular swelling and well-preserved mitochondria, and g) activation of cell survival cascades compared to the control hearts preserved in UW solution without MS1. In contrast, these protective effects of MS1 were abolished on opening the permeability transition pore before MS1 treatment. CONCLUSION: These results altogether indicate the efficacy of this compound in protecting the myocardium against reperfusion injury and thus making this drug a clinically useful tool in patients undergoing reperfusion after cardiac surgeries.     

The effect of short-term coronary perfusion using oxygenated diluted blood following cold storage for long-term heart preservation

BACKGROUND: The aim of this study was to compare the results obtained from the use of both University of Wisconsin (UW) solution and diluted blood in short-term coronary perfusion following 12-hour cold storage. METHODS: Following coronary vascular washout of adult mongrel dogs with the UW solution, the heart was excised and immersed in a cold (4 degrees C) UW solution for 12 hours followed by 1-hour of coronary perfusion. Two different solutions were used for the coronary perfusion; a 4 degrees C oxygenated UW solution (Group U, n=7) and 15 degrees C oxygenated diluted blood (Group B, n=7). Myocardial high energy phosphate (HEP) levels, tissue water content (TWC), interstitial tissue space (ITS) rates and histological findings were evaluated at 0- and 12-hour cold storage and also following coronary perfusion. The preserved graft was then evaluated through orthotopic transplantation. The control group in this experiment consisted of seven hearts transplanted after 12-hour cold storage without coronary perfusion. RESULTS: Myocardial HEP levels significantly decreased after 12-hour cold storage. The recovery rate of myocardial HEP levels after coronary perfusion was significantly (p<0.05) higher in Group B than in Group U. The increase of myocardial TWC during coronary perfusion was significantly (p<0.01) higher in Group B than in Group U. After 1-hour coronary perfusion, the subendocardial ITS rate was significantly (p<0.01) higher compared with the value at 0-hour cold storage in Group U, whereas it demonstrated no significant change in Group B. PAS stain revealed the glycogen content of the subendocardial tissues was higher in Group B than in Group U. The recovery rate of hemodynamic parameters 2 hours after heart transplantation was higher in Group U and significantly (p<0.05) higher in Group B than in the control. CONCLUSIONS: Myocardial HEP levels recovered significantly after additional coronary perfusion. Though the UW solution prevented myocardial cellular edema, subendocardial perfusion was incomplete and the recovery rate of myocardial HEP levels was lower, suggesting that diluted blood may become the solution of choice as a perfusate.     

The optimal pressure for initial flush with UW solution in heart procurement.

OBJECTIVE: University of Wisconsin (UW) solution is widely used in organ preservation. Some investigators have reported that high pressure during initial flush with UW solution may induce vasoconstriction and endothelial damage, because of its high potassium content and high viscosity. However, using lower pressure during the initial flush may lead to irregular distribution of the solution and incomplete flushing of blood components from coronary vascular beds. This experimental study evaluated the effects of a range of initial flush pressures during heart procurement, followed by orthotopic transplantation of the graft after 12 hours of preservation. MATERIALS AND METHODS: Twelve pairs of adult mongrel dogs, weighing 9 to 14 kg, formed the recipient-donor combinations. After determining hemodynamic status by measuring cardiac output, left ventricular pressure (LVP), and maximum positive and negative change in LVP (+/-LVdP/dt), donor hearts were excised. Coronary vascular beds were flushed with 4 degrees C UW solution at a pressure of 60 mm Hg in the low-pressure group (n = 6) and at 120 mm Hg in the high-pressure group (n = 6). After 12 hours of cold preservation, orthotopic transplantation was performed using cardiopulmonary bypass (CPB). The hemodynamics of the transplanted graft were assessed by comparing recovery rates (%) from donor hearts 2 hours after weaning from CPB. Endothelin-1 (ET-1) levels were measured in the blood obtained from the coronary sinus 30 minutes after reperfusion. The transplanted grafts were then harvested for histologic study and measurement of adenosine triphosphate (ATP) content. RESULTS: Cardiac output, LVP, LVdP/dt and myocardial tissue ATP content were significantly better (p < 0.05) in the high-pressure group than in the low-pressure group. We found no significant differences in ET-1 levels between the groups. Transmission electron microscopic findings revealed that degeneration of the mitochondria was less extensive in the high-pressure group than in the low-pressure group. We observed no obvious ultrastructural damage to the endothelial cells in either group. CONCLUSION: When using UW solution in heart procurement, high pressure is better to completely wash out the blood components and distribute the solution.     

Brain death-related energetic failure of the donor heart becomes apparent only during storage and reperfusion: an ex vivo phosphorus-31 magnetic resonance spectroscopy study on the feline heart.

BACKGROUND AND OBJECTIVE: Recently, we have shown, by using localized in vivo phosphorus-31 magnetic resonance spectroscopy (31P MRS) of the anterior left ventricular wall, that brain death (BD) is not associated with reduced myocardial energy status. In this study, we applied ex vivo 31P MRS of the entire heart to study the effects of BD on the energy status of the feline donor heart following explantation. METHODS: We used cats (6 BD and 6 controls [C]) in a 26-hour protocol. After 2 hours of preparation, we induced BD by filling an intracranial balloon at t = 0 hour. At t = 6 hours, the hearts were arrested with St. Thomas' Hospital cardioplegic solution, explanted, and stored in the same solution at 4 degrees C in a 4.7 Tesla magnet for 17 hours. Subsequently, the hearts were reperfused in the Langendorff mode at 38 degrees C for 1 hour. The first 5-minute 31P MRS spectrum was obtained 1 hour after crossclamping the aorta; we obtained subsequent spectra every hour during storage and every 5 minutes during reperfusion. At the end, the hearts were dried and weighed. Phosphocreatine (PCr), gamma-adenosine triphosphate (gamma-ATP), inorganic phosphate (Pi), and phosphomonoesters (PME), were expressed per g dry heart weight. The intracellular pH (pH(i)) and the PCr/ATP ratio were calculated. RESULTS: During storage, we identified a significant but similar decrease of pH(i), PCr/ATP ratio, and PCr in both groups. During reperfusion, pH(i) and PCr/ATP ratio recovered similarly in both groups, whereas the recovery of PCr in the BD group was significantly lower (p < 0.05). The Pi and PME increased in both groups during storage but to a lesser extent in the BD group (p < 0.05). This difference disappeared during reperfusion. The gamma-ATP was already significantly lower in the BD group at the onset of storage, and this remained so throughout storage and reperfusion (p < 0.05 vs C). Contractile capacity was lost in all hearts, except for 1 heart in the BD group. CONCLUSION: Brain death-related failure of the energetic integrity of the feline donor heart becomes apparent only when using 31P MRS during ischemic preservation and subsequent reperfusion.     

Lazaroid U74389G ameliorates ischemia-reperfusion injury in the rat lung transplant model.

We investigated the effect of Lazaroid U74389G on ischemia-reperfusion injury in the rat orthotopic left lung transplantation model. Five groups of reperfused lungs were studied. In group I, donor lungs were transplanted after 12 hours of preservation in University of Wisconsin (UW) solution at 4C. In groups II, III, and IV, Lazaroid was intravenously administrated at a dose of 1 mg/kg, 8 mg/kg, and 15 mg/kg, respectively, to the donors 30 minutes before preservation and also to the recipients 30 minutes before reperfusion after 12 hours of storage in UW solution at 4C. In group V, Lazaroid was added to the UW solution (80 micromol/l), and also was administered intravenously (6 mg/kg) 30 minutes before reperfusion. After 1 hour of reperfusion, gas exchange function and tissue lipid peroxide levels were significantly improved in Lazaroid-treated groups III, and V compared with no treatment group I. Histologic damage was less severe in groups III, IV, and V than in group I. These findings suggest that Lazaroid U74389G ameliorates ischemia-reperfusion injury in the rat lung transplants by inhibiting lipid peroxidation, regardless of whether it is administrated intravenously or given as an additive to the preservation solution.     

超极化心脏保存液对离体大鼠心脏低温保存的保护作用

目的　探讨含K 通道开放剂的心脏保存液(HCS液)对大鼠离体心脏的保存作用。方法　将24只SD大鼠随机平均分为 3 组,分别用 HCS液、UW液、K H液对心脏进行保存。采用Langendorff心脏灌注和工作模型装置进行心脏功能测定,比较 24h后心功能恢复率以及细胞酶学、心肌含水量、pH值变化和能量变化,观察心肌超微结构改变。结果　心脏保存24 h后, K H组左心室功能损伤严重,UW组及HCS组左心室功能损伤较轻。HCS组冠状动脉流量(CF)恢复率较 K H组、UW组好;HCS组冠脉回流液中乳酸脱氢酶(LDH)、磷酸肌酸激酶(CPK)含量及心肌含水量与UW组比较,差异无统计学意义;HCS组 pH值变化最小, ATP含量最高;HCS组心脏复跳时间与UW组基本相同; HCS组心肌保存良好。结论　HCS保存液对大鼠心脏的保存在 24 h内有明显的保护作用,心脏功能恢复率能达到UW液的水平,在能量保护、改善酸中毒方面则优于UW液。     

Optimized cardiac graft preservation: a comparative experimental study using P-31 magnetic resonance spectroscopy and biochemical analyses.

BACKGROUND: The University of Wisconsin (UW), St. Thomas (ST) and Broussais (B) solutions were compared to the CRMBM solution, that we developed for long term heart preservation. METHODS: Isolated isovolumic rat hearts were arrested with each cardioplegic solution (n = 5) to 8 hearts in each group), submitted to 12 hours of cold storage (4 degrees C) in the same solution and then reperfused for 60 minutes at 37 degrees C. Function was measured during control and reflow. High energy phosphates and intracellular pH were monitored by P-31 magnetic resonance spectroscopy. Analyses were performed by biochemical assays and HPLC in coronary effluents (CK, Pi, lactate, purines) and in freeze-clamped hearts (amino acids, nucleotides, CK, LDH) at the end of reperfusion. RESULTS: Functional recovery was significantly improved with the new cardioplegic solution (50+/-12% recovery for the rate pressure product at the end of reflow vs 8+/-3% with UW, 0% with B and with ST). This result was correlated with the best metabolic and cellular protection as assessed in particular by higher PCr levels during reflow (30+/-3% vs 10+/-3% with UW, 8+/-4% with B, and 7+/-1% with ST) as well as reduced creatine kinase leakage during reflow (110+/-15 IU/60 minute vs 270 +/- 57 IU/60 minute with UW, 323+/-36 IU/60 minute with Broussais solution and 237+/-18 IU/60 minute with ST). CONCLUSION: This new solution is more effective in prolonged myocardial protection than the three most widely used solutions.     

Endothelium-dependent relaxation of canine pulmonary artery after prolonged lung graft preservation in University of Wisconsin solution: role of L-arginine supplementation.

BACKGROUND: The University of Wisconsin (UW) solution has been demonstrated to enhance pulmonary allograft preservation. Endothelial nitric oxide (NO) production has been shown to be significantly impaired after ischemia and reperfusion (I/R) injury. The present experiments aimed to determine the protective effects of pulmonary endothelium-dependent function by using supplemental NO in University of Wisconsin (UW) solution following prolonged lung graft preservation. METHODS: Thirty-six healthy mongrel dogs underwent thoracotomy to expose the left lung. In addition to a group given UW solution (n = 4), 100 micromol/liter l-arginine, (n = 7), 100 micromol/liter N(G)-monomethyl-l-arginine (l-NMMA n = 7) and 1.0 micromol/liter 3-morpholinosydnonimine (SIN-1, n = 18 respectively, were added to UW solution, and infused from the aortic root and pulmonary artery to the pulmonary vein. The perfused lung was then allowed to inflate to its maximum volume for 24-hour oxygenated preservation in each supplemented condition of UW solution at 4 degrees C. In the SIN-1 group, the preservation period was further divided into 8 hours and 16 hours, respectively. Rings of the third-order pulmonary artery of the inflated lung were then suspended in organ chambers to measure isometric force. RESULTS: Endothelium-dependent relaxation (EDR) to acetylcholine, adenosine diphosphate and sodium fluoride of the pulmonary rings in the l-arginine group was significantly preserved compared with UW-solution-only group. The l-NMMA group showed significant EDR impairment after 24-hour preservation compared with the UW solution group. Similar to the l-arginine group, the SIN-1 group showed significant EDR protection with 8-hour preservation, but not with 24-hour preservation. In contrast, EDR to calcium ionophore A23187 showed no EDR changes after 24-hour preservation in any of the supplemented groups. CONCLUSIONS: Supplemental l-arginine in UW solution ameliorates impaired pulmonary EDR following prolonged lung preservation of up to 24 hours.     

Improved myocardial ischemic tolerance by contractile inhibition with 2,3-butanedione monoxime.

Contracture of the arrested myocardium during prolonged storage of the heart results in both systolic and diastolic dysfunction, and is a major limitation to extended preservation. We studied the effects of a reversible contractile inhibitor, 2,3-butanedione monoxime (BDM), on myocardial ischemic tolerance. Isolated rabbit hearts were flushed with University of Wisconsin (UW) solution with and without 30 mmol/L BDM and 1 mmol/L CaCl, stored at 4 degrees C for 24 hours, and subsequently reperfused for 60 minutes. Left ventricular pressure-volume relationships and adenine nucleotide content were determined before reperfusion. Left ventricular systolic pressure, diastolic volume, and adenine nucleotide content were measured after reperfusion. Hearts stored in UW solution underwent contracture and adenosine triphosphate (ATP) depletion during storage, and exhibited systolic dysfunction, impaired diastolic relaxation, and poor ATP regeneration upon reperfusion. The addition of calcium worsened contracture and ATP depletion (p < 0.005) and slightly improved function and ATP regeneration (p = not significant). Hearts stored in the presence of BDM experience no contracture during storage; ATP was preserved (10.7 versus 15.7 nmol/mg; p < 0.05), and left ventricular systolic pressure and ATP content recovered to 74% and 93% of control on reperfusion, respectively (p < 0.005). Left ventricular diastolic volume remained depressed, however, although less than with UW solution (0.87 versus 0.45 mL; p < 0.001). When both BDM and calcium were included in the UW solution, calcium-stimulated ATP hydrolysis and contracture were prevented, left ventricular systolic pressure returned to 87% of control, and left ventricular diastolic volume and ATP content returned to control levels.(ABSTRACT TRUNCATED AT 250 WORDS)