Reduced tolerance of global ischemia in the hypertrophied heart

OBJECTIVE: Reduced coronary reserve during reperfusion may cause postischemic diastolic dysfunction in pressure-overload-induced hypertrophy. We studied the effect of coronary flow regulation (simulated hyperemic or depressed flow) on postischemic cardiac function during reperfusion. METHODS: Left ventricular pressure overload was induced in 4-week-old rats by abdominal aortic constriction. At 6 weeks of age, isolated Langendorff-perfused hearts (perfusion pressures: 75 mmHg in controls and 110 mmHg in the aortic constriction group) were subjected to hypothermic global ischemia (15 degrees C, 210 min), followed by 2 types of coronary flow regulation during the initial 20 min of reperfusion--manipulated high flow in control hearts (group I), manipulated low flow in control hearts (group II), manipulated high flow in aortic constriction hearts (group III), and manipulated low flow in aortic constriction hearts (group IV) (n = 6/group), and then constant pressure perfusion during the subsequent 45 min of reperfusion. Cardiac function was measured using an isovolumic balloon in the pre- and postischemic periods. RESULTS: Aortic constriction hearts exhibited greater left ventricular end-diastolic pressure than did control hearts. The increase in left ventricular end-diastolic pressure did not differ between group I (3 +/- 2 mmHg) and group II (-1 +/- 1 mmHg) or between group III (29 +/- 5 mmHg) and group IV (30 +/- 6 mmHg). No difference was seen in postischemic recovery of left ventricular systolic pressure between high and low flow groups in control and aortic constriction hearts. CONCLUSION: Manipulations in coronary flow during reperfusion did not affect postischemic cardiac function in control or aortic constriction hearts, suggesting that depressed coronary flow during early reperfusion is not a primary cause of postischemic diastolic dysfunction in the hypertrophied myocardium.     

Oxygen-derived free radical scavengers for amelioration of reperfusion damage in heart transplantation

In this study we tried to define the possible benefits of the oxygen-derived free radical scavengers after 3 hours of cold myocardial global ischemia, as required in the setting of cardiac transplantation. Twenty-one pig hearts were harvested after preservation with a cold cardioplegic solution (St. Thomas' Hospital solution) and topical cooling. Normothermic reperfusion with blood was achieved with a special heart-lung machine preparation, which allows the heart to beat in a working or nonworking mode. Twelve hearts served as control hearts (group I), and nine (group II) were subjected to superoxide dismutase and catalase. Superoxide dismutase was applied at a dose of 40 U/ml of cardioplegic solution and 1500 U/kg body weight with the start of reperfusion. Catalase was added to the cardioplegic solution in a dose of 100 U/kg and 3500 U/kg body weight with the start of reperfusion. After 15 minutes of retrograde reperfusion, both left ventricular developed pressure and its first derivative were significantly higher in group II (137 +/- 7.6 mm Hg, 2467 +/- 162 mm Hg/sec) than in group I (105 +/- 6 mm Hg, 1676 +/- 231 mm Hg/sec, p less than 0.05 for each). In addition, a considerably higher coronary blood flow was observed in group II throughout the 180-minute period of reperfusion (p = 0.047). We therefore conclude that the combined administration of superoxide dismutase and catalase during the initial period of cardioplegic arrest and during early reperfusion of donor hearts submitted to 3 hours of cold ischemia has a beneficial effect on myocardial performance.     

Effects of potassium cardioplegia on high-energy phosphate kinetics during circulatory arrest with deep hypothermia in the newborn piglet heart

The protective effects of hypothermia and potassium-solution cardioplegia on high-energy phosphate levels and intracellular pH were evaluated in the newborn piglet heart by means of in vivo phosphorus nuclear magnetic resonance spectroscopy. All animals underwent cardiopulmonary bypass, cooling to 20 degrees C, 120 minutes of circulatory arrest, rewarming with cardiopulmonary bypass, and 1 hour off extracorporeal support with continuous hemodynamic and nuclear magnetic resonance spectroscopic evaluation. Group I (n = 5) was cooled to 20 degrees C; group II (n = 4) was given a single dose of 20 degrees C cardioplegic solution; group III (n = 7) was given a single dose of 4 degrees C cardioplegic solution; and group IV (n = 4) received 4 degrees C cardioplegic solution every 30 minutes. At end ischemia, adenosine triphosphate, expressed as a percent of control value, was lowest in group I 54% +/- 6.5% but only slightly greater in group II 66% +/- 7.0%. Use of 4 degrees C cardioplegic solution in groups III and IV resulted in a significant decrease in myocardial temperature, 9.9 degrees C versus 17 degrees to 20 degrees C, and significantly higher levels of adenosine triphosphate at end ischemia; with group III levels at 72% +/- 6.0% and group IV levels at 73% +/- 6.0%. Recovery of adenosine triphosphate with reperfusion was not related to the level of adenosine triphosphate at end ischemia and was best in groups I and II, with a recovery level of 95% +/- 4.0%. In group IV, no recovery of adenosine triphosphate occurred with reperfusion, resulting in a significantly lower level of adenosine triphosphate, 74% +/- 6.0%, than in groups I and II. Recovery of ventricular function was good for all groups but was best in hearts receiving a single dose of 4 degrees C cardioplegic solution. In this model, multiple doses of cardioplegic solution were not associated with either improved adenosine triphosphate retention during arrest or improved ventricular function after reperfusion, and in fact resulted in a significantly lower level of adenosine triphosphate with reperfusion. The complete recovery of adenosine triphosphate in groups I and II, despite a nearly 50% adenosine triphosphate loss during ischemia, may result from a decrease in the catabolism of the metabolites of adenosine triphosphate consumption in the newborn heart.     

Successful transplantation after long-term preservation of dog hearts.

Nucleoside transport inhibition is a new approach to long-term preservation of donor hearts. To evaluate its effectiveness, the following were tested: 1) the effect of nucleoside transport inhibition on high-energy phosphate content after cardioplegic arrest and during long-term cold storage (group I: cardioplegia, control ]n = 18]; group II: cardioplegia plus nucleoside transport inhibitor [n = 18]); 2) the effect of nucleoside transport inhibition on high-energy phosphates and hemodynamic recovery in a modified blood-perfused Langendorff system (group III: 24-h cold storage followed by reperfusion [n = 6]; group IV: addition of nucleoside transport inhibition to cardioplegia but not during reperfusion [n = 6]; group V: addition of nucleoside transport inhibition during reperfusion [n = 6]; group VI: addition of nucleoside transport inhibition to cardioplegia and during reperfusion [n = 6]); and 3) the effect of nucleoside transport inhibition added to cardioplegia and during reperfusion on high-energy phosphate content and outcome after heart transplantation (group VII: no nucleoside transport inhibitor in cardioplegia and during reperfusion [n = 8]; group VIII: addition of nucleoside transport inhibition to cardioplegia and during reperfusion [n = 8]). The following results were obtained: 1) addition of nucleoside transport inhibition prevented high-energy phosphate depletion during cold storage: after 24 h, adenosine triphosphate content in group I was 9.4 +/- 3.1 mumol/g versus 17.7 +/- 3.6 mumol/g dry weight in group II (P less than 0.05); 2) addition of nucleoside transport inhibition to cardioplegia and during reperfusion resulted in greater high-energy phosphate content (adenosine triphosphate in group III was 7.9 +/- 3.5 mumol/g vs. 17.8 +/- 2.8 mumol/g in group VI [P less than 0.05]) and improved hemodynamics upon reperfusion (hearts in group III did not recover, maximum isometric left ventricular pressure development was 1,635 +/- 577 mmHg/sec in group IV, 1,915 +/- 423 mmHg/sec in group V, and 2,437 +/- 201 mmHg/sec in group VI [P less than 0.05, group VI vs. groups IV and V]); and 3) hearts treated with nucleoside transport inhibition in cardioplegia and during reperfusion (group VIII) could be transplanted successfully in contrast to group VII hearts. These data indicate that nucleoside transport inhibition in dogs is highly effective in long-term preservation of donor hearts.     

Improved energy preservation following gentle reperfusion after hypothermic, ischemic cardioplegia in infarcted rat hearts

The influence of temperature and pressure during early reperfusion after 2 h of hypothermic, cardioplegic ischemia was investigated. Adenosine triphosphate (ATP) and creatinephosphate (CP) were measured after 45-min reperfusion. The experiments were carried out in normal and previously infarcted rat hearts (the left coronary artery having been ligated 3 weeks carlier). Four groups, each containing six hearts, were studied. Group 1 consisted of normal hearts reperfused with an abrupt rise in temperature and pressure, group 2 of normal hearts exposed to slowly rising temperature and pressure, and group 3 and 4 of previously infarcted hearts. Reperfusion procedures in groups 3 and 4 were the same as in group 1 and 2, respectively. The study showed that previously infarcted hearts have a lowered tolerance to ischemia and that the reperfusion technique may influence the preservation of myocardial energetics, although this influence was not statistically significant in normal hearts following only 2 h of ischemia. The gently reperfused infarcted hearts had energy stores equal to the normal hearts after 2 h of ischemia and 45 min of reperfusion, whereas the infarcted hearts reperfused in a rougher mode had significantly lowered values (P<0.05 for ATP and P<0.01 for CP).     

Response of hypertrophied myocardium to ischemia: correlation with biochemical and physiological parameters

The increased susceptibility of hypertrophied hearts to ischemic injury during cardiac operations has long been recognized. Although the imbalances in oxygen supply and demand which may occur with hypertrophy during hypotension, ventricular fibrillation, or reperfusion have been extensively studied, the biochemical response of hypertrophied myocardium to ischemia has not been fully elucidated. In the present investigation, rat hearts in which hypertrophy was induced by chronic pressure overload were used to examine the relationship of the physiological parameter, ischemic contracture, to high-energy phosphate content and mitochondrial function during global ischemia. Hypertrophied hearts developed ischemic contracture after significantly shorter duration of ischemia than did normal hearts (5.8 +/- 0.3 minutes versus 10.1 +/- 0.7 minutes). High-energy phosphate content was lower in hypertrophied hearts at control and at ischemic contracture initiation and completion than in normal hearts, whereas mitochondrial function was consistently greater in the hypertrophy group. This investigation demonstrates that the hypertrophied myocardium, independent of flow-related events, is more vulnerable to ischemic injury than normal myocardium and suggests that the increased susceptibility may result from lower high-energy phosphate stores present at the onset of ischemia. The results emphasize the need for rapid cardiac arrest with the induction of ischemia in hypertrophied myocardium and suggest the potential for increasing myocardial high-energy phosphate content in the hypertrophied ventricle by interventions such as arrested perfusion with substrate containing oxygenated cardioplegic solutions prior to the onset of planned ischemia.     

Adverse effects of low-pressure reperfusion after hypothermic cardioplegia in normal and hypertrophic hearts.

The aim of this study was to determine the effect of low-pressure and high-pressure reperfusion, with and without ventricular fibrillation, on the recovery of hypertrophic and normal hearts after hypothermic cardioplegia. Fourteen hearts rendered hypertrophic by valvular aortic stenosis and 18 normal canine hearts were subjected to 1 hour of cardioplegic arrest at 28 degrees C during cardiopulmonary bypass. Each heart was then reperfused at a coronary pressure of either 40 mm Hg (low) or 80 mm Hg (high), initially in the empty beating state and then during ventricular fibrillation. Low-pressure reperfusion produced left ventricular subendocardial ischemia in hypertrophic and in normal hearts, shown by marked depression of subendocardial blood flow, myocardial pH, and myocardial oxygen consumption. In hypertrophic hearts the ischemia was more severe and resulted in a persistent depression of left ventricular function and myocardial oxygen consumption even when coronary pressure was returned to normal levels. High-pressure reperfusion was associated with rapid and complete recovery of myocardial metabolism and function in hypertrophic and in normal hearts. During low-pressure reperfusion, ventricular fibrillation exacerbated ischemia in hypertrophic and in normal hearts. During high-pressure reperfusion, a short period of ventricular fibrillation produced no adverse effects either in hypertrophic or in normal hearts. We conclude that low-pressure reperfusion produces subendocardial ischemia in normal and in hypertrophic hearts even in the empty beating state; in hypertrophic hearts it also impairs recovery of myocardial metabolism and function. The adverse effects of low-pressure reperfusion are exacerbated by ventricular fibrillation.     

Protection of the hypertrophied pig myocardium. A comparison of crystalloid, blood, and Fluosol-DA cardioplegia during prolonged aortic clamping

The myocardial protective effects of crystalloid, blood, and Fluosol-DA-20% cardioplegia were compared by subjecting hypertrophied pig hearts to 3 hours of hypothermic (10 degrees to 15 degrees C), hyperkalemic (20 mEq/L) cardioplegic arrest and 1 hour of normothermic reperfusion. Left ventricular hypertrophy was created in piglets by banding of the ascending aorta, with increase of the left ventricular weight-body weight ratio from 3.01 +/- 0.2 gm/kg (control adult pigs) to 5.50 +/- 0.2 gm/kg (p less than 0.001). An in vivo isolated heart preparation was established in 39 grown banded pigs, which were divided into three groups to receive aerated crystalloid (oxygen tension 141 +/- 4 mm Hg), oxygenated blood (oxygen tension 584 +/- 41 mm Hg), or oxygenated Fluosol-DA-20% (oxygen tension 586 +/- 25 mm Hg) cardioplegic solutions. The use of crystalloid cardioplegia was associated with the following: a low cardioplegia-coronary sinus oxygen content difference (0.6 +/- 0.1 vol%), progressive depletion of myocardial creatine phosphate and adenosine triphosphate during cardioplegic arrest, minimal recovery of developed pressure (16% +/- 8%) and its first derivative (12% +/- 7%), and marked structural deterioration during reperfusion. Enhanced oxygen uptake during cardioplegic infusions was observed with blood cardioplegia (5.0 +/- 0.3 vol%), along with excellent preservation of high-energy phosphate stores and significantly improved postischemic left ventricular performance (developed pressure, 54% +/- 4%; first derivative of left ventricular pressure, 50% +/- 5%). The best results were obtained with Fluosol-DA-20% cardioplegia. This produced a high cardioplegia-coronary sinus oxygen content difference (5.8 +/- 0.1 vol%), effectively sustained myocardial creatine phosphate and adenosine triphosphate concentrations during the extended interval of arrest, and ensured the greatest hemodynamic recovery (developed pressure, 81% +/- 6%, first derivative of left ventricular pressure, 80% +/- 10%) and the least adverse morphologic alterations during reperfusion. It is concluded that oxygenated Fluosol-DA-20% cardioplegia is superior to oxygenated blood and especially aerated crystalloid cardioplegia in protecting the hypertrophied pig myocardium during prolonged aortic clamping.     

Cold cardioplegic arrest enhances heat shock protein 70 in the heat-shocked rat heart

BACKGROUND: Myocardial content of the 70-kd heat shock protein has been found to correlate with improved cardiac recovery after ischemia, but the mechanisms and conditions that regulate its level, particularly under clinical conditions, are unclear. The aim of this study was to assess the effect of hypothermic cardioplegic arrest and reperfusion on the expression of 70-kd heat shock protein in a protocol mimicking conditions of preservation for cardiac transplantation. METHODS: Heat-shocked and control hearts were subjected to 4 hours of cardioplegic arrest and global ischemia at 4 degrees C and then to 20 minutes of reperfusion. Hearts were freeze clamped at different time points-after 15 minutes of Langendorff perfusion, at the end of ischemia, and after 20 minutes of reperfusion, and analyzed for heat shock protein 70 content by Western blotting. Another set of hearts was subjected to 10 minutes of normothermic ischemia and 20 minutes of reperfusion followed by freeze clamping and analysis of heat shock protein 70 content as in cardioplegic arrest protocol. Cardiac function was measured by means of a left ventricular balloon at the end of reperfusion. RESULTS: Preischemic concentration of 70-kd heat shock protein was increased in heat-shocked hearts compared with control hearts. The content of 70-kd heat shock protein in heat-shocked hearts was further increased from 5.0 +/- 2.4 ng/microg at the end of ischemia to 11.0 +/- 4.9 ng/microg (n = 8, mean +/- SD; P <.05) at 20 minutes of reperfusion after cold cardioplegic arrest. No further rise in 70-kd heat shock protein of the heat-shocked hearts was observed after normothermic ischemia. Maximal developed pressure was 120.8 +/- 13.4 mm Hg in control hearts compared with 164.7 +/- 22.5 mm Hg in heat-shocked hearts (n = 5, mean +/- SD; P =.037) after cardioplegic arrest. By contrast, after normothermic ischemia, maximum developed pressure was 111.2 +/- 10.9 mm Hg in control hearts compared with 139.2 +/- 11.0 mm Hg in heat-shocked hearts (n = 4, mean +/- SD; P =.031). CONCLUSION: Hypothermic cardioplegic arrest but not short normothermic ischemia triggered a further increase in the level of 70-kd heat shock protein in heat-shocked rat hearts, which may enhance endogenous cardiac protection.     

Improved myocardial preservation with short hyperthermia prior to cold cardioplegic ischemia in immature rabbit hearts.

OBJECTIVE: Recent observations have been shown that the induction and accumulation of heat shock proteins (HSPs) by short exposure to nonlethal whole-body hyperthermia with normothermic recovery are closely associated with transient resistance to subsequent ischemia-reperfusion challanges. Here, this study was performed to investigate whether a shortly heat shock pretreatment affects the left ventricular (LV) function after cold cardioplegic ischemia in reperfused neonatal rabbit hearts. METHODS: Hearts from neonatal New Zealand White rabbits were isolated perfused (working heart preparation) and exposed to 2 h of cold cardioplegic ischemia followed by reperfusion for 60 min. To induce the heat shock response neonatal rabbits (n=5, HT-group) were subjected to whole-body hyperthermia at 42.0-42.5 degrees C for 15 min, followed by a normothermic recovery period of 60 min, before harvesting and the onset of global hypothermic cardioplegic arrest. Another set of hearts (n=5, control group) without a heat treatment underwent a similar perfusion and ischemia protocol served as control. The postischemic recovery was assessed by measuring several parameters of LV function. LV biopsies from all control and heat treated animals were taken before ischemia and at the end of reperfusion to examine myocardial HSP levels by Western blot analysis. RESULTS: At 60 min of reperfusion the HT-group showed significant better recovery of ventricular function such as LV developed pressure (DP) (74.6+/-10 vs. 52.1+/-8.5%, P<0.05), LV positive dP/dt (910+/-170 vs. 530+/-58 mmHg/s, P<0.01) and LV end-diastolic pressure (LVEDP) (8+/-2 vs. 18.4+/-5 mmHg, P<0.05) than control. Myocardial oxygen consumption (MVO(2)) was significantly higher in the HT-group compared with control (0.054+/-0.006 vs. 0.041+/-0.002 ml/g per min, P<0.05). Significant postreperfusion lower level in lactate production was observed in the HT-group (0.83+/-0.11 vs. 1.67+/-0.8 mmol/l, P<0.05). Also, the recovery of hemodynamic parameters such as aortic flow, coronary flow and cardiac output was significantly superior (P<0.05) in the HT-group. Furthermore, high expression of HSP72(+)/73(+) were detected in the myocardial tissue samples of heat-treated rabbits by immunoblotting, appearing even at 60 min of normothermic recovery after heat stress. CONCLUSIONS: These data in the immature rabbit heart indicate that previous shortly heat treatment with high level expression of heat shock proteins (HSP72(+)/73(+)) before hypothermic cardioplegic ischemia provides transient tolerance against myocardial injury and could be an improvement for the postischemic functional recovery of neonatal hearts.     

Functional recovery of hearts after cardioplegia and storage in University of Wisconsin and in St. Thomas' Hospital solutions

There are conflicting reports of the beneficial effects of University of Wisconsin (UW) cardioplegic solution used in heart preservation techniques. Therefore we investigated the efficacy of myocardial protection in adult rat hearts subjected to single-dose infusion (3 minutes) of nonoxygenated cardioplegic solutions (UW or St. Thomas' Hospital solution No. 2 [STH]) and stored at 4 degrees C by immersion in the same solution or in saline solution. Isolated working-heart preparations (n = 8 per group) were used to assess the prearrest (20 minutes' normothermic perfusion) and postischemic left ventricular functions. Four groups of hearts underwent 5, 8, 10, and 20 hours of cold ischemia (4 degrees C) in UW solution. Hearts stored for 8 to 20 hours showed no postischemic recovery of cardiac pump function (aortic flow, 0%), had decreased levels of myocardial high-energy phosphates, and were highly edematous (50% to 70% increased). After 5 hours of storage there was also poor recovery of aortic flow, coronary flow, and aortic pressure (55.0% +/- 19.4%, 67.1% +/- 5.1%, and 58.1% +/- 11.7%, respectively) but good recovery of adenosine triphosphate, creatine phosphate, and guanosine triphosphate (18.54 +/- 1.42, 29.99 +/- 2.05, and 1.64 +/- 0.14 mumol/gm dry weight, respectively). In contrast, hearts arrested and stored in STH solution for 5 hours rapidly established normal left ventricular functions (aortic flow, 111.5% +/- 2.5%; cardiac output, 99.1% +/- 1.2%; coronary flow, 85.0% +/- 3.4%; heart rate, 95.8% +/- 2.7%; and aortic pressure, 94.6%). A group of hearts arrested with STH solution but stored in saline solution recovered more slowly, had only partial return of function (aortic flow, 73.6% +/- 14.8%; p less than 0.01 vs STH/STH group), and had significantly greater tissue water content (8.020 +/- 0.080 vs 6.870 +/- 0.126 ml/gm dry wt; p less than 0.01). These results demonstrate the superior preservation of explanted hearts at 4 degrees C obtained by STH cardioplegic solution compared with UW solution under conditions used for transplantation.     

The consequences of asanguineous versus sanguineous reperfusion after long-term preservation of the heart

We have used the heterotopically transplanted rat heart to investigate whether the nature (sanguineous or asanguineous) of the initial period of reperfusion after hypothermic cardioplegic storage influences the postischaemic recovery of the heart. Excised rat hearts were arrested by infusion (1 min at 25 degrees C followed by 2 min at 7.5 degrees C) with the St Thomas' Hospital cardioplegic solution, subjected to 4 h of storage at 7.5 degrees C and heterotopically transplanted over a fixed period of 45 min. Reperfusion was then carried out for 80 min according to one of the following protocols: 60 or 20 min of blood perfusion in situ followed by excision, and 20 or 60 min of in vitro perfusion with crystalloid solution (Groups I and II, respectively) or immediate excision and 80 min of crystalloid perfusion (Group III). Intraventricular balloons were used to define pressure-volume relationships at the end of the 80 min period of reperfusion. Tissue samples were then taken for assessment of water content, adenosine triphosphate (ATP) and creatine phosphate (CP) content. Mean left ventricular developed pressure (at a loading volume of 110 microliters) was 92 +/- 6, 79 +/- 6 and 51 +/- 6 mmHg in Groups I, II and III, respectively. Left ventricular end-diastolic pressure was lower in the initial blood reperfusion groups (25 +/- 4 and 21 +/- 3 mmHg in Group I and II, respectively, compared with 37 +/- 5 mmHg in Group III).(ABSTRACT TRUNCATED AT 250 WORDS)     

Improved myocardial preservation during global ischemia by continuous retrograde coronary sinus perfusion

To investigate whether retrograde continuous low-pressure perfusion of the coronary sinus could deliver cardioplegic solutions with oxygen and substrate beyond stenoses and result in improved myocardial preservation, we subjected 41 canine hearts to 90 minutes of ischemia with an occlusion on the circumflex coronary artery. There were four groups: Group I, antegrade (aortic root) crystalloid cardioplegia every 30 minutes during ischemia; Group II, antegrade plus topical cooling; Group III, continuous retrograde perfusion; Group IV, same as Group III, with an oxygenated perfluorocarbon. All solutions had a PO2 of 400 to 500 mm Hg. Intramyocardial oxygen and carbon dioxide tensions (PO2 and PCO2) and mean myocardial temperatures were monitored during ischemia, and left ventricular (LV) function was assessed before ischemia and after reperfusion. After global ischemia, the circumflex occlusion was released and the hearts reperfused. Following 60 minutes of reperfusion, isovolumic developed pressure returned to 36% +/- 4% and 41% +/- 5% of preischemic levels, respectively, in Groups I and II. By contrast, Groups III and IV (retrograde perfusion) had a significantly greater percent of recovery (78% +/- 5% and 73% +/- 5%). Circumflex area intramyocardial PO2 fell 20 and 25 mm Hg below preischemic levels in Groups I and II during ischemia, whereas in Group III, intramyocardial PO2 in the circumflex region remained near preischemic levels, and in Group IV, it rose 19 mm Hg. Mean myocardial temperature during ischemia in the circumflex area was significantly higher in Group I than in Groups II, III, and IV. Peak intramyocardial PCO2 in the circumflex region was significantly less in the retrogradely perfused hearts. Retrograde coronary sinus perfusion resulted in significant improvement in recovery of LV function, uniform myocardial cooling, normal intramyocardial PO2, and less intramyocardial PCO2 accumulation, despite the presence of a total circumflex coronary artery occlusion.     

Effect of diltiazem on functional recovery and myocardial metabolism during hypothermic global ischemia and normothermic reperfusion

An isolated working rat heart preparation was used to determine the effect of diltiazem, a calcium antagonist, on the myocardial metabolism and functional recovery in the ischemic and reperfused heart, under conditions of 15 degrees C of topical hypothermia. The hearts were divided into two groups according to the solution injected into aortic root at the onset of ischemia. Group I (25 hearts) were given 3 ml of cold Krebs-Henseleit bicarbonate buffer solution (KHB), and Group II (25 hearts) were given the same dose of KHB containing 300 micrograms of diltiazem. After 30 min of reperfusion following 120 min of ischemia, cardiac output (ml/min) was significantly better in Group II (24.1 +/- 3.2) than in Group I (9.5 +/- 2.5). There were no differences between the groups with regard to tissue levels of creatine phosphate, adenosine triphosphate (ATP), total adenine nucleotide (TAN), glucose-6-phosphate and lactate during the ischemia. However, ATP and TAN levels were significantly higher in Group II after 30 min of reperfusion. These data show that, although diltiazem has little effect in preventing the catabolism of high-energy phosphates during hypothermic ischemia, there was an improvement in myocardial metabolism and an enhanced functional recovery during reperfusion in the diltiazem-treated hearts.     

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.     

Experimental evaluation of myocardial protective effect of prostacyclin analog (OP-41483) as an adjunct to cardioplegic solution

A stable prostacyclin analog (OP-41483) was evaluated for myocardial protective effect against global ischemia with the use of cardioplegia. Isolated canine hearts (n = 25) were exposed to 60 minutes of warm (37 degrees C) global ischemia after the arrest by crystalloid cardioplegia. Prostaglandin analog was given in three different ways: preadministration (700 ng/kg body weight per minute) before ischemia for 30 minutes (group I, n = 5), given as a component of cardioplegic solution (600 ng/ml, group II, n, = 6), and post-administration (25 ng/kg body weight per minute) during reperfusion for 30 minutes (group III, n = 7). During reperfusion, coronary sinus blood flow, 6-keto-prostaglandin F1 alpha in coronary sinus blood, and myocardial oxygen consumption were measured during reperfusion. As a result, groups II and III showed significantly better global left ventricular function (developed pressure, maximum dP/dt, and diastolic compliance) than the control group (without prostaglandin analog, n = 7) and group I. Myocardial oxygen consumption at reperfusion (1 minute) was significantly larger in group II than in the control group. 6-keto-prostaglandin F1 alpha flux was significantly larger in group II than in the other three groups during reperfusion. The results indicated that prostaglandin analog has a beneficial effect on myocardial protection under global ischemia with cardioplegia, particularly when used as a component of cardioplegic solution and also during reperfusion. The mechanism may relate to the cytoprotective effect (including protection of endothelium with enhanced endogenous prostacyclin production at reperfusion and also to the modulation of reperfusion per se.     

Comparison of ischemic vulnerability and responsiveness to cardioplegic protection in crystalloid-perfused versus blood-perfused hearts.

The possibility of differences between crystalloid-perfused and blood-perfused hearts in their vulnerability to ischemia and responsiveness to protective interventions has been investigated in isolated rabbit hearts perfused with bicarbonate buffer or arterial blood. In preliminary studies with 165 minutes of aerobic perfusion at constant perfusion pressure (55 +/- 3 mm Hg), the stability of left ventricular developed pressure was significantly better in blood-perfused hearts. In subsequent studies, hearts were subjected to 20 minutes of aerobic perfusion (coronary flow, 2.0 +/- 0.3 ml/min/gm wet weight in blood-perfused hearts versus 11.3 +/- 3.0 ml/min/gm wet weight in crystalloid-perfused hearts; left ventricular developed pressure, 90 +/- 4 and 91 +/- 2 mm Hg, respectively) followed by 30, 45, 60, 75, 90, or 105 minutes of normothermic global ischemia and 40 minutes of reperfusion (n = 4 per group). In the buffer-perfused groups the postischemic recoveries of left ventricular developed pressure were 74% +/- 6%, 45% +/- 7%, 39% +/- 6% 32%, +/- 5%, 27% +/- 4%, and 12% +/- 3% of preischemic control, respectively. In blood-perfused groups they were consistently greater (91% +/- 3%, 55% +/- 5%, 46% +/- 5%, 45% +/- 1%, 33% +/- 2%, and 19% +/- 3%, respectively). In further studies, hearts (n = 5 per group) were perfused with buffer (groups 1 and 2) or blood (groups 3 and 4), and each was subjected to 60 minutes of normothermic global ischemia, with (groups 2 and 4) or without (groups 1 and 3) a 3-minute preischemic infusion of St. Thomas' Hospital cardioplegic solution. After 60 minutes of reperfusion, the postischemic recoveries of left ventricular developed pressure in groups 1, 2, 3, and 4 were 32% +/- 3%, 44% +/- 4%, 43% +/- 7%, and 72% +/- 6%, respectively, with coronary flow recovering to 64% +/- 7%, 82% +/- 4%, 82% +/- 4%, and 110% +/- 5%, respectively. Left ventricular end-diastolic pressures were 20 +/- 5, 24 +/- 7, 15 +/- 4, and 4 +/- 3 mm Hg, and tissue water contents were 4.76 +/- 0.11, 4.87 +/- 0.55, 3.93 +/- 0.05, and 3.68 +/- 0.02 ml/gm dry weight, respectively. In conclusion, compared with crystalloid perfusion, the blood-perfused rabbit heart has a greater resistance to ischemia, a superior response to cardioplegic protection, and a lower tissue water content.     

Myocardial self-preservative effect of heat shock protein 70 on an immature lamb heart

BACKGROUND: Heat shock proteins have been shown to enhance myocardial tolerance of ischemia-reperfusion injury and are induced in the myocardium of many animals by various stressors. METHODS: To assess the effects and time course of the inducible form of heat shock protein 70, we raised the rectal temperature of 15 neonatal lambs to 43 degrees C for 15 minutes. At 15, 30, 60, and 120 minutes and 24 hours after heat shock, hearts were subjected to immunoblot analysis for heat shock protein (hsp 72/73). Twenty-four hours after heat shock, neonatal lamb hearts (n = 8) were subjected to 2 hours of cold cardioplegic ischemia (HSP group). Eight neonatal lamb hearts without heat shock served as control. After 60 minutes of reperfusion, left ventricular systolic and diastolic function, coronary blood flow (CBF), myocardial oxygen consumption (MVO2), and lactate levels were measured. Endothelial function was assessed by measuring in situ coronary vascular resistance response to acetylcholine and trinitroglycerine. RESULTS: The HSP group showed a significantly higher recovery of systolic function as well as MVO, and a lower lactate level compared to the control group at 60 minutes after reperfusion. Recovery of coronary endothelial function was also significantly better in the HSP group than in the control group. Inducible form of HSP 70 was expressed 15 minutes after heat shock and continued to be observed at 24 hours after the stress. CONCLUSIONS: Heat shock stress associated with the production of inducible heat shock proteins improved the recovery of ventricular function as well as endothelial function and aerobic metabolism after hypothermic cardioplegic ischemia. Induction of heat shock proteins by any means prior to planned hypothermic ischemia may lead to a new approach for myocardial protection.     

Calcium-induced ventricular contraction during cardioplegic arrest

Cardiac arrest induced by hyperkalemic perfusion is generally considered to represent a state of complete electromechanical arrest. However, high-energy phosphate concentrations and ventricular function decrease with increasing cardioplegic calcium concentrations, possibly because of elevated resting muscle tone produced by calcium influx. We examined isolated rat hearts containing an isovolumic intraventricular balloon for the presence of contractile activity during the administration at 10 degrees C of a cardioplegic solution containing potassium, 20 mEq/L. Significant left ventricular pressure was developed (35.6% +/- 4.3% of prearrest systolic pressure) during administration of a solution containing a calcium concentration of 1.0 mmol/L and far less (9.7% +/- 1.6% of prearrest systolic pressure) with a calcium-free cardioplegic solution. The muscle contraction diminished with repeated doses, was increased by increasing cardioplegic calcium content, and was inhibited by magnesium. Adenosine triphosphate and creatine phosphate concentrations were 9.0 +/- 1.4 and 7.0 +/- 0.9 nmol/mg dry weight immediately after infusion of 15 ml of a hypoxic cardioplegic solution containing calcium, versus 13.3 +/- 1.3 (p less than 0.02) and 31.9 +/- 3.5 nmol/mg dry weight (p less than 0.0001) after a hypoxic acalcemic solution was given. When repeated doses of a hypoxic cardioplegic solution containing calcium in a concentration of 1.0 mmol/L were given at 15 minute intervals at 10 degrees C, ischemic contracture (a sustained development of ventricular pressure, mean 51% +/- 4% of prearrest systolic pressure) resulted within 1 hour. Coronary vascular resistance was increased during the muscle contractions induced by calcium-containing solutions, markedly so during contracture. Calcium-related mechanical activity was also observed during hypothermic cardioplegic arrest in five of six isolated isovolumic canine hearts. We conclude that hearts remain potentially active mechanically during cold hyperkalemic arrest and undergo energetically wasteful contraction when stimulated with calcium-containing hyperkalemic cardioplegic solutions.     

Effect of sodium aspartate on the recovery of the rat heart from long-term hypothermic storage.

We have investigated the reported ability of aspartate to enhance greatly the cardioprotective properties of the St. Thomas' Hospital cardioplegic solution after prolonged hypothermic storage. Rat hearts (n = 8 per group) were excised and subjected to immediate arrest with St. Thomas' Hospital cardioplegic solution (2 minutes at 4 degrees C) with or without addition of monosodium aspartate (20 mmol/L). The hearts were then immersed in the same solution for 8 hours (4 degrees C) before heterotopic transplantation into the abdomen of homozygous rats and reperfusion in vivo for 24 hours. The hearts were then excised and perfused in the Langendorff mode (20 minutes). Addition of aspartate to St. Thomas' Hospital cardioplegic solution gave a small but significant improvement in left ventricular developed pressure, which recovered to 82 +/- 3 mm Hg compared with 70 +/- 2 mm Hg in control hearts (p less than 0.05). However, coronary flow and high-energy phosphate content were similar in both groups. In subsequent experiments hearts (n = 8 per group) were excised, arrested (2 minutes at 4 degrees C) with St. Thomas' Hospital cardioplegic solution containing a 0, 5, 10, 20, 30, 40, or 50 mmol/L concentration of aspartate, stored for 8 hours at 4 degrees C, and then reperfused for 35 minutes. A bell-shaped dose-response curve was obtained, with maximum recovery in the 20 mmol/L aspartate group (cardiac output, 48 +/- 5 ml/min versus 32 +/- 5 ml/min in the aspartate-free control group; p less than 0.05). However, additional experiments showed that a comparable improvement could be achieved simply by increasing the sodium concentration of St. Thomas' Hospital cardioplegic solution by 20 mmol/L. Similarly, if sodium aspartate (20 mmol/L) was added and the sodium content of the St. Thomas' Hospital cardioplegic solution reduced by 20 mmol/L, no significant protection was observed when recovery was compared with that of unmodified St. Thomas' Hospital cardioplegic solution alone. In still further studies, hearts (n = 8 per group) were perfused in the working mode at either high (greater than 80 ml/min) or low (less than 50 ml/min) left atrial filling rates. Under these conditions, if functional recovery was expressed as a percentage of preischemic function, artifactually high recoveries could be obtained in the low-filling-rate group. In conclusion, assessment of the protective properties of organic additives to cardioplegic solutions requires careful consideration of (1) the consequences of coincident changes in ionic composition and (2) the characteristics of the model used for assessment.