Free radical-mediated vascular injury in lungs preserved at moderate hypothermia

Lung preservation: from perfusion to temperature

PURPOSE OF REVIEW

This article will review the evidence behind elements of the lung preservation process that have remained relatively stable over the past decade as well as summarize recent developments in ex-vivo lung perfusion and new research challenging the standard temperature for static cold storage.

RECENT FINDINGS

Ex-vivo lung perfusion is becoming an increasingly well established means to facilitate greater travel distance and allow for continued reassessment of marginal donor lungs. Preliminary reports of the use of normothermic regional perfusion to allow utilization of lungs after DCD recovery exist, but further research is needed to determine its ability to improve upon the current method of DCD lung recovery. Also, research from the University of Toronto is re-assessing the optimal temperature for static cold storage; pilot studies suggest it is a feasible means to allow for storage of lungs overnight to allow for daytime transplantation, but ongoing research is awaited to determine if outcomes are superior to traditional static cold storage.

SUMMARY

It is crucial to understand the fundamental principles of organ preservation to ensure optimal lung function posttransplant. Recent advances in the past several years have the potential to challenge standards of the past decade and reshape how lung transplantation is performed.

Donor management and lung preservation for lung transplantation

Although lung transplantation has become a life-saving option for patients with end-stage lung disease, this intervention is hampered by a shortage of lungs in view of the growing number of people on the waiting list. Lungs are retrieved from only a small percentage of multiorgan donors, and the transplantation and intensive-care communities have recognised the need to develop innovative methods to expand the donor pool. Advancements in lung-preservation techniques in the preretrieval and postretrieval periods have increased the pool of available donors, and novel research and discoveries in this area have steadily improved post-transplantation adverse events. This Review summarises current best practice and the latest research on intensive-care management of a potential lung donor. We also discuss lung-preservation techniques, including advancements in normothermic ex-vivo lung perfusion, and the potential for a personalised medicine approach to the organ.

Strategies to prevent intraoperative lung injury during cardiopulmonary bypass

During open heart surgery the influence of a series of factors such as cardiopulmonary bypass (CPB), hypothermia, operation and anaesthesia, as well as medication and transfusion can cause a diffuse trauma in the lungs. This injury leads mostly to a postoperative interstitial pulmonary oedema and abnormal gas exchange. Substantial improvements in all of the above mentioned factors may lead to a better lung function postoperatively. By avoiding CPB, reducing its time, or by minimizing the extracorporeal surface area with the use of miniaturized circuits of CPB, beneficial effects on lung function are reported. In addition, replacement of circuit surface with biocompatible surfaces like heparin-coated, and material-independent sources of blood activation, a better postoperative lung function is observed. Meticulous myocardial protection by using hypothermia and cardioplegia methods during ischemia and reperfusion remain one of the cornerstones of postoperative lung function. The partial restoration of pulmonary artery perfusion during CPB possibly contributes to prevent pulmonary ischemia and lung dysfunction. Using medication such as corticosteroids and aprotinin, which protect the lungs during CPB, and leukocyte depletion filters for operations expected to exceed 90 minutes in CPB-time appear to be protective against the toxic impact of CPB in the lungs. The newer methods of ultrafiltration used to scavenge pro-inflammatory factors seem to be protective for the lung function. In a similar way, reducing the use of cardiotomy suction device, as well as the contact-time between free blood and pericardium, it is expected that the postoperative lung function will be improved.

Lung ischemia-reperfusion injury: implications of oxidative stress and platelet-arteriolar wall interactions

Pulmonary ischemia-reperfusion (IR) injury may result from trauma, atherosclerosis, pulmonary embolism, pulmonary thrombosis and surgical procedures such as cardiopulmonary bypass and lung transplantation. IR injury induces oxidative stress characterized by formation of reactive oxygen (ROS) and reactive nitrogen species (RNS). Nitric oxide (NO) overproduction via inducible nitric oxide synthase (iNOS) is an important component in the pathogenesis of IR. Reaction of NO with ROS forms RNS as secondary reactive products, which cause platelet activation and upregulation of adhesion molecules. This mechanism of injury is particularly important during pulmonary IR with increased iNOS activity in the presence of oxidative stress. Platelet-endothelial interactions may play an important role in causing pulmonary arteriolar vasoconstriction and post-ischemic alveolar hypoperfusion. This review discusses the relationship between ROS, RNS, P-selectin, and platelet-arteriolar wall interactions and proposes a hypothesis for their role in microvascular responses during pulmonary IR.

Inflammatory response to pulmonary ischemia-reperfusion injury

Lung ischemia-reperfusion (IR) injury is one of the most important complications following lung transplant and cardiopulmonary bypass. The pulmonary dysfunction following lung IR has been well documented. Recent studies have shown that ischemia and reperfusion of the lung may each play significant yet differing roles in inducing lung injury. The mechanisms of injury involving neutrophil activation, and the release of numerous inflammatory mediators and oxygen radicals also contributes to lung cellular injury, pneumocyte necrosis, and apoptosis. We herein review the current understanding of the underlying mechanism involved in lung IR injury. The biomolecular mechanisms and interactions which lead to the inflammatory response, pneumocyte necrosis, and apoptosis following lung IR therefore warrant further investigation.

Efeito da ventilação com diferentes frações inspiradas de oxigênio e do alopurinol na isquemia-reperfusão pulmonar em ratos

OBJETIVO: Avaliar o efeito da ventilação associada a frações inspiradas de oxigênio a 0,21 e 1,00 e do alopurinol (antioxidante) na isquemia-reperfusão pulmonar. MÉTODO: Foram utilizados 60 ratos Wistar, distribuídos aleatoriamente em seis grupos. O grupo 1 foi o controle; no grupo 2 os animais foram ventilados durante a isquemia-reperfusão pulmonar com FiO2 de 0,21; e no grupo 3, com FiO2 de 1,00. Os três grupos restantes 1A, 2A e 3A foram medicados com 100 mg/kg de alopurinol no pré-operatório e submetidos a procedimentos semelhantes aos grupos 1, 2 e 3, respectivamente. O modelo utilizado foi de isquemia-reperfusão normotérmica, in situ. O tempo de isquemia foi de 30 minutos, e o de reperfusão, de 10 minutos. Como parâmetros de avaliação foram utilizados a pressão arterial média sistêmica (PAM), a relação da pressão parcial de oxigênio/fração inspirada de oxigênio (PaO2/FiO2), a dosagem das substâncias reativas ao ácido tiobarbitúrico (TBARS) no tecido pulmonar e a relação entre peso pulmonar úmido e peso pulmonar seco. RESULTADOS: Em relação à PAM, ocorreu diminuição significante (p<0,05) entre os grupos 3 x 1, 2 x 2A e 3 x 3A. Na PaO2/FiO2 ocorreu diminuição significante (p<0,05) entre os grupos 3 x 2 e 3 x 3A. Nas TBARS ocorreu diminuição significante (p<0,05) entre os grupos 3 x 3A. Na relação peso pulmonar úmido/seco ocorreu aumento significante (p<0,05) entre os grupos 3 x 2, 2 x 2A e 3 x 3A. CONCLUSÕES: A ventilação com oxigênio a 21%, quando comparada à ventilação com oxigênio a 100%, apresentou diminuição menos acentuada da PAM, melhor relação entre PaO2/FiO2, e menor edema pulmonar. O uso de alopurinol no pré-operatório mostrou uma diminuição menos acentuada da PAM, melhor relação entre PaO2/FiO2, menor produção de TBARS e menor edema pulmonar, quando comparado aos resultados dos grupos que não o utilizaram.

Deep hypothermia during ischemia improves functional recovery and reduces free-radical generation in isolated reperfused rat heart

BACKGROUND

We investigated the influence of deep hypothermia (4 degrees C) during ischemia-reperfusion in the isolated rat heart model.

METHODS

Isolated, perfused rat hearts underwent either 30 minutes of normothermic ischemia (control group) or 30 minutes of hypothermic ischemia (hypothermia-treated group), followed by 30 minutes of reperfusion in both groups. We recorded functional parameters and used electron spin resonance (ESR) spectroscopy to detect ascorbyl radicals, as markers of free-radical production, in samples of coronary effluents.

RESULTS

Functional parameters were stable in the 2 groups during pre-ischemic and ischemic periods. During reperfusion, coronary flow, left diastolic ventricular pressure, left ventricular developed pressure, and heart rate more rapidly recovered to values close to those obtained during the pre-ischemic period in the hypothermia-treated group than in the control group. Moreover, the post-ischemic contracture observed in the control group did not appear in the hypothermia-treated group. Finally, ESR analysis showed that the post-ischemic release of ascorbyl radicals decreased in the hypothermia-treated group.

CONCLUSIONS

These results demonstrate that the protective effect of hypothermia against functional injury caused by ischemia-reperfusion may decrease the free-radical burst at reperfusion.

Ischemia-reperfusion-induced lung injury

Ischemia-reperfusion-induced lung injury is characterized by nonspecific alveolar damage, lung edema, and hypoxemia occurring within 72 hours after lung transplantation. The most severe form may lead to primary graft failure and remains a significant cause of morbidity and mortality after lung transplantation. Over the past decade, better understanding of the mechanisms of ischemia-reperfusion injury, improvements in the technique of lung preservation, and the development of a new preservation solution specifically for the lung have been associated with a reduction in the incidence of primary graft failure from approximately 30 to 15% or less. Several strategies have also been introduced into clinical practice for the prevention and treatment of ischemia-reperfusion-induced lung injury with various degrees of success. However, only three randomized, double-blinded, placebo-controlled trials on ischemia-reperfusion-induced lung injury have been reported in the literature. In the future, the development of new agents and their application in prospective clinical trials are to be expected to prevent the occurrence of this potentially devastating complication and to further improve the success of lung transplantation.

Do vitamins C and E attenuate the effects of reactive oxygen species during pulmonary reperfusion and thereby prevent injury?

BACKGROUND

We established an in vivo pig model of standardized lung ischemia to analyze pulmonary reperfusion injury. Enhanced chemiluminescence measurement (CM) allowed immediate quantification of reactive oxygen species (ROS) and subsequent lipid peroxidation. In such model we analyzed efficacy of vitamins C and E to prevent reperfusion injury.

METHODS

After left lateral thoracotomy in group I (n = 6), normothermic lung ischemia was maintained for 90 minutes followed by a 5-hour reperfusion period. In group II, animals (n = 6) underwent ischemia as in group I, but received vitamins (preoperative IV bolus C = 1 g, E = 0.75 g, then continuous infusion (125 mg/h) each throughout the study). In Group III, animals (n = 6) underwent sham surgery and served as controls. Hemodynamic variables and gas exchange were assessed. The CM was performed for injury quantification in blood samples and to determine activation of isolated PMNs. The Wilcox rank test was used for statistical analysis.

RESULTS

During reperfusion, all animals in group I developed significant pulmonary edema with significant loss of pulmonary function. The addition of vitamins (group II) improved oxygenation and almost abolished pulmonary inflammatory cell infiltration; however, as in group I, pulmonary compliance still tended to decline and the number of circulating leucocytes increased. The CM showed that, compared with group I, vitamins reduced O2- basic release by PMNs significantly (460% to 170%, p < 0.05; control 165%), but could not prevent an increase of free ROS in whole blood similar to group I (443% to 270%, p = ns, control 207%). With regard to lipid peroxidation only a trend of reduction was observed (117% to 105%, p = ns, control 100%).

CONCLUSIONS

Differentiated analysis by CM demonstrated that vitamins C and E inhibited PMN activation but were not able to prevent radical production by other sources. This offers a potential explanation why radical scavengers like vitamins only attenuate but ultimately do not prevent reperfusion injury.

Current strategies in lung preservation

Current methods of lung preservation allow for effective, expeditious transplantation as a treatment for end-stage pulmonary disease. However, the utilization of hypothermia, hyperkalemia, and pulmonary artery distension as a single rapid flush for perfusion is less than ideal. All these interventions result in increased pulmonary vascular resistance and suboptimal preservation of lung function. The ability to preserve lungs for longer time intervals and with less risk of tissue injury would provide significant advantages. There would be a greater likelihood that rare size or blood types could find matches by enlarging the area of organ distribution. Optimal preservation would also improve the perioperative outcomes in regard to primary graft failure and subsequently reduce the later complication of chronic rejection and graft lung dysfunction. Finally, through a better understanding of the mechanisms of lung injury during preservation and by developing means to limit the injury, it would be possible to utilize organs from donors that at this time would not be considered optimal. This would increase the donor pool without compromising the recipient's outcome.

High oxygen concentration exacerbates cardiopulmonary bypass-induced lung injury

OBJECTIVE

To investigate the effect of ventilation with 100% oxygen on lung injury associated with surgery involving cardiopulmonary bypass (CPB).

DESIGN

A prospective randomized study.

SETTING

University hospital.

PARTICIPANTS

Thirty patients undergoing coronary artery bypass graft surgery with CPB.

INTERVENTIONS

Patients were randomized to receive 100% oxygen (Oxygen group) or 50% oxygen (Air group) throughout surgery. During CPB, patients' lungs in the Air group were flushed with air and in the Oxygen group with 100% oxygen.

MEASUREMENTS AND MAIN RESULTS

Lung injury was evaluated by arterial oxygen tension-inspired oxygen concentration (PaO2-FIO2) ratio and cytokine levels (tumor necrosis factor-alpha and interleukin-8) in blood and bronchoalveolar lavage fluid measured before and after CPB. The lowest PaO2-FIO2 value was observed after 40 minutes following the completion of CPB in both groups. PaO2-FIO2 values 6 hours after CPB were not different from baseline in the Air group but remained lower (359+/-63 mmHg and 298+/-78 mmHg; p = 0.013) in the Oxygen group. Blood cytokine levels rose during surgery in both groups. Bronchoalveolar lavage levels of interleukin-8 did not change, whereas tumor necrosis factor-alpha increased only in the Oxygen group (p = 0.035).

CONCLUSIONS

A significant decrease of oxygenation was observed in the early post-CPB period in both groups of patients, with delay in recovery in patients treated with 100% oxygen. A larger increase of the proinflammatory cytokines was found in patients treated with 100% oxygen. High oxygen concentrations during surgery with CPB should be used only when specifically required.

Lung deflation impairs alveolar epithelial fluid transport in ischemic rabbit and rat lungs

BACKGROUND

Because the fluid transport capacity of the alveolar epithelium after lung ischemia with and without lung deflation has not been well studied, we carried out experimental studies to determine the effect of lung deflation on alveolar fluid clearance.

METHODS

After 1 or 2 hr of ischemia, we measured alveolar fluid clearance using 125I-albumin and Evans blue-labeled albumin concentrations in in vivo rabbit lungs in the presence of pulmonary blood flow and in ex vivo rat lungs in the absence of any pulmonary perfusion, respectively.

RESULTS

The principal results were: (1) lung deflation decreased alveolar fluid clearance while inflation of the lungs during ischemia preserved alveolar fluid clearance in both in vivo and ex vivo studies; (2) alveolar fluid clearance was normal in the rat lungs inflated with nitrogen (thus, alveolar gas composition did not affect alveolar fluid clearance); (3) amiloride-dependent alveolar fluid clearance was preserved when the lungs were inflated during ischemia; (4) terbutaline-simulated alveolar fluid clearance was preserved in the hypoxic rat lungs inflated with nitrogen; (5) lecithinized superoxide dismutase, a scavenger of superoxide anion, and N(omega)-nitro-L-arginine methyl ester, an inhibitor of nitric oxide, preserved normal alveolar fluid clearance in the deflated rat lungs.

CONCLUSION

Lung deflation decreases alveolar fluid clearance by superoxide anion- and nitric oxide-dependent mechanisms.

Reduction of post-ischemic lung reperfusion injury by fibrinolytic activity suppression

BACKGROUND

Although extensive studies on the detailed mechanisms of ischemia-reperfusion injury have been conducted, the implication of the fibrinolytic system has not been known. To determine the role of the fibrinolytic system in ischemia-reperfusion injury, we used tranexamic acid, a synthetic specific plasmin and tissue-type plasminogen activator inhibitor, to suppress fibrinolytic activity in a rabbit lung ischemia-reperfusion model.

METHODS

New Zealand White rabbits were randomly divided into two groups: a simple ischemia group and a group injected with tranexamic acid before left hilar occlusion. After 2 hours of warm ischemia, plasma was collected from pulmonary vessels. Fibrin zymography was used to ascertain fibrinolytic activity, and enzyme-linked immunosorbent assay was used to determine soluble thrombomodulin levels as a marker for endothelial cells damage. Changes in left pulmonary function including arterial oxygen tension, peak airway pressure, and pulmonary vascular resistance were recorded during reperfusion after the 2 hours of warm ischemia.

RESULTS

Fibrinolytic activity and soluble thrombomodulin levels increased in the vessels of the ischemic lung, indicating endothelial cell injury. The increased fibrinolytic activity and the rise in soluble thrombomodulin were suppressed by the preadministration of tranexamic acid, resulting in remarkably improved pulmonary function during reperfusion. After 2 hours of reperfusion, the wet-to-dry weight ratios and histological studies showed reduced pulmonary edema in the group that had received tranexamic acid.

CONCLUSION

These findings suggest that the fibrinolytic system is involved in the onset mechanism of ischemia-reperfusion injury through induced endothelial cell damage and increased vascular permeability.

University of Wisconsin solution with butanedione monoxime and calcium improves rat lung preservation

BACKGROUND

A limitation to fully using lung transplantation for patients with end-stage lung diseases is short, safe preservation time (4 to 6 hours). Our goal is to extend this to 24 hours or more, which would greatly improve clinical lung transplantation.

METHODS

We used the isolated perfused rat lung to test how two preservation solutions (low potassium dextran and University of Wisconsin solution) affected quality of lungs after 6, 12, and 24 hours of preservation. Also, we tested modifications of the University of Wisconsin solution, including reversing the ratio of Na/K, the addition of 1.5 mmol/L calcium, and the combination of calcium and butanedione monoxime, agents that improve cardiac preservation. After preservation at 4 degrees C, lungs were reperfused at 37 degrees C with a physiologically balanced solution. Pulmonary artery flow rate, airway peak inspiratory pressure, and tissue edema were used to assess degree of preservation and reperfusion injury.

RESULTS

Low potassium dextran solution gave poor preservation (decreased pulmonary artery flow, tissue edema) after 12 hours of cold storage. There were no differences between regular and reversed Na/K ratio University of Wisconsin solutions at 12 or 24 hours of preservation. Addition of calcium had no beneficial effect on lung preservation. However, University of Wisconsin solution with calcium and butanedione monoxime gave excellent 24-hour cold storage, with pulmonary artery flow rate, tissue edema, and airway peak inspiratory pressure equal to control (0 hours of preservation) lungs.

CONCLUSIONS

The University of Wisconsin solution appears capable of lung preservation for up to 24 hours if modified to contain calcium and butanedione monoxime. The mechanism of action of butanedione monoxime may be related to the suppression of smooth muscle contraction resulting in vasodilation of the cold-stored lung on reperfusion.

Protective effects of ischemic preconditioning on donor lung in canine lung transplantation

BACKGROUND

Myocardial ischemic preconditioning has been found to protect the myocardium. We hypothesized that lung ischemic preconditioning might enhance canine lung preservation and reduce allograft lung dysfunction after transplantation.

METHODS

Ten pairs of adult canines underwent left lung allotransplantation. Five donors were treated with ischemic preconditioning (their left hilus clamped for 10 min and released for 15 min [group IP]), and five donors were not treated with ischemic preconditioning (group C). The donor lungs were flushed with 4 degrees C Euro-Collins solution (ECS) and stored in the same solution for 2 1/2 h, then transplanted to the recipient canines. The animals were observed for 1 to 2 h after transplantation. The lung venous blood of the recipient and donor lung tissue was collected just after thoracotomy and 1 h after reperfusion of the transplanted lung in both groups.

RESULTS

The numbers of polymorphonuclear leukocytes (PMNs) in the pulmonary venous blood after reperfusion were significantly higher in group IP than in group C (p<0.05). However, the numbers of PMNs in lung interstitium under microscopy were less in group IP than in group C. The thromboxane B2, malondialdehyde, and mean pulmonary artery pressure contents were significantly lower in group IP than in group C (p<0.05), and the superoxide dismutase and mixed venous oxygen tension values were significantly higher in group IP than in group C (p<0.05). Histologic findings show less damage in group IP than in group C.

CONCLUSIONS

The protective effects of ischemic preconditioning in conjunction with ECS flush and storage were superior to using ECS alone. The possible mechanisms were that ischemic preconditioning inhibited the accumulation and activation of PMNs in lung tissue and reduced the production of oxygen-free radicals.

Inflammatory response to cardiopulmonary bypass: mechanisms involved and possible therapeutic strategies

BACKGROUND

Recent study of the inflammatory reactions occurring during and after cardiopulmonary bypass (CPB) has improved our understanding of the involvement of the inflammatory cascade in perioperative injury. However, the exact mechanisms of this complex response remain to be fully determined.

METHODS

Literature on the inflammatory response to CPB was reviewed to define current knowledge on the possible pathways and mediators involved, and to discuss recent developments of therapeutic interventions aimed at attenuating the inflammatory response to CPB.

RESULTS

CPB has been shown to induce complement activation, endotoxin release, leukocyte activation, the expression of adhesion molecules, and the release of many inflammatory mediators including oxygen-free radicals, arachidonic acid metabolites, cytokines, platelet-activating factor, nitric oxide, and endothelins. Therapies aimed at interfering with the inflammatory response include the administration of pharmacologic agents such as corticosteroids, aprotinin, and antioxidants, as well as modification of techniques and equipment by the use of heparin-coated CPB circuits, intraoperative leukocyte depletion, and ultrafiltration.

CONCLUSIONS

Improved understanding of the inflammatory reactions to CPB can lead to improved patient outcome by enabling the development of novel therapies aimed at limiting this response.

Inhaled nitric oxide at the time of harvest improves early lung allograft function

BACKGROUND

Inhalation of nitric oxide (NO) has been shown to have beneficial effects on a variety of acute lung injuries, including lung allograft reperfusion injury. The purpose of the present study was to investigate the effects of inhaled NO at the time of harvest on function of canine left lung allografts after transplantation.

METHODS

Ten dogs underwent left lung allotransplantation. Donor lungs were flushed with modified Euro-Collins solution and stored for 21 hours at 1 degree C. Immediately after transplantation, the contralateral main pulmonary artery and bronchus were ligated to assess isolated allograft function. Hemodynamics and arterial blood gases (inspired oxygen fraction, 1.0) were assessed intermittently for 6 hours prior to sacrifice. Allograft myeloperoxidase activity and wet to dry weight ratio were assessed. Donor animals were divided into two groups. Group I animals (n = 5) received no NO. In group II (n = 5), donors received inhaled NO (60 ppm) at the time of harvest.

RESULTS

Pulmonary vascular resistance decreased to 79.6% of baseline because of inhalation of 60 ppm NO in group II donor animals. Thiobarbituric acid-reactive materials were reduced during the storage period in group II, a finding suggesting less oxidant injury during storage in donor lungs treated with NO. Throughout the 6-hour assessment, oxygenation in group II was superior to that in group I (p < 0.05). At 360 minutes of assessment, mean arterial oxygen tension in groups I and II was 88.9 +/- 11.4 mm Hg and 169.1 +/- 33.0 mm Hg, respectively. Myeloperoxidase activity was significantly decreased in group II (p < 0.05), data indicating reduced neutrophil sequestration. Wet to dry weight ratio was significantly lower in group II.

CONCLUSIONS

These data suggest that inhaled NO at the time of harvest improves early function of preserved lung allografts by attenuating oxidant injury during storage and subsequent neutrophil sequestration.

EPC-K1 is effective in lung preservation in an ex vivo rabbit lung perfusion model

BACKGROUND

L-Ascorbic acid 2-[3,4-dihydro-2,5,7,8-tetramethyl-2-(4,8,12-trimethyltridecyl)-2H -1-benzopyran-6yl-hydrogen phosphate] potassium salt (EPC-K1) is a phosphate diester of alpha-tocopherol and ascorbic acid. It has been reported that EPC-K1 inhibits lipid peroxidation and phospholipase A2. We hypothesized that EPC-K1 might enhance lung preservation and reduce the degree of posttransplantation lung dysfunction.

METHODS

Eighteen rabbits were divided into three groups, as follows: group 1, no preservation (n = 6); groups 2 (n = 6) and 3 (n = 6), 24 hours of preservation at 8 degrees C. Low-potassium dextran-1% glucose solution was used for flushing and immersion in all groups, but EPC-K1 (0.5 mg/L) was added to the solution used in group 3. After storage the left lung was reperfused with autologous blood and ventilated using a membrane oxygenator in an isolated rabbit lung reperfusion model. The grafts used in the group 1 rabbits were perfused for 5 hours to confirm the reliability of this model, and the grafts used in the group 2 and 3 rabbits were perfused for 2 hours. Pulmonary arterial pressure, airway pressure, blood gas analysis, and the lipid peroxide level of the perfusate were assessed. The lipid peroxide levels of the lung tissue before and after storage and the wet-dry weight ratio of the perfused lung were determined in groups 2 and 3.

RESULTS

Superior graft function was noted in group 3 in terms of all indices. The lipid peroxide level in the perfusate and the wet-dry weight ratio were also suppressed in group 3. The lipid peroxide level in the lung tissue did not change during storage in either group.

CONCLUSIONS

The administration of EPC-K1 in the flush and preservation solution helps enhance lung graft function and suppresses lipid peroxidation after reperfusion.

The importance of static lung inflation during organ storage: the impact of varying ischemic intervals in a double lung rat transplantation model

To determine the importance of static lung inflation during storage, graft performance was evaluated at different levels of intratracheal pressure and varying ischemic intervals. Lewis rat lungs were perfused with low-potassium Euro-Collins and stored for 4 or 8 hr either in atelectasis (4 hr: group I; 8 hr: group IV, respectively) or 13 (group II; V) or 26 cmH2O of airway pressure (groups III, VI). Following implantation continuous measurement of alveolar-arterial oxygen difference (AaDO2*) and pulmonary vascular resistance (PVR) were performed. Separate ventilation allowed assessment of mechanical lung function of the graft. At the end of reperfusion (120 min) weight gain, histology, and phospholipid and protein content in the pulmonary lavage were compared between the groups. Despite significant differences in survival at 4 hr of ischemia graft function did not differ in groups I to III. In contrast, static inflation had a significant impact after 8 hr of ischemia. Lungs stored in atelectasis (group IV) could not be reperfused and failed immediately. Survival in group V was 83+/-11 versus 107+/-7 min in group VI (P<0.05). Compliance at 80 min was 27+/-3 in group V and 52+/-6 ml/cmH2O in group VI (P<0.02). Corresponding values for PVR were 232+/-92 and 112+/-16 mmHg/ml/min, respectively (P<0.05). Less inflation and longer ischemia resulted in a reduction of the large to small phospholipid aggregate ratio and deterioration of surfactant function in the bubble surfactometer. In conclusion, while the amount of static lung inflation may not be critical following short ischemia, the performance of the graft improves significantly with full inflation (26 cmH2O) following extended ischemia (8 hr).

Inhaled nitric oxide reveals and attenuates endothelial dysfunction after lung transplantation

BACKGROUND

Maintaining endothelial function within transplanted organs may be critical to successful preservation. In this study we have evaluated the relationship between the effect of inhalation of nitric oxide and the degree of endothelial dysfunction after lung transplantation.

METHODS

A left lung, which had been preserved for 24 hours, was transplanted and a right pneumonectomy was performed in 5 pigs. After a 24-hour observation period the pigs inhaled 5, 20, and 80 ppm nitric oxide, and pulmonary vascular resistance was recorded continuously. From the same donors preserved pulmonary arteries from the contralateral lung were studied simultaneously in organ baths. Acetylcholine chloride was used to elicit endothelium-dependent relaxation in vessel segments contracted with the thromboxane A2 analogue U-46619.

RESULTS

Maximal endothelium-dependent relaxation decreased in the preserved lungs and correlated to the pulmonary vascular resistance in the simultaneously transplanted lungs. Inhalation of nitric oxide in the pigs that had received transplants caused the pulmonary vessels to dilate in proportion to the endothelial dysfunction.

CONCLUSIONS

Preservation of lung for transplantation induces an endothelial dysfunction, and the degree of the decrease in pulmonary vascular resistance caused by nitric oxide inhalation may be an indication of the degree of this endothelial damage. The vasodilation caused by inhaled nitric oxide increases as the endothelial function deteriorates.

Nicorandil, a potent adenosine triphosphate-sensitive potassium-channel opener, ameliorates lung allograft reperfusion injury

BACKGROUND

Lung allograft ischemia-reperfusion injury, characterized by increased pulmonary vascular resistance, pulmonary edema, and hypoxia, is the most frequent cause of early graft failure. Exogenous nitric oxide has been shown to reduce lung allograft reperfusion injury. During hypoxia, the adenosine triphosphate-sensitive potassium channel is an important ionic channel that links the bioenergetic metabolism to membrane excitability. It has been shown to play a critical role in vascular permeability and in activation of neutrophils and their subsequent interaction with vessel wall cellular components. The purpose of this study was to investigate whether nicorandil, a novel nitric oxide generator and adenosine triphosphate-sensitive potassium-channel opener, might enhance lung preservation and prevent allograft reperfusion injury.

MATERIALS AND METHODS

Fourteen dogs underwent left lung allotransplantation. Donor lungs were flushed with modified Euro-Collins solution and stored for 21 hours at 1 degree C. Immediately after transplantation, the contralateral right main pulmonary artery and bronchus were ligated to assess isolated allograft function. Hemodynamics and arterial blood gas analysis (inspired oxygen fraction 1.0) were assessed for 6 hours before the dogs were put to death. After the assessment, activity of allograft myeloperoxidase and protein levels of bronchoalveolar lavage fluid were measured. Control animals (group I, n = 5) received no nicorandil. In group II (n = 5), the donor lung received nicorandil (24 mg/L) in the flush solution. In addition, recipient animals received nicorandil (0.5 mg/kg, intravenously) just before reperfusion, as well as a continuous infusion (0.74 +/- 0.03 mg/kg per hour) during the 6-hour assessment period. In group III (n = 4), glibenclamide, a selective adenosine triphosphate-sensitive potassium-channel blocker, was administered 15 minutes before nicorandil administration to both donor and recipient. The animals in group III received nicorandil in the same regimen as group II.

RESULT

Superior gas exchange and hemodynamics were observed in lungs receiving only nicorandil. Allograft myeloperoxidase activity and protein levels in bronchoalveolar lavage fluid were significantly reduced in group II. Glibenclamide eliminated the beneficial effects of nicorandil.

CONCLUSIONS

Nicorandil administration in the flush solution and during the reperfusion period ameliorates lung allograft dysfunction, improves blood flow, and reduces pulmonary vascular resistance and myeloperoxidase activity in the transplanted lung. The present study suggests that nicorandil reduces lung allograft reperfusion injury. The beneficial effects of nicorandil may be attributed to its properties as an adenosine triphosphate-sensitive potassium-channel opener.

Nitroprusside ameliorates lung allograft reperfusion injury

BACKGROUND

Nitric oxide is believed to play a critical role in the maintenance of vascular integrity through its interaction with neutrophils, platelets, and cellular components of the vessel wall. It has been reported that endogenous nitric oxide level was depressed after ischemia, reperfusion, or both. Furthermore, exogenous as well as endogenous nitric oxide decreases reperfusion-induced vascular dysfunction. We hypothesized that nitroprusside, a potent nitric oxide donor, might enhance lung preservation and reduce posttransplantation lung allograft dysfunction.

METHODS

Ten dogs underwent left lung allotransplantation. Donor lungs were flushed with modified Euro-Collins solution and stored for 21 hours at 1 degree C. Immediately after transplantation, the contralateral right main pulmonary artery and bronchus were ligated to assess isolated allograft function. Hemodynamics and arterial blood gas analysis (inspired oxygen fraction, 1.0) were assessed for 6 hours before sacrifice. Allograft myeloperoxidase activity and wet-to-dry weight ratio were assessed. Group 1 (n = 5) animals received no nitroprusside. In group 2 (n = 5), the donor lung received nitroprusside in the flush solution (10 mg/L) and recipient animals received 0.2 mg/kg just before reperfusion as well as a continuous infusion (0.11 +/- 0.01 mg.kg-1. h-1) during the assessment period.

RESULTS

Superior gas exchange and hemodynamics were noted in lungs receiving nitroprusside. Although allograft myeloperoxidase activity and the total amount of fluid suctioned from the allograft were significantly reduced in group 2, protein levels in bronchoalveolar lavage fluid were not statistically different.

CONCLUSIONS

Nitroprusside administration in the flush solution and during reperfusion improves lung allograft function and blood flow, and reduces pulmonary vascular resistance and myeloperoxidase activity in the transplanted lung. Nitroprusside reduces lung allograft reperfusion injury.

Lung preservation: the importance of endothelial and alveolar type II cell integrity

The practice of lung transplantation is constrained by a shortage of suitable donor organs. Furthermore, even "optimal" donor lung grafts are at risk of significant dysfunction perioperatively. Significant insights into the cellular and molecular mechanisms of pulmonary ischemia-reperfusion injury have occurred since the publication of previous reviews on lung preservation 3 to 4 years ago. Recent evidence indicates that the endothelium plays an essential role in regulating the dynamic interaction between pulmonary vasodilatation and vasoconstriction and is a major target during lung injury. In addition, the composition, function, and metabolism of pulmonary surfactant produced by alveolar type II cells are increasingly being recognized as important factors in pulmonary ischemia-reperfusion injury. We hypothesize that reperfusion after a period of pulmonary ischemia results in significant endothelial and alveolar type II cell dysfunction and that an important strategy in lung preservation is to preserve the integrity of these cells in the face of this injury. Given the persistent shortage of lungs available for transplantation, laboratory studies need to focus also on the "rescue" of compromised donor lungs that would have been previously regarded as unsuitable. Importantly, innovative work from the laboratory needs to be translated into clinical practice via prospective, randomized trials to ensure that the prevalence of postoperative lung graft dysfunction is reduced and the shortage of lung grafts for transplantation is alleviated.

Effects of inflation volume during lung preservation on pulmonary capillary permeability

The degree of lung allograft inflation during harvest and storage may affect posttransplantation function. High volume ventilation causes pulmonary vascular injury and increased pulmonary capillary permeability. However, the effect of lung inflation on pulmonary capillary permeability after hypothermic flush and storage is unknown. The current study was designed to examine the effects of hyperinflation and hypoinflation during preservation on pulmonary vascular permeability.

METHODS

An isolated, ex vivo rabbit lung gravimetric model without the confounding effects of reperfusion was used to determine post pulmonary capillary filtration coefficients (Kf). New Zealand White rabbits (2.75 to 3.15 kg) were intubated and lungs ventilated with room air (tidal volume 25 ml). After sternotomy and heparinization, the pulmonary artery was flushed with low potassium dextran-1% glucose solution (200 ml). The heart-lung block was then excised. Two studies were conducted. For measurement of changes in airway pressure and lung volume during preservation, lungs were inflated to one of four storage volumes (12, 25, 40, 55 ml) with room air, 100% O2, or 100% N2 and stored at 10 degrees C in a sealed container filled with saline solution. During preservation, lung volume and airway pressure were measured at 3, 6, 12 and 24 hours. In the Kf study, lungs were inflated with 100% O2, 50% O2 (with 50% N2), or room air and preserved. After 24 hours of preservation at 10 degrees C, the heart-lung block was suspended from a strain-gauge force transducer and the lungs were ventilated with room air. The pulmonary artery was connected to a reservoir of hetastarch solution (6% hetastarch with 0.9% saline solution). Lung weight gain, airway pressure, pulmonary artery pressure, and left atrial pressure were measured continuously. After a brief flush with hetastarch solution, the reservoir was then elevated to achieve 1.0 to 1.5 mm Hg increments in pulmonary artery pressure.

RESULTS

The slope of subsequent steady-state lung weight gain was used to determine the Kf. The current study demonstrated the following: (1) changes in lung volume and airway pressure during storage increased with intraalveolar O2 concentration, (2) irrespective of inflation, fraction of inspired oxygen, hyperinflation during lung preservation increased the Kf in a volume-dependent fashion; (3) Kf was increased in lungs stored hypoinflated with room air; and (4) at any inflation volume, the Kf was significantly increased with 100% O2 inflation after 24 hours of preservation.

CONCLUSION

These results suggest that storage at high lung volume or high inspired oxygen fraction increases pulmonary capillary permeability.

Pentoxifylline in flush solution improves early lung allograft function

BACKGROUND

Postischemic ischemia reperfusion injury is a frequent and unpredictable problem in clinical lung transplantation. Pentoxifylline (PTX) has a number of effects that could decrease reperfusion injury: reduced neutrophil adhesion to endothelium, decreased production of tumor necrosis factor, decreased platelet aggregation, and increased production of vasodilatory prostaglandins by vascular endothelium. We have demonstrated previously that PTX administered before storage and again during reperfusion reduced lung reperfusion injury. The purpose of the present study was to determine whether these observations were storage or reperfusion effects.

METHODS

Fourteen canine left lung allotransplantations were performed. Donor lungs were flushed with modified Euro-Collins solution and stored for 24 hours at 1 degree C. Immediately after transplantation, the contralateral right main pulmonary artery and bronchus were ligated to assess isolated allograft function. Hemodynamic indices and arterial blood gas analysis (inspired oxygen fraction 1.0) were assessed for 6 hours before sacrifice. Allograft myeloperoxidase activity was assessed. Bronchoalveolar lavage fluid was obtained from the allograft middle lobe for neutrophil counts. The animals were divided into three groups based on the timing of PTX administration. Group 1 (n = 5) animals received no PTX. Group 2 (n = 4) animals received PTX (20 mg/kg) just before reperfusion as well as continuous infusion (0.1 mg x kg-1 x min-1) during the assessment period. In group 3 (n = 5), donor lungs received PTX (200mg/L) in the flush solution only.

RESULTS

Superior gas exchange was noted in the lungs receiving PTX only in the flush solution (group 3). Myeloperoxidase activity in group-3 allografts was significantly reduced. In addition, protein levels and neutrophil counts in the bronchoalveolar lavage fluid were significantly reduced in group-3 allografts.

CONCLUSIONS

Pentoxifylline ameliorates lung allograft reperfusion injury when administered in the flush solution. Our data suggest that PTX will prevent graft endothelial dysfunction during 24-hour cold ischemic storage and consequently will prevent neutrophil activation and migration into lung tissue.