Is Ischemic Preconditioning a Useful Strategy in Steatotic Liver Transplantation?

This study examined the effect of preconditioning on steatotic livers for transplantation and attempted to identify the underlying protective mechanisms. Blood flow alterations, neutrophil accumulation, tumor necrosis factor alpha release and lipid peroxidation were observed in nonsteatotic livers after transplantation. Steatotic and nonsteatotic liver grafts were similar in their blood flow, neutrophil accumulation, and TNF release after transplantation. However, in the presence of steatosis, lipid peroxidation and hepatic injury increased. In addition, recipients of steatotic liver grafts were more vulnerable to lung damage associated with transplantation. The conversion of xanthine dehydrogenase to xanthine oxidase and the accumulation of xanthine during cold ischemia was greater in steatotic than in nonsteatotic liver grafts. The results obtained with xanthine oxidase inhibitors indicated that xanthine/xanthine oxidase could be responsible for the increased lipid peroxidation as well as the exacerbated liver and lung damage associated with transplantation of steatotic livers. Preconditioning reduced the xanthine accumulation and percentage of xanthine oxidase seen in steatotic liver grafts during cold ischemia, and conferred protection against liver and lung damage following transplantation. The benefits of preconditioning could be mediated by nitric oxide. These findings suggest that preconditioning could be a relevant new strategy to protect against the inherent risk of steatotic liver failure following transplantation.     

Leukocyte depletion as a mechanism for reducing neutrophil-mediated ischemic-reperfusion injury during transplantation

Patients undergoing transplantation are at high risk for leukocyte-mediated morbidity because of activated neutrophils and oxygen free radicals. This type of injury is most prominent during the reperfusion stage of transplantation. When tissue becomes ischemic, normal oxidation is altered. As oxygen is reintroduced to the system, oxygen free radical formation occurs via the oxidation of hypoxanthine by xanthine oxidase, causing destruction of the endothelium, increased permeability, and decreased organ function. In addition, neutrophils that may have already been activated by contact activation from the cardiopulmonary bypass circuit, accumulate in the ischemic organ at reperfusion. Activated neutrophils then release oxygen metabolites and proteolytic enzymes, which further destroy the integrity of the vascular endothelium. This insult can cause edema, capillary plugging, and poor graft function. Recent attempts have been made to decrease the mediators of ischemic-reperfusion injury. Perhaps the most advantageous of these attempts is the removal of leukocytes during reperfusion. This has been successfully achieved using leukocyte-depleting filters before exposing the organ to systemic blood flow. This article is a review of ischemic-reperfusion injury and the use of leukocyte depletion during reperfusion of transplanted organs.     

Changes in xanthine oxidase in ischemic rat brain

Xanthine oxidase activity in the rat brain was measured by means of high-performance liquid chromatography with electrochemical detection of uric acid. Cerebral ischemia was produced by a four-vessel occlusion method. In the control rat, the enzyme activity was 0.87 +/- 0.13 nmol/gm wet weight/min at 25 degrees C (mean +/- standard deviation), of which 92.4% was associated with the nicotinamide adenine dinucleotide (NAD)-dependent dehydrogenase form and only 7.6% with the oxygen-dependent superoxide-producing oxidase form. However, the ratio of the latter form increased to 43.7% after 30 minutes of global ischemia, despite the total xanthine oxidase activity remaining the same. Thus, it was revealed that uric acid can be synthesized in the rat brain and that cerebral ischemia induced the conversion of xanthine oxidase from an NAD-dependent dehydrogenase to an oxygen-dependent superoxide-producing oxidase. Although the xanthine oxidase pathway has been proposed as a source of oxygen-derived free radicals in various ischemic organs other than brain, the results of the present study suggest the involvement of the oxygen free radicals generated from this pathway in the pathogenesis of the ischemic injury of the rat brain.     

Cerebral uric acid, xanthine, and hypoxanthine after ischemia: the effect of allopurinol

The existence of uric acid in mammalian brain was recently reported, but it has not yet become a consensus. The mammalian brain has been thought to lack xanthine oxidase, which catalyzes hypoxanthine to xanthine and xanthine to uric acid as the last steps of ATP degradation in other tissue. Using high-performance liquid chromatography, we performed assays for hypoxanthine, xanthine, and uric acid in rat brain after cerebral ischemia. It was confirmed that all three substances showed significant augmentation in the removed brains and that the chronological order of those increases corresponded to the order in the metabolic pathway. Allopurinol, a specific inhibitor of xanthine oxidase, significantly suppressed the increases in uric acid and xanthine, and a compensatory accumulation of hypoxanthine was observed. From these results, it was concluded that uric acid does exist in the brain, increases after ischemia, and is possibly the end product of purine degradation in the brain. Furthermore, it is suggested that xanthine oxidase exists in the brain and catalyzes the reaction from hypoxanthine to xanthine and then to uric acid. These reactions catalyzed by xanthine oxidase are considered to be a source of free radicals and may play important roles in the pathogenesis of cerebral ischemic injury.     

Response to Allopurinol Pretreatment in a Swine Model of Heart-Lung Transplantation

The role of allopurinol in the prevention of ischemia-reperfusion injury was assessed in a model of heart-lung transplantation. Fourteen swine were divided into two groups (seven donors and seven recipients). All heart and lung blocks were placed in hypothermic storage after perfusion with cold iso-osmolar cardioplegic solution and modified Collins solution, respectively (t = 8–10°C for heart and t = 16–18°C for lungs). The total ischemic time including the orthotopic transplantation was 6 h. Animals (donors and recipients) were pretreated with allopurinol given orally at a dosage of 50 mg/kg for 4 days. Animals were assessed by monitoring heart and lung function, including extravascular lung water at three time intervals, which included pretransplantation (donor), and 30 min and 2 h posttransplantation (recipient). Erythrocyte peroxidation susceptibility was assessed for 3 days, and surgery was performed on day 4. The malondialdehyde levels determined from erythrocyte exposure to in vitro peroxidative challenge classified three paired donor and recipient animals as responders and four paired donor and recipient animals as nonresponders to the allopurinol pretreatment. A persistent deterioration of lung function was observed over time in nonresponders (p > 05) (increase of lung water, decrease of partial pressure of oxygen, increase in alveolar-arterial gradient, and decrease in arterial-alveolar tension ratio). Responders showed no significant alterations in lung function. This study in swine, a species devoid of myocardial xanthine oxidase activity, indicates that allopurinol may have a mechanism of action other than xanthine oxidase inhibition in the prevention of ischemia-reperfusion injury. The parallelism between protection of lung function and of red blood cells suggests the involvement of a generalized increase in tissue antioxidant capacity.     

Response to allopurinol pretreatment in a swine model of heart-lung transplantation

The role of allopurinol in the prevention of ischemia-reperfusion injury was assessed in a model of heart-lung transplantation. Fourteen swine were divided into two groups (seven donors and seven recipients). All heart and lung blocks were placed in hypothermic storage after perfusion with cold iso-osmolar cardioplegic solution and modified Collins solution, respectively (t = 8-10 degrees C for heart and t = 16-18 degrees C for lungs). The total ischemic time including the orthotopic transplantation was 6 h. Animals (donors and recipients) were pretreated with allopurinol given orally at a dosage of 50 mg/kg for 4 days. Animals were assessed by monitoring heart and lung function, including extravascular lung water at three time intervals, which included pretransplantation (donor), and 30 min and 2 h posttransplantation (recipient). Erythrocyte peroxidation susceptibility was assessed for 3 days, and surgery was performed on day 4. The malondialdehyde levels determined from erythrocyte exposure to in vitro peroxidative challenge classified three paired donor and recipient animals as responders and four paired donor and recipient animals as nonresponders to the allopurinol pretreatment. A persistent deterioration of lung function was observed over time in nonresponders (p less than .05) (increase of lung water, decrease of partial pressure of oxygen, increase in alveolar-arterial gradient, and decrease in arterial-alveolar tension ratio). Responders showed no significant alterations in lung function. This study in swine, a species devoid of myocardial xanthine oxidase activity, indicates that allopurinol may have a mechanism of action other than xanthine oxidase inhibition in the prevention of ischemia-reperfusion injury. The parallelism between protection of lung function and of red blood cells suggests the involvement of a generalized increase in tissue antioxidant capacity.     

Minimal role of xanthine oxidase and oxygen free radicals in rat renal tubular reoxygenation injury

The role of xanthine oxidase and oxygen free radicals in postischemic reperfusion injury in the rat kidney remains controversial. Proximal tubules, the focal segment affected by ischemic renal injury, were isolated in bulk, assayed for xanthine oxidase activity, and subjected to 60 min of anoxia or hypoxia and 60 min of reoxygenation to evaluate the participation of xanthine oxidase and oxygen radicals in proximal tubule reoxygenation injury. The total xanthine oxidase in isolated rat proximal tubules was 1.1 mU/mg of protein, approximately 30% to 40% of the activity found in rat intestine and liver. Lactate dehydrogenase release, an indicator of irreversible cell damage, increased substantially during anoxia (39.8 +/- 2.3 versus 9.8 +/- 1.8% in controls) with an additional 8 to 12% release during reoxygenation. Addition of 0.2 mM allopurinol, a potent xanthine oxidase inhibitor, and dimethylthiourea, a hydroxyl radical scavenger, failed to protect against the reoxygenation lactate dehydrogenase release. Analysis of xanthine oxidase substrate levels after anoxia and flux rates during reoxygenation indicates that hypoxanthine and xanthine concentrations are in a 15-fold excess over the enzyme Km and 0.3 mU/mg of protein of xanthine oxidase activity exists during reoxygenation. Hypoxic tubule suspensions had a minimal lactate dehydrogenase release during hypoxia and failed to demonstrate accelerated injury upon reoxygenation. In conclusion, although xanthine oxidase is present and active during reoxygenation in isolated rat proximal tubules, oxygen radicals did not mediate reoxygenation injury.     

The role of calcium ions and calcium channel entry blockers in experimental ischemia-reperfusion-induced liver injury.

Verapamil administered before treatment, but not after treatment, had a beneficial effect on a 90-minute warm ischemia-reperfusion rat liver injury model. The possible activation of proteases converting the xanthine dehydrogenase to xanthine oxidase, the significant mitochondrial calcium loading during the ischemic period, and the potentiation of calcium and oxygen-derived free radicals to promote injury to mitochondria are mechanisms supported by this study, based on both histologic observations and on the pattern of enzyme leak after the acute ischemic event.     

Desflurane Increases Pulmonary Alveolar-Capillary Membrane Permeability after Aortic Occlusion-Reperfusion in Rabbits: Evidence of Oxidant-mediated Lung Injury

Background: Pulmonary injury occurs after vascular surgery, with xanthine oxidase (an oxidant generator) released from reperfusing liver and intestines mediating a significant component of this injury. Because halogenated anesthetics have been observed to enhance oxidant-mediated injury in vitro, the authors hypothesized that desflurane would increase alveolar-capillary membrane permeability mediated by circulating xanthine oxidase after thoracic occlusion and reperfusion.

Methods: Rabbits were assigned to one of five groups: aorta occlusion groups administered desflurane (n = 14), desflurane and tungstate (xanthine oxidase inactivator, n = 12), fentanyl plus droperidol (n = 13), and two sham-operated groups (desflurane, n = 7 and fentanyl plus droperidol, n = 7). Aortic occlusion was maintained for 45 min with a balloon catheter, followed by 3 h of reperfusion. Alveolar-capillary membrane permeability was assessed by measurement of bronchoalveolar lavage fluid protein. Xanthine oxidase activity was determined in plasma and lung tissue. Ascorbic acid content (an antioxidant) was determined in lung tissue.

Results: Desflurane was associated with significantly increased alveolar-capillary membrane permeability after aortic occlusion-reperfusion when compared with the fentanyl plus droperidol anesthesia or sham-operated groups (P < 0.05). Inactivation of xanthine oxidase abrogated the alveolar-capillary membrane compromise associated with desflurane. Although significantly greater than for sham-operated animals, plasma xanthine oxidase activities released after aortic occlusion-reperfusion were not different between the two anesthetics. There were no anesthetic-associated differences in lung tissue xanthine oxidase activity. However, desflurane anesthesia resulted in a significant reduction in lung ascorbic acid after aortic occlusion-reperfusion compared with the sham-operated animals.     

Modification of oxidative stress in response to intestinal preconditioning

Previous studies have demonstrated that intestinal preconditioning protects the organ from ischemia reperfusion damage. Xanthine oxidase mediating free radical generation contributes to the development of injury associated to ischemia reperfusion. Thus, any process able to modulate the oxygen free radical generation system could attenuate the injury. Also, it is known that nitric oxide is implicated in the preconditioning response. The aim of this work is to determine: (1) the effect of intestinal preconditioning on the xanthine oxidase system, (2) the relevance of this system in the development of injury, and (3) its relationship with nitric oxide. For this purpose, we have determined the activity of the xanthine dehydrogenase/xanthine oxidase system, the levels of its substrate (xanthine), and end-product (uric acid) and oxidant stress status in rat small intestine subjected to ischemic pre-conditioning. The effects of nitric oxide inhibition have also been evaluated. Results show that the percentage of xanthine dehydrogenase to xanthine oxidase conversion, xanthine, uric acid concentration, lipoperoxides, and reduced glutathione were significantly reduced in preconditioned rats irrespectively of nitric oxide inhibition. In summary, this work shows that oxidative stress in intestinal preconditioning is reduced as consequence of the diminished conversion of xanthine dehydrogenase to xanthine oxidase, and also as a consequence of the reduced availability of xanthine.     

Xanthine oxidase-induced lung injury inhibits removal of 5-hydroxytryptamine from the pulmonary circulation

We were interested in determining the effect of lung injury initiated by superoxide anions and hydroxyl radicals on removal of 5-hydroxytryptamine (5-HT) and phenylethylamine by the isolated perfused lung. The rate of removal and percentage of removal of these bioamines was determined before and after lung injury initiated by perfusion of the lung with hypoxanthine (HX) and xanthine oxidase (XO) or xanthine oxidase alone for 10 or 30 minutes; free radicals are generated by such treatment. Because of variation in removal of bioamines among lungs of different animals, the effects of lung injury on bioamine removal were determined by calculating the percentage of inhibition of removal using data from the control and test period for each lung. Perfusion of the lung with HX/XO or XO for 10 or 30 minutes significantly inhibited 5-HT removal by 39.5% and 63.3%, respectively. In contrast, only perfusion of the lung for 30 minutes with HX/XO produced inhibition of phenylethylamine uptake (by 54.8%). As uptake of 5-HT is the rate-limiting step in 5-HT removal, these data demonstrate dose (time)-related depression of active 5-HT uptake by free radicals generated in vitro. The rate-limiting step of phenylethylamine uptake, metabolism by monoamine oxidase, is inhibited only by severe lung injury.     

Alveolar recruitment prevents rapid-reperfusion-induced injury of lung transplants.

BACKGROUND: Physical factors play an important role in ischemia-reperfusion-induced injury of lung transplants. For example, rapid restoration of reperfusion resulted in severe pulmonary edema and deterioration of pulmonary function of lung explants in an ex vivo reperfusion system. This type of injury can be prevented by a stepwise increase in the perfusion flow rate, or by adding prostaglandin E1 (PGE1) to the blood perfusate during the first 10 minutes. However, the mechanisms of these protective effects are unknown. We noted a dramatic decrease in airway pressure rather than pulmonary arterial pressure in these studies, suggesting that lung recruitment may be an important factor in minimizing injury. METHODS: In the present study, we examined the importance of alveolar recruitment in preventing rapid-reperfusion-induced lung injury. Rat lungs were flushed preserved with low potassium dextran solution for 12 hours at 4 degrees C. Lung explants were randomly divided into three groups: 1) untreated control; 2) lungs inflated to total lung capacity for 2 minutes; and 3) lungs ventilated for 10 minutes prior to reperfusion. Postpreservation lung function was assessed in an isolated rat lung reperfusion model. RESULTS: Rapid initiation of reperfusion led to severe pulmonary edema and significant pulmonary dysfunction. In inflation or ventilation groups, the injury was significantly attenuated. The PaO2 and shunt fractions in these lungs were comparable to normal lungs. A significant drop in airway pressure was observed in these two groups and the lung compliance in the inflation group was significantly better than other two groups. CONCLUSIONS: These results suggest that overcoming alveolar collapse with inflation or ventilation, may protect the lung from mechanical-stress-induced injury during reperfusion.     

Lung preconditioning with N-acetyl-L-cysteine prevents reperfusion injury after liver no flow-reflow: a dose-response study

BACKGROUND: Circulating xanthine oxidase activity and the generated oxidants have been linked to lung reperfusion injury from no flow-reflow conditions in other organs after organ transplantation or surgery. N-acetyl-1-cysteine (NAC), an oxidant scavenger, promotes glutathione in its reduced form (GSH) that is depleted during ischemia. We have recently demonstrated its efficacy in protecting lungs from reperfusion injury if administered during reperfusion of postischemic liver. We now investigated whether preconditioning of lungs with NAC could attenuate lung respiratory or vascular derangement after no flow-reflow (ischemia-reperfusion, IR) and if this depends on lung GSH levels. METHODS: Rat isolated livers were stabilized and perfused with modified Krebs-Henseleit solution (KH) (control, n=12) or made ischemic (no flow, IR-0, n=12) for 2 hr. Meanwhile, lungs were isolated, ventilated, and stabilized (KH+bovine albumin 5%). Serial perfusion (15 min) of liver+lung pairs took place followed by lung only recirculation (45 min) with the accumulated solution. Another three controls and three ischemic groups included lungs treated during stabilization with NAC at 100 mg x kg(-1), 150 or 225 mg x kg(-1) (in 2.5, 3.7 or 5.5 mmol solutions, respectively). Results. Ischemic liver damage, expressed by circulating hepatocellular constituents, was associated with pulmonary artery and ventilatory pressure increases by 70-100% of baseline, abnormal wet-to-dry weight ratio, and abnormal bronchoalveolar lavage volume and content in the IR-0 (nontreated) and the IR-100 and IR-225 pretreated lungs. NAC-150 pretreatment afforded preservation for most parameters. GSH content in the IR-150 lung tissue was only 11% higher than that of IR-225, but 2-fold that in IR-0 and IR-100 GSH lungs. CONCLUSION: Lung preconditioning with NAC prevents reperfusion injury but not in a dose-related manner. Although enhanced GSH tissue content explains lung protection, GSH-independent NAC activity is another possibility.     

Pulmonary reperfusion injury: evidence for oxygen-derived free radical mediated damage and effects of different free radical scavengers

Blood granulocyte-mediated reactions involving generation of oxygen-derived free radicals have recently been shown to be capable of causing injury to the lungs. These findings suggest a similar mechanism also to be involved in the development of pulmonary ischemia/reperfusion injury. In the present study, therefore, the effects of three oxygen-derived free radical scavengers, superoxide dismutase (SOD; 1 mg/kg), catalase (20000 IU/kg) and allopurinol (45 mg/kg), were evaluated during reperfusion in a rabbit model after 2 h normothermic ischemia of the lung. During reperfusion, ischemic lungs were found to have an elevated pulmonary vascular resistance, increased total and extravascular lung water content, and decreased arterial oxygen tension (PaO₂) compared to control animals. SOD and catalase, but not allopurinol, were able to reduce pulmonary injury by lowering the pulmonary vascular resistance, but could not prevent pulmonary damage as shown by total lung water (TLW) or PaO₂. It is concluded that oxygen-derived free radicals such as hydrogen peroxide and the superoxide anion may play an important role in precipitating pulmonary injury after ischemia. The failure of xanthine oxidase inhibition (allopurinol) to exert protective effects may suggest that oxygen-derived free radical generation following pulmonary ischemia occurs predominantly via leukocyte-mediated reactions.     

Lipid peroxidation is not a major factor involved in the edema formation in perfused lungs

Perfusion of isolated rat lungs was previously found to induce edema formation, which was considered to be mediated by oxygen-free radicals as scavengers reduced the edema. In the present study we elaborated upon these findings by measuring products found by O2-radical generation. We measured reduced and oxidized glutathione as well as conjugated dienes as an estimate of lipid peroxidation. Amount of water was also measured. Perfusion with oxygenated dextran/Tyrode solution increased edema as compared to nonoxygenated dextran/Tyrode and to nonperfused control lungs. Induction of oxygen radical formation by addition of xanthine and xanthine oxidase to the nonoxygenated dextran/Tyrode perfusate significantly increased the amount of edema as measured by the percentage of water in the lung to 87.0% as compared to the control value of 78.2%. Addition of the radical scavenger superoxide dismutase and catalase to this perfusate prevented edema accumulation. Levels of conjugated dienes as well as those of reduced and oxidized glutathione in lung tissue were measured before the start of perfusion and after 5 and 30 min of perfusion. No significant changes were seen in any of these parameters, indicating that lipid peroxidation may not be a major factor contributing to the edema formation during perfusion of isolated lungs.     

Long-term hypothermic lung preservation: does adenosine A1 receptor antagonism have a role in ischemic preconditioning protection?

Ischemic preconditioning or phosphodiesterase inhibition improves lung protection during prolonged hypothermic storage. In ischemic preconditioning of cat lungs, adenosine A1 receptor antagonism was suggested as a possible mechanism. Some phosphodiesterase inhibitors (such as theophylline) are also adenosine antagonists; we showed theophylline to be particularly effective in protecting lungs. In isolated, perfused and ventilated rat lungs, we examined (1) whether synergy exists between phosphodiesterase inhibition and ischemic preconditioning and (2) whether theophylline acts both to inhibit phosphodiesterase and block adenosine receptors, by comparing its effects with enprofylline (selective phosphodiesterase inhibition) or xanthine amine congener (selective adenosine A1 receptor antagonism). In Study 1, rolipram (added to St Thomas' cardioplegia) or ischemic preconditioning before hypothermic storage (8 h) did not improve lung function during reperfusion (40 min); a combination of these treatments was also ineffective. In Study 2, lungs stored in St Thomas' cardioplegia containing enprofylline or theophylline had improved recovery of function compared to control lungs; however, xanthine amine congener was without effect. Thus, no interaction exists between phosphodiesterase inhibition and ischemic preconditioning. Adenosine A1 receptor antagonism plays no role in protecting rat lungs from the effects of prolonged hypothermic storage by either preconditioning or addition of theophylline to the storage solution.     

Aprotinin attenuated ischemia-reperfusion injury in an isolated rat lung model after 18-hours preservation.

OBJECTIVE: Ischemia-reperfusion injury is a major factor in the early phase of lung transplantation. We hypothesized that aprotinin, a nonspecific serine protease inhibitor, attenuates ischemia-reperfusion lung injury by inhibiting the inflammatory response and suppressing NADPH oxidase. METHODS: We used an isolated rat lung model to test the above. A Control group was immediately perfused with fresh heparinized allogeneic blood after lung harvest without an ischemic period. Study lungs were flushed with low-potassium dextran (LPD) solution and stored for 18h at 4 degrees C then divided into two groups: the LPD group was flushed with LPD solution only, and the LPD+A group was flushed with LPD solution +200KIU/ml aprotinin. Lungs in all three groups were then reperfused with fresh heparinized allogeneic blood for 120min at 37 degrees C. RESULTS: Throughout reperfusion, PO(2) levels in the LPD+A group were similar to those in the Control group; although in the LPD group, PO(2) levels were significantly lower (P<0.05). Tissue MDA levels were significantly higher in the LPD group than the Control and LPD+A groups (P<0.05). IL-8 levels were significantly higher in the LPD group than the Control group (P<0.05), while in the LPD+A group they were similar to those in the Control group. Histological evaluation showed interstitial edema accompanied by neutrophil extravasation in the LPD group, whereas this effect was modest in the LPD+A group. An additional study of ischemia-reperfusion in an alveolar macrophage culture showed that the activitvation of NADPH oxidase, and translocation of p47(phox) from the cytosol to the membrane were suppressed in aprotinin group. CONCLUSIONS: Aprotinin attenuates ischemia-reperfusion lung injury by inhibiting the early inflammatory response, neutrophil extravasation and the production of oxygen free radicals through inhibition of the activation of the NADPH oxidase. The inhibition of p47(phox) translocation in alveolar macrophage seemed involved in this mechanism of aprotinin.     

Immunology of pyelonephritis. VII. Effect of allopurinol

The inflammatory response and the respiratory burst of bacterial phagocytosis have been shown to be at least partially responsible for the renal damage from infection. In addition, we have shown that renal blood flow decreases following infection. Hypoxanthine is produced in ischemic tissue during the anaerobic metabolism of adenosine monophosphate (AMP). During reperfusion hypoxanthine is metabolized to uric acid and superoxide in the presence of xanthine oxidase. The toxicity of this oxygen radical was prevented by preventing its formation with pretreatment with allopurinol, an xanthine oxidase inhibitor. The data suggest that xanthine oxidase may be the enzyme responsible for the respiratory burst of phagocytosis, as well as preventing reperfusion damage which occurs after ischemia.     

Free radicals and cardioplegia: allopurinol and oxypurinol reduce myocardial injury following ischemic arrest

Oxygen-derived free radicals generated by xanthine oxidase may represent a major cause of myocardial injury during ischemia and reperfusion. We have used the isolated working rat heart model of cardiopulmonary bypass and ischemic arrest to assess whether allopurinol or oxypurinol, which should prevent free radical formation through their ability to inhibit xanthine oxidase, can improve postischemic myocardial recovery when the drugs are administered either chronically (pretreatment) or acutely (as an addition to the cardioplegic or reperfusion solution). With normothermic ischemic arrest, both drugs, when given either chronically or acutely, significantly improved postischemic recovery of function. However, under hypothermic conditions, allopurinol conferred no protection when given either as pretreatment or during reperfusion, but it was effective when added to the cardioplegic solution. When administered under the appropriate conditions, both allopurinol and oxypurinol enhanced the protective effect afforded by the St. Thomas' Hospital cardioplegic solution, possibly by inhibiting xanthine oxidase activity and preventing the formation of oxygen-derived free radicals.     

Warm ischemia lung protection with pinacidil: an ATP regulated potassium channel opener

BACKGROUND: Ischemia/reperfusion injury remains a limiting factor in lung transplantation. Traditional hyperkalemic preservation solutions are associated with a host of metabolic derangements. ATP-regulated potassium channel openers (PCOs) may provide an attractive alternative to traditional solutions by utilizing inherent mechanisms of ischemic preconditioning. The purpose of this study was to assess warm ischemia graft protection with pinacidil, a nonspecific PCO. METHODS: An isolated recirculating blood perfused ventilated rabbit lung model was used (n = 15). No ischemia control lungs underwent immediate reperfusion (n = 5). Warm ischemia control lungs were flushed with lactated Ringers (LR), stored at 37 degrees C for 2.5 hours and then reperfused for 2 hours (n = 5). PCO protected lungs were flushed with LR + 100 micromol/L pinacidil, stored, and then reperfused (n = 5). Intermittent blood gases were taken from the pulmonary artery and left atria. Every 30 minutes, graft function was assessed with a 10-minute 100% fractional inspired oxygen concentration challenge to measure maximal gas exchange. Lung samples were graded for histologic injury and assayed for myeloperoxidase activity. RESULTS: A mixed-models repeated measures ANOVA demonstrated a significant difference between groups. Tukey's honestly significant difference multiple comparison test demonstrated significantly improved graft function and reduced histologic injury with pinacidil protection compared with the warm ischemia controls. There was no significant difference in graft function or pathology grade between the pinacidil protected lungs and the no ischemia controls. A similar trend, although not significant, was seen in myeloperoxdiase activity. CONCLUSIONS: Potassium channel openers with pinacidil can provide pulmonary protection against warm ischemia reperfusion injury.