Impaired posthypoxic relaxation in single cardiac myocytes: role of intracellular pH and inorganic phosphate

OBJECTIVE: The aim was to examine the effects of alterations in intracellular pH and inorganic phosphate concentration (known to influence myofilament kinetics and to change rapidly during hypoxia) on cell contraction, relaxation, and the Ca2+ transient in normoxic and hypoxic myocytes. METHODS: Single adult rat ventricular myocytes were electrically stimulated (0.2 Hz) and cell length (photodiode array), intracellular Ca2+ (indo-1 fluorescence), or intracellular pH (SNARF-1 fluorescence) measured. Hypoxia was induced in a special open chamber in which a laminar layer of argon prevented the back diffusion of atmospheric oxygen. RESULTS: Electrically stimulated contraction was preserved during exposure to hypoxia. At reoxygenation 10 minutes later the time from the stimulus to the peak of contraction (TPK) increased by 30(SEM 9)% and the time from the peak of contraction to 50% recovery of cell length (RT50) increased by 59(13)% relative to prehypoxic values (n = 8). These changes were not accompanied by a change in the kinetics of the Ca2+ transient. pHi fell from a baseline of 7.33(0.04) to 7.25(0.03) during hypoxia and then overshot to 7.44(0.03) at reoxygenation (n = 5). Since an intracellular alkalosis can slow myofilament relaxation, proton extrusion routes were blocked to examine posthypoxic relaxation in the absence of an alkalosis. Despite inhibition of the pHi overshoot, posthypoxic relaxation remained impaired. Intracellular inorganic phosphate levels were manipulated in two protocols (2-deoxyglucose to "trap" phosphate and Tris(hydroxymethyl)-aminomethane to buffer phosphate) and both TPK and RT50 increased in normoxic cells. Having established that these two interventions, which would be expected to decrease intracellular inorganic phosphate, result in a slowing of relaxation, myocytes were first phosphate loaded (exposed to 5.0 mM phosphate) and then made hypoxic and reoxygenated after 10 min to blunt the expected fall in phosphate accompanying reoxygenation. This led to a reduction in the slowing of contraction and relaxation following reoxygenation [TPK increased by 7(5)% and RT50 by 17(9)%, n = 8; p < 0.05 v cells studied in control buffer]. CONCLUSIONS: Impaired posthypoxic relaxation is not the result of changes in pHi but is attenuated by phosphate loading of cells and may be due to a rapid decrease in intracellular phosphate accompanying the resynthesis of high energy phosphates at reoxygenation.     

Prediction of tumor control in patients with cervical cancer: analysis of combined volume and dynamic enhancement pattern by MR imaging

BACKGROUND: Hypoxemic developing hearts are susceptible to oxygen-mediated damage that occurs after reintroduction of molecular oxygen. This unintended hypoxemic/reoxygenation injury leads to lipid peroxidation and membrane damage and may contribute to postoperative cardiac dysfunction. Biochemical and functional status are improved by delaying reoxygenation on cardiopulmonary bypass (CPB) until cardioplegic arrest. METHODS: Six immature piglets (3 to 5 kg) without hypoxemia underwent 30 minutes of cardioplegic arrest during 1 hour of CPB. Fourteen others underwent 2 hours of hypoxemia on ventilator before reoxygenation on CPB. Reflecting our clinical routine, 9 were reoxygenated on CPB for 5 minutes followed by 30 minutes of cardioplegic arrest and 25 minutes of reperfusion. The other 5 were put on hypoxemic CPB for 5 minutes, before being reoxygenated during cardioplegic arrest for 30 minutes followed by 25 minutes of reperfusion. RESULTS: Cardioplegic arrest (no hypoxemia group) caused no functional or biochemical changes. In contrast, by preceding hypoxemia with subsequent reoxygenation on CPB (no treatment group) we found 39.5% decrease in antioxidant reserve capacity, 1,212% increase in myocardial conjugated diene production, significant increase in coronary sinus blood conjugated dienes, and an 81% reduction of left ventricular contractility, all of which were statistically significant (p < 0.05) when compared with the no hypoxemia group. Conversely, delaying reoxygenation until cardioplegic arrest (treatment group) resulted in 33.1% improvement in antioxidant reserve capacity, 91.7% less conjugated diene production, lower coronary sinus blood conjugated diene levels, and a 95% improved contractility, all of which were significant (p < 0.05) when compared with the no treatment group. CONCLUSIONS: A reoxygenation injury associated with lipid peroxidation and decreased postbypass contractility occurs in cyanotic immature hearts when reoxygenated on CPB. Delaying reoxygenation until cardioplegic arrest by starting CPB with ambient partial pressure of oxygen results in significantly improved myocardial status.     

Is a high glycogen content beneficial or detrimental to the ischemic rat heart? A controversy resolved

A high glycogen level may be beneficial to the ischemic heart by providing glycolytic ATP or detrimental by increasing intracellular lactate and protons. To determine the effect of high glycogen on the ischemic myocardium, the glycogen content of Langendorff-perfused rat hearts was either depleted or elevated before 32 minutes of low-flow (0.5 mL/min) ischemia with Krebs-Henseleit buffer with or without 11 mmol/L glucose, followed by 32 minutes of reperfusion with buffer containing 11 mmol/L glucose. 31P nuclear magnetic resonance spectra were acquired sequentially throughout. Further experiments involved early reperfusion or the addition of HOE 694, a Na+-H+ exchange inhibitor, during reperfusion. When glucose was supplied throughout ischemia, no ischemic contracture occurred, and postischemic recovery of contractile function was highest, at 88% of preischemic function. In the absence of glucose, normal-glycogen hearts underwent ischemic contracture at 5 minutes, had an end-ischemic pH of 6.87, and recovered to 54%, whereas in high-glycogen hearts, contracture was delayed to 13 minutes, the end-ischemic pH was 6.61, and functional recovery decreased to 13%. Contracture onset coincided with the decrease in glycolysis, which occurred as glycogen became fully depleted. Functional recovery in the high-glycogen hearts increased to 89% when reperfused before contracture and to 56% when reperfused in the presence of HOE 694. Thus, during brief ischemia in the high-glycogen hearts, ischemic glycogen depletion and contracture were avoided, and the hearts were protected from injury. In contrast, during prolonged ischemia in the high-glycogen hearts, glycogen became fully depleted, and myocardial injury occurred; the injury was exacerbated by the lower ischemia pH in these hearts, leading to increased Na+-H+ exchange during reperfusion. The contradictory findings of past studies concerning the effect of high glycogen on the ischemic myocardium may thus be due to differences in the extent of glycogen depletion during ischemia.     

Ramiprilat attenuates hypoxia/reoxygenation injury to cardiac myocytes via a bradykinin-dependent mechanism

Isolated rat neonatal cardiac myocytes were subjected to immersion in hypoxic (PO2 < 2 mm Hg), glucose-free Tyrode's solution for 5 h followed by concomitant reoxygenation and staining with the membrane-impermeant fluorophore, propidium iodide, in normoxic (PO2 > 150 mm Hg), serum-free culture media for 15 min in order to assess sarcolemmal damage indicative of myocyte viability due to hypoxia/reoxygenation injury. Prior to hypoxic exposure, cells were pretreated for 90 min with the angiotensin-converting enzyme inhibitor cyclopenta[b]pyrrole-2-carboxylic acid, 1-[2-[(1-carboxy-3-phenylpropyl)amino]-l-oxopropyl]octahydro-[2S-[1[R* (R*)]2 alpha, 3a beta, 6a beta]] (ramiprilat), concomitantly with ramiprilat and H-D-Arg-Arg-Pro-Hyp-Gly-Thi-Ser-D-Tic-Oic-Arg-OH (bradykinin B2 receptor antagonist HOE 140), the bioactive peptide Arg-Pro-Pro-Gly-Phe-Ser-Pro-Phe-Arg (bradykinin) or concomitantly with bradykinin and HOE 140. Hypoxia/reoxygenation injury to untreated control cardiac myocytes was characterized by a significant loss of sarcolemmal integrity measured at 75 +/- 4% of total cell fluorescence (mean +/- S.E., n = 42 cultures). Compared to propidium iodide staining of the above untreated control myocytes, those pretreated with 30 or 100 microM ramiprilat showed a significant reduction of propidium iodide staining to 45 +/- 9% and 40 +/- 8% (n = 9, P < 0.05) of untreated controls, respectively. Pretreatment with the protective concentrations of ramiprilat concomitant with 10 microM HOE 140 abolished the significant reduction in propidium iodide staining observed with ramiprilat alone. Similarly, pretreatment with 10 or 100 nM bradykinin significantly reduced propidium iodide staining to 35 +/- 5% and 60 +/- 10% (n = 6, P < 0.05) of the untreated hypoxic controls, respectively. In addition, concomitant pretreatment with protective concentrations of bradykinin and 10 microM HOE 140 also abolished the significant reduction in propidium iodide staining observed with bradykinin alone. The results indicate that the angiotensin-converting enzyme inhibitor ramiprilat has a protective effect on isolated cardiac myocytes exposed to hypoxia/reoxygenation and that this effect is most likely related to a local action of bradykinin on the cardiac myocyte via the activation of the kinin B2 receptor.     

Altered hypoxia-induced coronary vasodilatation in diabetic rabbit heart

The effect of type 1 diabetes mellitus on hypoxia-induced coronary vasodilation was studied in isolated perfused rabbit hearts. Four groups of hearts were compared: control hearts from normal rabbits perfused with physiological buffer (5 mM glucose and 2 mM pyruvate added), hearts from alloxan-induced diabetic rabbits (same perfusion as control), hyperglycemic hearts from normal rabbits perfused with 22 mM glucose and 2 mM pyruvate, and hyperosmotic hearts from normal rabbits perfused with 5 mM glucose, 2 mM pyruvate, and 8.5 mM choline chloride. Hypoxia was produced by perfusion with a mixture of N2- and O2- saturated solutions. Endothelium-dependent and -independent dilators were also tested. Papaverine-induced coronary vasodilatation was unaltered, whereas that of serotonin and adenosine was significantly reduced in hyperglycemic and hyperosmotic hearts but not in diabetic hearts perfused with normoglycemic buffer. Hypoxia (PO2 from 515 +/- 86 to 131 +/- 24 mmHg; 1 mmHg = 133.3 Pa) caused a significant coronary vasodilatation in normal hearts (-66 +/- 3%). This vasodilatation was reduced slightly in diabetic (-45 +/- 7%, p < 0.05) and severely in hyperglycemic (-21 +/- 5%, p < 0.05) and hyperosmotic (-24 +/- 5%, p < 0.05) hearts. The adenosine-receptor antagonist 8-phenyltheophylline (10 microM) reduced hypoxia-induced vasodilatation in normal and diabetic hearts. However, inhibition of prostaglandin synthesis with diclofenac (1 microM), which reduces hypoxia-induced vasodilatation in normal hearts, had no effect in diabetic hearts. In conclusion, alloxan-induced type 1 diabetes mellitus in rabbits is accompanied by a reduced coronary vasodilator response to hypoxia. The contribution of adenosine in this response is unaffected. However, the abated contribution of cyclooxygenase products may account for the reduced vasodilatation during hypoxia in this particular model.     

Aging impairs functional, metabolic and ionic recovery from ischemia-reperfusion and hypoxia-reoxygenation

Functional and metabolic responses to ischemia-reperfusion and hypoxia-reoxygenation were studied in Langendorff perfused hearts from mature (2-4 months) and aged (18-24 months) Wistar rats. Hearts were subjected to 20 min global ischemia or hypoxia followed by 30 min reperfusion or reoxygenation. Cellular metabolism was assessed by 31P-NMR spectroscopy. Normoxic function, phosphate metabolite levels, and cytosolic free energy state (delta GATP) were comparable in both age groups, although free [5'-AMP] and purine efflux were elevated in aged hearts. There were no aging-related differences in phosphate metabolite levels, pH or delta GATP during ischemia or hypoxia. Nevertheless, ischemic and hypoxic contracture tended to be higher in aged hearts. After reperfusion, heart rate x left-ventricular pressure recovered to 55% of pre-ischemia in mature hearts, and only 25% in aged hearts. After reoxygenation, function recovered to 75% in mature hearts and 55% in aged hearts. Recoveries of cellular [ATP], [phosphocreatine], [inorganic phosphate] and [Mg2+] were impaired, and delta GATP was consistently depressed in aged v mature hearts, Impaired recovery of delta GATP was associated with enhanced purine efflux in aged hearts. Post-ischemic Na+ and Ca2+ accumulation was also increased by 30-40% in aged hearts. Tissue damage assessed by post-ischemic creatine kinase efflux was modest in mature hearts (< 2% total tissue activity) and was 2.5-fold higher in aged hearts. The data show that: (i) aging reduces contractile recovery from ischemia/hypoxia; (ii) this is unrelated to the metabolic insult during ischemia/hypoxia, but parallels reduced recovery of delta GATP [inorganic phosphate], [Mg2+]i [Na+] and [Ca2+]; and (iii) increased purine catabolism may contribute to poor metabolic recovery in aged hearts.     

Rapid turnover of connexin43 in the adult rat heart

Remodeling of the distribution of gap junctions is an important feature of anatomic substrates of arrhythmias in patients with healed myocardial infarcts. Mechanisms underlying this process are poorly understood but probably involve changes in gap junction protein (connexin) synthesis, assembly into channels, and degradation. The half-life of the principal cardiac gap junction protein, connexin43 (Cx43), is only 1.5 to 2 hours in primary cultures of neonatal myocytes, but it is unknown whether rapid turnover of Cx43 occurs in the adult heart or is unique to disaggregated neonatal myocytes that are actively reestablishing connections in vitro. To characterize connexin turnover dynamics in the adult heart and to elucidate its potential role in remodeling of gap junctions, we measured Cx43 turnover kinetics and characterized the proteolytic pathways involved in Cx43 degradation in isolated perfused adult rat hearts. Hearts were labeled for 40 minutes with Krebs-Henseleit buffer containing [35S]methionine, and then chase perfusions were performed with nonradioactive buffer for 0, 60, 120, and 240 minutes. Quantitative immunoprecipitation assays of Cx43 radioactivity in 4 hearts at each time point yielded a monoexponential decay curve indicating a Cx43 half-life of 1.3 hours. Proteolytic pathways responsible for Cx43 degradation were elucidated by perfusing isolated rat hearts for 4 hours with specific inhibitors of either lysosomal or proteasomal proteolysis. Immunoblot analysis demonstrated significant increases ( approximately 30%) in Cx43 content in hearts perfused with either lysosomal or proteasomal pathway inhibitors. Most of the Cx43 in hearts perfused with lysosomal inhibitors consisted of phosphorylated isoforms, whereas nonphosphorylated Cx43 accumulated selectively in hearts perfused with a specific proteasomal inhibitor. These results indicate that Cx43 turns over rapidly in the adult heart and is degraded by multiple proteolytic pathways. Regulation of Cx43 degradation could play an important role in gap junction remodeling in response to cardiac injury.     

Synergism between platelets and neutrophils in provoking cardiac dysfunction after ischemia and reperfusion: role of selectins

BACKGROUND: Neutrophils (PMNs) are known to contribute to both cardiac dysfunction and myocardial necrosis after reperfusion of an ischemic heart. Moreover, platelets are also important blood cells that can aggravate myocardial ischemic injury. This study was designed to test the effects of PMNs and platelets separately and together in provoking cardiac dysfunction in isolated perfused rat hearts after ischemia and reperfusion. METHODS AND RESULTS: Control rat hearts not subjected to ischemia were perfused without blood cells for 80 minutes. Additional control rat hearts were perfused with 75x106 PMNs, with 100x106 platelets, or with 75x106 PMNs+100x106 platelets over a 5-minute perfusion followed by a 75-minute observation period. No significant reduction in coronary flow, left ventricular developed pressure (LVDP), or the first derivative of LVDP (dP/dtmax) was observed at the end of the observation period in any nonischemic group. Similarly, global ischemia (I) for 20 minutes followed by 45 minutes of reperfusion (R) produced no sustained effects on the final recovery of any of these parameters in any group of hearts perfused in the absence of blood cells. However, I/R hearts perfused with either PMNs or platelets alone exhibited decreases in these variables of 10% to 12% (P<0.05 from control). Furthermore, I/R hearts perfused with both PMNs and platelets exhibited decreases of 50% to 60% in all measurements of cardiac function (P<0.001). These dual-cell-perfused I/R hearts also exhibited marked increases in cardiac myeloperoxidase (MPO) activity, indicating a significant PMN infiltration, and enhanced P-selectin expression on the coronary microvascular endothelium. All cardiodynamic effects as well as MPO accumulation and PMN infiltration were markedly attenuated by a sialyl LewisX-oligosaccharide or a recombinant soluble P-selectin ligand, which inhibits selectin-mediated cell adhesion. CONCLUSIONS: These results provide evidence that platelets and neutrophils act synergistically in provoking postreperfusion cardiac dysfunction and that this may be largely due to cell-to-cell interactions mediated by P-selectin. These findings may help explain the reperfusion injury phenomenon.     

Coronary flow reserve after ischemia and reperfusion of the isolated heart. Divergent results with crystalloid versus blood perfusion

Mechanical function and coronary hemodynamics were assessed in 73 isolated rabbit hearts randomly subjected to 0, 10, 20, 30, or 45 minutes of 37 degrees C global ischemia and 45 minutes of reperfusion in either a modified Krebs buffer or homologous blood-perfused Langendorff mode (n = 7 to 9 hearts per group). Isovolumic developed pressure, resting coronary flow, and response to endothelium-dependent (bradykinin) and -independent (nitroglycerin) agonists were quantitated at defined preload and heart rate. Perfusate did not influence systolic performance, which was impaired after 30 minutes of ischemia and fell to 64% to 72% of preischemic values after 45 minutes of ischemia (p < 0.05). However, basal coronary flow was at least sixfold greater in crystalloid-perfused hearts. Moreover, coronary hyperemia (p < 0.05) persisted for Krebs-perfused hearts subjected to all but the longest ischemic interval. After equilibration, all postischemic blood-perfused hearts had basal flow unchanged from before ischemia. Bradykinin and nitroglycerin induced similar increases in coronary flow for each group before and after each ischemia interval. However, the magnitude of this increase was greater in blood-perfused hearts (p < 0.01) and was not attenuated by the ischemic times encompassed in this protocol. In contrast, endothelium-dependent and -independent coronary flow reserve was abolished after 20 minutes of ischemia or longer in Krebs-perfused hearts. These data suggest that the unphysiologic resting flow patterns of crystalloid-perfused isolated hearts obfuscate interpretation of the interaction between coronary flow reserve and ischemic injury.     

Reactive oxygen species in reoxygenation injury of rat brain capillary endothelial cells

OBJECTIVE: To clarify the mechanism of anoxia/reoxygenation (A/R) injury of rat brain capillary endothelial cells (BCEC). METHODS: BCEC isolated from Sprague-Dawley rats by enzymatic treatment and centrifugation were subjected to anoxia (95% N2, 5% CO2) for 20 minutes and then to reoxygenation (95% air, 5% CO2) for 3 hours. Enzyme inhibitors, including oxypurinol, indomethacin, and N(G)-nitro-L-arginine methyl ester, or specific free-radical scavengers, such as superoxide dismutase, catalase, and the ferric iron chelator deferoxamine, were added before A/R injury. The BCEC were incubated in a range of Ca2+ concentrations from 1 to 0.01 mmol/L during A/R injury. Cytotoxicity was assayed by release of intracellular lactate dehydrogenase (LDH). RESULTS: With A/R injury, LDH release from the control group (no protective agents) significantly increased (44.8 +/- 3.3%), compared with a small increase in a normoxic group. BCEC treated with oxypurinol, indomethacin, or N(G)-nitro-L-arginine methyl ester showed suppression of LDH release. LDH release was almost totally suppressed by superoxide dismutase and partially by catalase or deferoxamine. The LDH release was partly dependent on calcium concentration. CONCLUSION: BCEC subjected to A/R become potent generators of free radicals, especially superoxide anion. Free radical production depends on both xanthine oxidase and cyclooxygenase pathways. Peroxynitrite and extracellular Ca2+ both contribute importantly to reoxygenation injury of BCEC.     

Influence of hypoxia and hypoxia/hypercapnia upon brain and blood peroxidative and glutathione status in normal weight and growth-restricted newborn piglets

Glutathione (reduced (GSH) and oxidized (GSSG)), lipid peroxidation products (TBAR) and in vitro production of reactive oxygen species (ROS, by means of stimulated lipid peroxidation, H2O2 formation and amplified chemiluminescence (CL) in 9000 xg brain supernatants) were studied in the cerebellum (C) and temporoparietal area (TP) of the brain of normal weight (NW) and spontaneously intra-uterine growth-restricted newborn piglets (IUGR) after 1 hour hypoxia (fractional inspired oxygen concentration (FiO2) 8%), and in combination with 10% CO2, followed by 3 hours recovery (FiO2 30%). The strong GSH depletion accompanied by an increased concentration of GSSG and TBAR, more distinct in IUGR, is the most important result in the brain after hypoxia and reoxygenation. Hypercapnia-related acidosis seems to protect the brain of IUGR from hypoxia/reoxygenation induced injury by reducing GSH depletion as well as GSSG and TBAR increases. But stimulated lipid peroxidation and H2O2 formation in 9000 xg supernatants of C and TP were found to be higher in acidosis and hypercapnia. Decreased or unchanged amplified CL, demonstrating lower in vitro production of ROS, cannot explain the GSH depletion after hypoxia and reoxygenation. The scarce changes in erythrocyte GSH and GSSG as well as plasma TBAR concentrations did not reflect the findings in the brain. Nevertheless, the changes in the brain support the hypothesis that oxidative stress plays a role in neuronal damage after hypoxic stress, but the brain of IUGR did not reveal a special response to moderate hypoxia.     

Long-term preservation of the rat isolated heart with staurosporine and 2,3-butanedione monoxime

The present study was designed to investigate the effectiveness of staurosporine and 2,3-butanedione monoxime (BDM) in preserving cardiac function of long-term hypothermic-stored hearts. Rat isolated hearts were perfused very slowly at 4 degrees C for 16 hr with a storage buffer solution containing staurosporine and BDM. Heart functions were then examined during 2 hr of normothermic reperfusion. Isovolumetric left ventricular-developed pressure (LVDP), its differential, heart rate, and coronary flow were measured in 5 groups of hearts: controls (fresh unstored hearts), stored drug-free hearts, stored staurosporine-treated hearts, stored BDM-treated hearts, and stored BDM + staurosporine-treated hearts. Hearts that had been perfused with staurosporine or BDM during hypothermic storage attained LVDP values that were 37% or 70%, respectively, of that shown by the control group. Hearts perfused without any drug in the storage buffer attained an LVDP value that was 20% of the control value. Heart rates of stored and then normothermically reperfused hearts were lower than, but not significantly different from, values in the control group. Coronary flow values in all stored hearts were significantly lower than the control values. Thus, BDM, and to a lesser extent staurosporine, applied during prolonged hypothermic storage improved cardiac function during normothermic reperfusion.     

The importance of cardioplegic infusion pressure in neonatal myocardial protection

BACKGROUND: Cardioplegia infusion pressure is usually not directly monitored during neonatal heart operations. We hypothesize that the immature newborn heart may be damaged by even moderate elevation of cardioplegic infusion pressure, which in the absence of direct aortic monitoring may occur without the surgeon's knowledge. METHODS: Twenty neonatal piglets received cardiopulmonary bypass and the heart was protected for 70 minutes with multidose blood cardioplegia infused at an aortic root pressure of 30 to 50 mm Hg (low pressure) or 80 to 100 mm Hg (high pressure). Group 1 (n = 5, low pressure), and group 2 (n = 5, high pressure) were uninjured (nonhypoxic) hearts. Group 3 (n = 5, low pressure) and group 4 (n = 5, high pressure) first underwent 60 minutes of ventilator hypoxia (FiO2 8% to 10%) before initiating cardiopulmonary bypass to produce a clinically relevant hypoxic stress before cardiac arrest. Function was assessed using pressure volume loops (expressed as a percentage of control), and coronary vascular resistance was measured with each cardioplegic infusion. RESULTS: In nonhypoxic (uninjured) hearts (groups 1 and 2) cardioplegic infusion pressure did not significantly affect systolic function (end systolic elastance, 104% versus 96%), preload recruitable stroke work (102% versus 96%) diastolic compliance (152% versus 156%), or coronary vascular resistance but did raise myocardial water (78.9% versus 80.1%; p < 0.01). Conversely, if the cardioplegic solution was infused at even a slightly higher pressure in hypoxic hearts (group 4), there was deterioration of systolic function (end systolic elastance, 28% versus 106%) (p < 0.001) and preload recruitable stroke work (31% versus 103%; p < 0.001), rise in diastolic stiffness (274% versus 153%; p < 0.001), greater myocardial edema (80.5% versus 79.6%), and marked increase in coronary vascular resistance (p < 0.001) compared to hypoxic hearts given cardioplegia at low infusion pressures (group 3), which preserved function. CONCLUSIONS: Hypoxic neonatal hearts are very sensitive to cardioplegic infusion pressures, such that even moderate elevations cause significant damage resulting in myocardial depression and vascular dysfunction. This damage is avoided by using low infusion pressures. Because small differences in infusion pressure may be difficult to determine without a direct aortic measurement, we believe it is imperative that surgeons directly monitor cardioplegia infusion pressure, especially in cyanotic patients.     

Extracellular reduced glutathione increases neuronal vulnerability to combined chemical hypoxia and glucose deprivation

In addition to its intracellular antioxidant role, reduced glutathione (GSH) is released by CNS cells and may mediate or modulate excitatory neurotransmission. Although extracellular GSH levels rise in the ischemic cortex, its effect on the viability of energy-compromised neurons has not been defined. In this study, we tested the hypothesis that exogenous GSH would increase the vulnerability of cultured cortical neurons to azide-induced chemical hypoxia combined with glucose deprivation. Thirty minutes azide exposure in a glucose-free buffer was tolerated by most neurons, with release of less than 10% of neuronal LDH over the subsequent 21-25 h. Concomitant treatment with 10-100 microM GSH increased cell death in a concentration-dependent fashion, to 71.6+/-5.1% of neurons at 100 microM; GSH alone was nontoxic. Injury was blocked by the selective N-methyl-d-aspartate (NMDA) antagonist MK-801 but not by the AMPA/kainate antagonist NBQX. The sulfhydryl reducing agent mercaptoethanol (10-100 microM) mimicked the action of GSH; however, the zinc chelator ethylenediaminetetraacetic acid (EDTA) was ineffective. Two GSH analogues that lack a sulfhydryl group, S-hexylglutathione (SHG) and oxidized glutathione (GSSG), were inactive per se but attenuated the effect of both GSH and mercaptoethanol. These results suggest that micromolar concentrations of GSH enhance neuronal loss due to energy depletion by altering the extracellular redox state, resulting in increased NMDA receptor activation.     

Performance of isolated rat hearts perfused with helium- or nitrogen-containing, gas-saturated solutions

Effects of helium on the isolated perfused rat heart were studied employing the Langendorff technique. The perfusate consisted of Krebs-Henseleit solution saturated with one of three gas mixtures: 1) 95% O2-5% CO2, 2) 50% O2-45% He-5% CO2, and 3) 50% o2-45% N2-5% CO2. Contractile indices measured revealed the performance of hearts with the helium mixture to be equivalent to those perfused with the 95% O2-5% CO2 mixture. Those perfused with the nitrogen gas mixture exhibited contractile activity lower than that in the other two groups. It was concluded that helium exerts a direct effect on the coronary vasculature of the isolated rat heart by reducing its resistance to flow. A greater oxygen delivery to hearts perfused with the He-saturated solution compared to the N2-perfused hearts may account for the difference in performance.     

Myocyte adaptation to chronic hypoxia and development of tolerance to subsequent acute severe hypoxia

Studies in animal models and humans suggest that myocardium may adapt to chronic or intermittent prolonged episodes of reduced coronary perfusion. Stable maintenance of partial flow reduction is difficult to achieve in experimental models; thus, in vitro cellular models may be useful for establishing the mechanisms of adaptation. Since moderate hypoxia is likely to be an important component of the low-flow state, isolated adult rat cardiac myocytes were exposed to 1% O2 for 48 hours to study chronic hypoxic adaptation. Hypoxic culture did not reduce cell viability relative to normoxic controls but did enhance glucose utilization and lactate production, which is consistent with an anaerobic pattern of metabolism. Lactate production remained transiently increased after restoration of normal O2 tension. Myocyte contractility was reduced (video-edge analysis), as was the amplitude of the intracellular Ca2+ transient (indo 1 fluorescence) in hypoxic cells. Relaxation was slowed and was accompanied by a slowed decay of the Ca2+ transient. These changes were not due to alterations in the action potential. Tolerance to subsequent acute severe hypoxia occurred in cells cultured in 1% O2 and was manifested as a delay in the time to full ATP-depletion rigor contracture during severe hypoxia and enhanced morphological recovery of myocytes at reoxygenation. The latter was still seen after normalization of the data for the prolonged time to rigor, suggesting a multifactorial basis for tolerance. An intervening period of normoxic exposure before subsequent acute severe hypoxia did not result in loss of tolerance but rather increased the delay to subsequent ATP depletion rigor. Cellular glycogen was preserved during chronic hypoxic exposure and increased after the restoration of normal O2 tension. As mitochondrial cytochromes should be fully oxygenated at levels well below 1% O2, hypoxic adaptation may be mediated by a low-affinity O2-sensing process. Thus, adaptations that occur during prolonged periods of moderate hypoxia are proposed to poise the myocyte in a better position to tolerate impending episodes of severe O2 deprivation.     

Dichotomy of ischemic preconditioning: improved postischemic contractile function despite intensification of ischemic contracture

BACKGROUND: Acceleration of ischemic contracture is conventionally accepted as a predictor of poor postischemic function. Hence, protective interventions such as cardioplegia delay ischemic contracture and improve postischemic contractile recovery. We compared the effect of ischemic preconditioning and cardioplegia (alone and in combination) on ischemic contracture and postischemic contractile recovery. METHODS AND RESULTS: Isolated rat hearts were aerobically perfused with blood for 20 minutes before being subjected to zero-flow normothermic global ischemia for 35 minutes and reperfusion for 40 minutes. Hearts were perfused at a constant pressure for 60 mm Hg and were paced at 360 beats per minute. Left ventricular developed pressure and ischemic contracture were assessed with an intraventricular balloon. Four groups (n=8 hearts per group) were studied: control hearts with 35 minutes of unprotected ischemia, hearts preconditioned with one cycle of 3 minutes of ischemia plus 3 minutes of reperfusion before 35 minutes of ischemia, hearts subjected to cardioplegia with St Thomas' solution infused for 1 minute before 35 minutes of ischemia, and hearts subjected to preconditioning plus cardioplegia before 35 minutes of ischemia. After 40 minutes of reperfusion, each intervention produced a similar improvement in postischemic left ventricular development pressure (expressed as a percentage of its preischemic value: preconditioning, 44 +/- 2%; cardioplegia, 53 +/- 3%; preconditioning plus cardioplegia, 54 +/- 4% and control, 26 +/- 6%, P<.05). However, preconditioning accelerated whereas cardioplegia delayed ischemic contracture; preconditioning plus cardioplegia gave an intermediate result. Thus, times to 75% contracture were as follows: control, 14.3 +/- 0.4 minutes; preconditioning, 6.2 +/- 0.3 minutes; cardioplegia 23.9 +/- 0.8 minutes; and preconditioning plus cardioplegia 15.4 +/- 2.4 minutes (P<.05 preconditioning and cardioplegia versus control). In additional experiments, using blood- and crystalloid-perfused hearts, we describe the relationship between the number of preconditioning cycles and ischemic contracture. CONCLUSIONS: Although preconditioning accelerates, cardioplegia delays, and preconditioning plus cardioplegia has little effect on ischemic contracture, each affords similar protection of postischemic contractile function. These results question the utility of ischemic contracture as a predictor of the protective efficacy of anti-ischemic interventions. They also suggest that preconditioning and cardioplegia may act through very different mechanisms.     

Effects of a metalloproteinase that truncates P-selectin glycoprotein ligand on neutrophil-induced cardiac dysfunction in ischemia/reperfusion

This study was designed to test the effects of polymorphonuclear leukocytes (PMNs) in the presence and absence of a P-selectin blocker, mocarhagin, in provoking cardiac dysfunction in isolated perfused rat hearts following ischemia and reperfusion. Control rat hearts not subjected to ischemia were perfused without blood cells for 80 min. Additional control rat hearts were perfused with 100 x 10(6) PMNs in the presence and absence of 0.2 microgram/ml mocarhagin over a 5-min perfusion followed by a 45-min observation period. No significant reduction in coronary flow (CF), left ventricular developed pressure (LVDP), or the first derivative of LVDP (dP/dt max) was observed at the end of the observation period in any non-ischemic group. Similarly, global ischemia (I) for 20 min followed by 45 min of reperfusion (R) produced no sustained effects on the final recovery of any of these parameters in any group of hearts perfused in the absence of PMNs. I/R hearts perfused with PMNs exhibited decreases of 50-60% in all measurements of cardiac function (P < 0.001). These PMN perfused I/R hearts also exhibited marked increases in cardiac myeloperoxidase (MPO) activity indicating a significant PMN infiltration, and enhanced P-selection expression on the coronary microvascular endothelium. All cardiodynamic effects as well as MPO accumulation and PMN infiltration were attenuated markedly by the metalloproteinase, mocarhagin, which inhibits P-selectin-mediated cell adhesion by cleaving its high-affinity receptor, PSGL-1, present on neutrophils. These results provide evidence that neutrophils provoke post-reperfusion cardiac dysfunction, and that this may be largely due to P-selectin-induced adherence of neutrophils to the endothelium.     

Effect of metoclopramide, ranitidine, and droperidol on the lower sphincter of the esophagus. Experimental study on the opossum (Didelphis albiventris)

Electromanometric measures of the gastroesophageal junction were performed in 20 adult, male and female, anesthetised opossums. The electromanometric examinations were performed according the intermitent pull through technique. The research was divided in four groups, according to the drug to be analysed: group 1 (20 animals) IM injection of physiological solution (control group); group 2 (20 animals) IM injection of metoclopramide; group 3 (20 animals) IM injection of ranitidine; group 4 (20 animals) IM injection of droperidol. Electromanometry was done 15 minutes before the drug injection, just after the injection and 15, 30, 45 and 60 minutes after the injection. In each one of the moments the pressure of the lower esophageal sphincter (LES-mmHg) was analysed. Considering LES pressure the results observed were: in group 1 it was not observed any significative alteration after IM injection of physiologic solution; in group 2 it was observed significative pressure increase, 15 minutes after metoclopramide IM injection; in group 3 it was observed pressure increase, being significative at 15 and 30 minutes after IM injection; in group 4 it was observed significative increase in LES pressure in every moment, 15 minutes after droperidol IM injection.     

Clearance of technetium 99m N-NOET in normal, ischemic-reperfused, and membrane-disrupted myocardium

BACKGROUND: Technetium 99m-labeled bis(N-ethoxy, N-ethyl dithiocarbamato) nitrido technetium(v) (99mTcN-NOET) is a new neutral cardiac perfusion imaging agent that has been shown to have very high uptake and retention in vitro. The purpose of this study was to determine the clearance kinetics of 99mTcN-NOET in control, ischemic-reperfused, and membrane-disrupted myocardium. METHODS AND RESULTS: After a 100 microCi (3.7 x 10(6) Bq) bolus of 99mTcN-NOET was injected, myocardial clearance was monitored for 1 hour by the use of a sodium iodide detector in 30 isolated, Krebs-Henseleit (KH) perfused rat hearts. Seven hearts were used as controls (group 1). In seven ischemic-reperfused hearts, tracer administration and uptake was followed by 30 minutes of no flow and 1 hour of reflow (group 2). In six additional ischemic-reperfused hearts, tracer administration was followed by deprivation of flow for 1 hour followed by 1 hour of reflow (group 3). Six hearts were perfused with a 0.5% Triton X-100 KH perfusate for 1 hour (group 4). Four hearts were perfused with KH for 10 minutes, followed by cyanide for 10 minutes (group 5). This cycle was repeated three times. Activities remaining in each heart at the end of each experiment were quantitated, and activity at peak uptake was calculated. The 99mTcN-NOET myocardial clearance was near linear in the control (0.6 +/- 0.4) and both ischemic-reperfused groups with virtually no fractional clearance (1.2% +/- 0.6% and 2.1% +/- 0.6%, respectively; p = NS). In the Triton X-100 membrane-disrupted hearts, clearance was substantial (94.2% +/- 4.0%; p < 0.0001 compared with the control and ischemic-reperfused groups). Cyanide treatment produced rapid clearance, which was arrested by a return to the standard KH perfusate. Peak uptake as a percentage of injected dose was 74.9% +/- 1.4% for all groups combined. CONCLUSION: Thus 99mTcN-NOET has extremely high myocardial retention after 1 hour in normal myocardium and is not significantly affected by ongoing myocardial ischemia or reperfusion injury in this model. Clearance is increased markedly in extreme conditions of membrane disruption. These data are consistent with the concept that 99mTc-NOET is localized predominantly in or on cell membranes. 99mTcN-NOET is a promising, new myocardial perfusion imaging agent that exhibits a stable myocardial distribution in the setting of acute developing injury.