Prolonged preservation of canine lung allografts: The role of prostaglandins

Comparing the performance of rat lungs preserved for 6 or 12 hours after perfusion with low-potassium dextran or histidine-tryptophan-ketoglutarate

INTRODUCTION

In lung transplantation, graft dysfunction is a frequent cause of mortality; the etiopathogenesis is related to ischemia-reperfusion injury. We sought to compare the lung performance of rats after reperfusion after presentation with 3 solutions at 2 ischemia times.

METHODS

We randomized 60 male Wistar rats to undergo anterograde perfusion via the pulmonary artery with low-potassium dextran (LPD), histidine-tryptophan ketoglutarate (HTK), or saline. After extraction, the heart-lung blocks were preserved in a solution at hypothermia for 6 or 12 hours before perfusion with homologous blood for 60 minutes using ex vivo system Isolated Perfused Rat or Guinea Pig Lung System (Harvard Apparatus). Respiratory mechanics, pulmonary weight, pulmonary artery pressure (PAP), and relative lung oxygenation capacity (ROC) measurements were obtained every 10 minutes.

RESULTS

Comparing tidal volume (TV), compliance, resistance, ROC, PAP, and pulmonary weight the LPD, HTK, and saline group did not differ at 6 and 12 hours. The TV was higher in the lungs with 6-hour ischemia in the LPD, HTK, and saline groups. Compliance was higher in the lungs with 6-hour ischemia in the LPD and saline groups. There were no differences in ROC values comparing lungs with 6- versus 12-hour ischemia in the LPD group. A significant difference was observed between lungs in the HTK and saline groups. Resistance was higher in the lungs with 12-hour ischemia among the LPD, HTK, and saline groups. There was a gradual weight increase in the lungs, particularly those undergoing 12-hour ischemia, despite the absence of a significant difference between groups.

CONCLUSION

Rat lungs perfused with LPD and HTK preservation solutions showed similar reperfusion performances in this ex-vivo perfusion model.

Comparison between Perfadex and locally manufactured low-potassium dextran solution for pulmonary preservation in an ex vivo isolated lung perfusion model

INTRODUCTION

Lung transplantation, a consolidated treatment for end-stage lung disease, utilizes preservation solutions, such as low potassium dextran (LPD), to mitigate ischemia-reperfusion injury. We sought the local development of LPD solutions in an attempt to facilitate access and enhance usage. We also sought to evaluate the effectiveness of a locally manufactured LPD solution in a rat model of ex vivo lung perfusion.

METHODS

We randomized the following groups \?\adult of male Wistar rats (n = 25 each): Perfadex (LPD; Vitrolife, Sweden); locally manufactured LPD-glucose (LPDnac) (Farmoterapica, Brazil), and normal saline solution (SAL) with 3 ischemic times (6, 12, and 24 hours). The harvested heart-lung blocks were flushed with solution at 4°C. After storage, the blocks were connected to an IL-2 Isolated Perfused Rat or Guinea Pig Lung System (Harvard Apparatus) and reperfused with homologous blood for 60 minutes. Respiratory mechanics, pulmonary artery pressure, perfusate blood gas analysis, and lung weight were measured at 10-minute intervals. Comparisons between groups and among ischemic times were performed using analysis of variance with a 5% level of significance.

RESULTS

Lungs preserved for 24 hours were nonviable and therefore excluded from the analysis. Those preserved for 6 hours showed better ventilatory mechanics when compared with 12 hours. The oxygenation capacity was not different between lungs flushed with LPD or LPDnac, regardless of the ischemic time. SAL lungs showed higher PCO(2) values than the other solutions. Lung weight increased over time during perfusion; however, there were no significant differences among the tested solutions (LPD, P = .23; LPDnac, P = .41; SAL, P = .26). We concluded that the LPDnac solution results in gas exchange were comparable to the original LPD (Perfadex); however ventilatory mechanics and edema formation were better with LPD, particularly among lungs undergoing 6 hours of cold ischemia.

Preservation solution for lung transplantation

Despite the increasing success of lung transplantation as the mainstay therapeutic modality for end-stage lung disease, the 1-year survival rate after lung transplantation remains 80% and primary graft dysfunction (PGD) accounts for 30% of mortality. Ischemia-reperfusion injury has been identified as one of the main causes of PGD, and thus significant efforts have been made to optimize the methods for lung preservation in an attempt to minimize lung injury during the period of ischemia. The composition of the lung preservation solution used in the pulmonary artery flush has been considered to be the key to successful lung preservation, and many lung transplant programs have been shifting the use of the preservation solution from the intracellular fluid type to the extracellular fluid type because of preferable posttransplant lung function with the latter. This review summarizes the experimental and clinical studies on lung preservation, particularly focusing attention on the preservation solution being employed for clinical lung transplantation.

Iloprost ameliorates post-ischemic lung reperfusion injury and maintains an appropriate pulmonary ET-1 balance

BACKGROUND

Ischemia-reperfusion (I/R) injury of the lung involves increased pulmonary vascular resistance. Prostaglandins are thought to have a beneficial effect in lung transplantation, but their mechanism in I/R injury is unknown. We investigated whether iloprost, a stable prostacyclin analogue, prevents I/R-associated pulmonary vascular dysfunction and whether it affects endothelin-1 (ET-1) balance.

METHODS

In an isolated blood-perfusion model, we subjected lungs of Lewis rats to 45 minutes of ischemia at 37 degrees C and randomly allocated the lungs to 3 groups (n = 6 each): iloprost (33.3 nmol/liter) added to the perfusate before ischemia and reperfusion (ILO+IR), iloprost (33.3 nmol/liter) given only before reperfusion (ILO+R), and controls without iloprost treatment (ILO-).

RESULTS

Reperfusion induced marked pulmonary edema in non-treated controls (ILO-), which was attenuated in ILO+R lungs and completely prevented in ILO+IR lungs. At 60 minutes reperfusion, arterial oxygen tension was significantly greater in both ILO+R and ILO+IR lungs compared with ILO- controls. Mean pulmonary artery pressure and pulmonary vascular resistance were slightly decreased in the ILO+R and significantly decreased in the ILO+IR group compared with the ILO- controls. Plasma levels of big ET-1, measured in both afferent and efferent blood, showed that I/R results in increased pulmonary venous levels of big ET-1. Interestingly, the increased venoarterial ET-1 gradient in ILO- lungs decreased significantly in the ILO+IR group.

CONCLUSIONS

We demonstrated in an isolated lung perfusion model that iloprost ameliorates post-ischemic lung reperfusion injury and maintains an appropriate pulmonary ET-1 balance.

A comparative study of Euro-Collins, low potassium University of Wisconsin and cold modified blood solutions in lung preservation in acute autotransplantations in the pig

OBJECTIVE

The aim of the study was to assess the quality of lung preservation offered by Euro-Collins solution (EC), Cold Modified Blood solution (CMB) and low potassium University of Wisconsin solution (UWLP).

METHOD

Fifteen right lung auto-transplantations (five for each solution) in the pig (Large White) were performed after 2 h of cold ischaemic storage in physiological solution at 4 degrees C. Right lung biopsies were performed before ischaemia and 30 min after reperfusion, for histoenzymatic, histopathological and electron microscope studies.

RESULTS

After reperfusion, significant alterations were observed in the haemodynamics with only the right lung perfused; pulmonary arteriolar resistance increased by a factor of 5 in the EC group, by a factor of 4 in the CMB group and by a factor of 1.2 in the UWLP group; the right ventricular ejection fraction fell by 60% in the EC group, by 50% in the CMB group and by 31% in the UWLP group. Haemodynamic impairment was lower in the UWLP group (P<0.05; P<0.001) as was ischaemic-reperfusion injury (P<0.05). Oedema was observed in the EC group and extensive alveolar wall damage in the CMB group. Hypoxaemia was observed in all groups but the differences in the degree of hypoxaemia were not significant.

CONCLUSIONS

The authors concluded that UWLP solution was the most effective of the three in this transplant model.

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.

Overview and future practice patterns in cardiac and pulmonary preservation

Heart and lung transplantation have become standard therapy for many patients with end-stage heart and lung disease. Successful transplantation requires preservation of allografts until they can be implanted and reperfused. In the decades since the transplantation of thoracic organs became a clinical reality, many advances have been made in preoperative donor management, procurement, and preservation techniques. This article summarizes the state of the art in heart and lung preservation and review some of the areas of current research that may lead to improvements in preservation techniques in the future.

Beneficial effects of leukocyte-depleted blood and low-potassium dextran solutions on microvascular permeability in preserved porcine lung

Modified Euro-Collins (EC) solution, a crystalloid intracellular-type solution, has been commonly used for pulmonary preservation. Several experimental studies have shown the advantages of using extracellular colloid-based solutions. The aim of this study was to compare the quality of preservation of two extracellular colloid solutions, leukocyte-depleted blood (BL) and low-potassium dextran (LPD) solutions, with that of EC solution. Lungs of 22 domestic pigs were flushed and preserved with EC (n = 8), BL (n = 7), or LPD (n = 7) solution. After harvesting, one of the lungs was reperfused immediately in an ex vivo circuit (control lungs), whereas the contralateral lung was reperfused after 8 h of cold (4 degrees C) storage (preserved lungs). Besides the lung function parameters (gas exchange, pulmonary hemodynamics and mechanics), the permeability of the endothelial-epithelial barrier was assessed by determining the transferrin leak index (TLI) using a double radioisotopic method, by measuring the alveolar/arterial protein concentration ratio, and by analyzing histopathologic changes. The functional quality (oxygenation, airway resistance, dynamic compliance [CL, dyn]) of both BL and LPD lungs was slightly but significantly superior to that of EC lungs. However, pulmonary vascular resistance was lower in BL-preserved than in EC- or LPD-preserved lungs. The TLI was increased in EC control and preserved lungs, whereas it was low in BL and LPD control lungs and did not increase after preservation. The alveolar/arterial protein concentration ratio was not different between control groups, but was increased fourfold in EC-preserved compared with BL- or LPD-preserved lungs. Finally, EC-preserved lungs presented a weight gain about twice that of BL- and LPD-preserved lungs. Morphologic analysis confirmed these results, because in the EC-preserved lungs, rupture of alveolar septa and severe alveolar edema and hemorrhage were observed, whereas BL- and LPD-preserved lungs showed a relatively well-preserved structure. The results demonstrate that both BL and LPD flush solutions preserve the endothelial-epithelial barrier better than does EC solution. Although the quality of preservation is similar, pulmonary vascular resistance is higher in LPD-preserved than in BL-preserved lungs.

Combined use of prostacyclin and higher perfusate temperatures further enhances the superior lung preservation by Celsior solution in the isolated rat lung

BACKGROUND

The poor tolerance of the lung to ischemia and reperfusion (IR) still represents one of the limitations in clinically successful lung transplantation. Modified Euro-Collins (EC) is routinely used in lung preservation, but alternative solutions have been developed for improvement of pulmonary preservation. Celsior is an extracellular solution that has significantly reduced the IR-induced pulmonary damage in animal studies. So far, no extensive experimental studies exist concerning the influence of Celsior on pulmonary gas exchange following IR.

METHODS

In an extracorporeal rat lung model 10 lungs, each, were preserved with Celsior (CE) and Celsior/prostacyclin (CEPC, 6 microg/100 ml) at 4 degrees and 15 degrees C, each, and compared to low-potassium Euro-Collins (EC-40, 40 mmol/liter potassium). After 2 hours of ischemia lungs were reventilated and reperfused using a roller pump. Oxygenation in terms of oxygen partial tension in the left atrial effluent, pulmonary vascular resistance (PVR), peak inspiratory pressure, and wet/dry ratio were monitored for 50 minutes. Furthermore, edema formation was evaluated by light microscopy. Statistical analysis was performed using ANOVA models.

RESULTS

Compared to the EC-40 group, oxygenation was increased and amount of edema was reduced in most Celsior-preserved organs (p<0.032) with exception of the CEPC group at 4 degrees C (p = 0.06). Additional application of prostacyclin did not have any significant effect on oxygenation in the Celsior group. However, after temperature elevation of the CEPC perfusate to 15 degrees C, a superior partial tension of oxygen was observed (p<0.023) in contrast to the 4 degrees C groups CE and CEPC. The lowest PVR was found in the CE 4 degrees C group (p<0.02).

CONCLUSIONS

Celsior provides better lung preservation than EC-40 solution. Application of prostacyclin at higher perfusate temperatures results in additional functional improvement. In vivo experiments and ultrastructural analysis are warranted for further evaluation of Celsior in lung preservation.

Combined lung and liver transplantation in a girl with cystic fibrosis

PURPOSE

To describe the anesthetic considerations of a combined lung and liver transplant in a 14-yr-old girl with cystic fibrosis.

CLINICAL FEATURES

A 14 yr-old girl with cystic fibrosis presented for combined liver and lung transplantation. Anesthetic management was complex in that the pulmonary, hemodynamic, and hematological changes after cardiopulmonary bypass and lung transplantation made the management of the subsequent liver transplant unique. We used a moderate dose fentanyl and isoflurane anesthetic with invasive monitoring including a pulmonary artery catheter. Upon reperfusion of the new liver our patient exhibited severe pulmonary hypertension that was associated with a decrease in cardiac output and systemic hypotension. Utilizing a pulmonary artery catheter, this episode was treated with an increase of prostaglandin E1 (PGE1) infusion to 0.025 microg x kg(-1) x min(-1) and the initiation of 3 microg x kg(-1) x min(-1) dobutamine. The pulmonary hypertension resolved and the cardiac output and blood pressure returned to baseline levels.

CONCLUSION

The anesthetic considerations for a combined lung and liver transplant are complex because of the interactions and alterations in cardiovascular, pulmonary and hemostatic systems. The use of a pulmonary artery catheter was critical to the management of our patient because it allowed us to accurately treat an episode of hypotension occurring during liver transplantation. This episode was secondary to acute pulmonary hypertension which is common after pulmonary transplantation but unusual during liver transplantation. It is also critical that a team approach is used to consider all of the concerns of the multiple services managing these complex patients.

Celsior solution for improvement of currently used clinical standards of lung preservation in an ex vivo rat model

OBJECTIVE

The introduction of Euro-Collins solution with its intracellular electrolyte composition has allowed for clinically accepted pulmonary preservation for up to 7 h of ischemic time. In recent years several alternative solutions have been developed for the improvement of pulmonary preservation. Celsior is an extracellular solution which has significantly reduced the ischemia/reperfusion (IR)-induced pulmonary damage in animal studies. So far, no larger experimental studies exist concerning the influence of Celsior on pulmonary gas exchange following IR.

METHODS

In an extracorporeal rat lung model ten lungs, were each preserved with Celsior (CE) and Celsior/ prostacycline (CEPC, 6 mg/100 ml) at 4 degrees C and compared with preservation with low-potassium-Euro-Collins solution (LPEC, 40 mmol/l of potassium). After 2 h of ischemia the lungs were re-ventilated and reperfused using a roller-pump. Relative oxygenation capacity (ROC), pulmonary vascular resistance (PVR), peak inspiratory pressure (PIP) and wet/dry ratio were monitored for 50 min. Statistical analysis was performed using ANOVA.

RESULTS

ROC was increased in all Celsior preserved organs compared with the EC group (P < 0.032). Though the CEPC group was found to have the lowest PIP and the least amount of lung water as assessed by wet/dry ratio, PVR was highest after 30-50 min. The significantly lowest PVR was determined in the CE group (P < 0.02).

CONCLUSIONS

Celsior provides better lung preservation than LPEC solution, as demonstrated by a significantly increased oxygenation ability, a lower PVR and a decreased wet/ dry ratio. In vivo experiments and additional histological analysis are warranted for further evaluation of Celsior in lung preservation.

Perfusão pulmonar anterógrada "versus" retrógrada na preservação pulmonar para transplante em modelo canino de viabilidade pulmonar pós-morte

A doação pulmonar após parada cardiocirculatória tem sido estudada experimentalmente na obtenção de órgãos para transplante, porém a severa lesão isquêmica/reperfusão exigem métodos de preservação que permitam viabilidade pulmonar. A perfusão do enxerto com solução cristalóide hipotérmica via anterógrada (artéria pulmonar) é o método de preservação mais utilizado, porém esta via não perfunde a circulação brônquica, permitindo a retenção sanguínea neste território capaz de desencadear fenômenos de lesão de reperfusão. Isto nos levou a testar os efeitos da perfusão anterógrada versus retrógrada (via átrio esquerdo, capaz de perfundir a circulação brônquica) em modelo canino de transplante unilateral cujos pulmões foram extraídos 3 horas após parada cardiorrespiratória. Doze cães doadores foram sacrificados com tiopental sódico e mantidos à temperatura ambiente sob ventilação mecânica durante 3 horas, após as quais os animais foram randomizados e os blocos cardiopulmonares perfundidos via retrógrada (n = 6) ou anterógrada (n = 6) com solução de Euro-Collins modificada e extraídos. Os receptores (n = 12) foram anestesiados, pneumonectomizados e submetidos a transplante pulmonar esquerdo recebendo enxertos perfundidos por via retrógrada (grupo I) ou anterógrada (grupo II). Após a reperfusão do enxerto, os animais foram mantidos sob ventilação mecânica (FiO2 = 1) por 6 horas, sendo então sacrificados. Durante este período obtiveram-se medidas hemodinâmicas e gasometrias arteriais, além de amostras de tecido pulmonar para dosagem de ATP intracelular. As medidas hemodinâmicas não diferiram entre os grupos. Nos animais do grupo I a PaO2 e PaCO2 foram superiores às do grupo II (p = 0,016 e p = 0,008, respectivamente). O ATP intracelular não diferiu entre os grupos, embora tenha se reduzido nas amostras obtidas na extração do enxerto do doador quando comparados aos valores após a reperfusão (p = 0,01) e ao término do período de avaliação (p = 0,01). Os autores concluem que, neste modelo experimental, a perfusão retrógrada hipotérmica resulta em função superior do enxerto após 3 horas de isquemia normotérmica sob ventilação mecânica.

Plasma thromboxane B2 concentrations and pulmonary vascular resistance during lung reperfusion

The purpose of this study was to measure the behavior of plasmatic thromboxane B2 (pITxB2) after reperfusion of a glucose-insulin-potassium preserved lung. Seven adult mongrel dogs underwent a left lung allotransplantation. Hemodynamic changes including pulmonary artery pressure and cardiac output were measured. Pulmonary artery vascular resistance, systemic resistance, arterio-venous oxygen difference, and shunt were calculated. Immunoreactive arterial and venous plasma thromboxane B2 concentrations were measured at 0 (basal), 60, 120, and 180 min after reperfusion. Hemodynamic measurements were made after 5 min of occlusion of the right pulmonary artery and ventilation with 100% oxygen. Prepreservation, pre-reperfusion, and posttransplant lung weights were obtained. All animals survived the procedure. Ischemic time was 14.72 (+/-0.31) h. Cardiac output, systemic arterial pressure, and arterio-venous oxygen difference decreased while systemic vascular resistance, pulmonary vascular resistance, and shunt increased during the study. Mean pulmonary artery pressure correlated with pulmonary vascular resistance (p < .01). Oxygen tension diminished significantly at 180 min after reperfusion. Mean basal pulmonary arterial TxB2 was 3589 (+/-424) pg/ml; mean plasma pulmonary venous TxB2 was 6578 (+/-1571) pg/ml. Pulmonary arterial to venous TxB2 ratio (a/vTxB2) increased from 0.70 at basal measurement to 0.83 at 60 min, and 0.99 at 120 and 180 min after reperfusion (p < .05). Pulmonary arterial TxB2 had a positive correlation with mean pulmonary artery pressure (p < .05); also, a/v pITxB2 correlated with pulmonary vascular resistance (r = .616, p < .01). Mean post-reperfusion lung weight increase was 74.88% (45.37 g). In conclusion, pITxB2 a/v ratio ratio increases after reperfusion of a 14-h preserved lung; pulmonary vascular resistance significantly increases after 180 min of reperfusion and correlates with the increase in pITxB2 a/v ratio.

Perioperative anaesthetic considerations for patients undergoing lung transplantation

PURPOSE

Five thousand, two hundred and eight lung transplants were performed worldwide before April, 1996. This review will discuss lung transplantation from an historical perspective, its indications, donor and recipient selection criteria, donor lung preparation, surgical considerations, perioperative anaesthetic management, and associated morbidity and mortality.

SOURCE

Recent literature on perioperative anaesthetic management of lung transplantation and experience from international centres including the Toronto Lung Transplant Group and the St. Louis Lung Transplant Group.

PRINCIPAL FINDINGS

Lung transplantation comprises of a family of operations, including single lung transplant, bilateral single lung transplant, lobar transplant and block heart-lung transplant. Improved donor lung preservation techniques have increased the duration of cold ischaemic time. The advent of bilateral single lung transplant has decreased the requirement for cardiopulmonary bypass, and airway complications have been reduced by adoption of the telescoping bronchial anastomoses. Advances in perioperative monitoring (including transoesophageal echocardiography), pulmonary vasodilators (e.g., nitric oxide and prostaglandin E1), cardiopulmonary bypass and ventilatory management, and a better understanding of the pathophysiological processes during the procedure have improved perioperative anaesthetic management. Also, advances in broad spectrum antibiotics and immunosuppressant drugs have improved the outcome by better management of the complications of infection and rejection.

CONCLUSION

Lung transplantation improves the quality of life with marginal improvement in life expectancy of the recipients. It is an expensive procedure requiring continued resources for long term management of these patients.

Donor pretreatment with intravenous prostacyclin versus inhaled nitric oxide in experimental lung transplantation

The pulmonary vasodilatory effects of prostacyclin (PGI2) were compared with inhaled nitric oxide (NO) for donor treatment in an acute double lung transplantation model in the rat. The PGI2 group (n=10) received 35 microg/kg PGI2 both intravenously and into the flush solution. The NO group (n=10) was ventilated before and during perfusion with nitric oxide for an expiratory NO concentration of 20 ppm. Both groups were compared with untreated controls (n=10). Following cold ischemia of 16 hr the donor lungs were implanted in syngeneic recipients via specially designed stents to the left pulmonary artery and vein. Separate graft ventilation permitted determination of compliance and resistance. During 120 min of reperfusion serial measurements of graft pulmonary vascular resistance (PVR) and alveolar arterial oxygen difference (AAD02) were obtained. Final graft assessment included weight gain and histological analysis. Data are listed as mean+/-SE. The type of donor pretreatment had a definite and negative impact on survival (NO: 106+/-6, controls: 116+/-4, PGI2: 120+/-0 min; P<0.02) and overall graft function. During reperfusion the compliance was significantly reduced in NO (23+/-4) in comparison with controls (34+/-3) and PGI2 (50+/-4 ml/cmH2O; P<0.01). The PVR was 785+/-238 in NO, 240+/-60 in controls and 181+/-71 mmHg/ml/min in PGI2 (P<0.02). The AaD02 was compromised in NO (486+/-44) compared with controls (396+/-53) and PGI2 (108+/-34 mmHg; P<0.02). The weight increase at the end of reperfusion amounted to 101+/-17% in NO, 98+/-13% in controls, and 69+/-7% in PGI2 (P<0.05). Histological analysis showed significantly more interstitial edema in the NO group. In conclusion, PGI2 administration significantly improves global lung function while the inhalation of nitric oxide before and during donor perfusion has a detrimental effect on the quality of graft preservation.

Relative importance of prostaglandin/cyclic adenosine monophosphate and nitric oxide/cyclic guanosine monophosphate pathways in lung preservation

BACKGROUND

Modulation of vascular tone and platelet and neutrophil function through the prostaglandin/cyclic adenosine monophosphate or nitric oxide/cyclic guanosine monophosphate pathway can benefit lung graft function. The relative importance of these pathways is unclear.

METHODS

Rat lung grafts (5 per group) were studied in an ex vivo reperfusion model. Group I grafts were pretreated with prostacyclin (20 ng.kg-1.min-1), flushed with cold Euro-Collins solution containing prostacyclin (200 micrograms/L), and reperfused immediately for 1 hour. Group II grafts were similarly procured but were stored at 4 degrees C for 6 hours before reperfusion. In group III, no prostacyclin therapy was used; instead, the nitric oxide donor glyceryl trinitrate (0.1 mg/mL) was added to the flush/storage solution, and the grafts were stored for 6 hours.

RESULTS

Group II grafts performed poorly compared with those in group I, with substantial deterioration of oxygenation and blood flow and elevation of pulmonary artery pressure, peak airway pressure, and wet to dry weight ratio. In contrast, graft function in group III was similar to that in controls.

CONCLUSIONS

Lung graft integrity after storage in Euro-Collins solution was better preserved by glyceryl trinitrate than by prostacyclin in this model.

cAMP-mediated vascular protection in an orthotopic rat lung transplant model. Insights into the mechanism of action of prostaglandin E1 to improve lung preservation

Prostaglandin E1 (PGE1) is often added to the donor pulmonary flush solution to enhance clinical lung preservation for transplantation. Although PGE1 is thought to act as a pulmonary vasodilator during the harvest period, the precise mechanism(s) of action whereby PGE1 enhances lung preservation is unknown. Because cAMP levels decline in endothelial and vascular smooth muscle cells exposed to hypoxia, we hypothesized that a PGE1-mediated increase in cAMP levels within the preserved lungs might improve pulmonary vascular homeostasis following lung transplantation. Rat lungs demonstrated a time-dependent decline in cAMP levels during hypothermic storage, with cAMP levels significantly increased by PGE1 supplementation (approximately 2-fold by 6 hours, P < .0005). To test whether augmenting cAMP levels may enhance lung preservation, experiments were performed using an orthotopic rat left lung transplant model. Compared with controls, supplementing the preservation solution with the membrane-permeable cAMP analogue dibutyryl-cAMP resulted in dose-dependent preservation enhancement, marked by reduced pulmonary vascular resistance (6.0-fold, P < .01), improved arterial oxygenation (3.0-fold, P < .01), reduced graft neutrophil infiltration (1.5-fold, P < .05), and improved recipient survival (7.0-fold, P < .005). Similar preservation enhancement was observed with another cAMP analogue (8-bromo-cAMP) or the phosphodiesterase inhibitor indolidan. Stimulating the cAMP second messenger system by PGE1 supplementation resulted in marked hemodynamic benefits and improved recipient survival, in parallel with reduced graft neutrophil infiltration, vascular permeability, and platelet deposition. These beneficial effects of PGE1 were abrogated by simultaneous administration of the cAMP-dependent protein kinase antagonist Rp-cAMPS. Although an arterial vasodilator (minoxidil) resulted in significant pulmonary vasodilation during harvest, it lacked other nonvasodilating effects of PGE1 and resulted in poor preservation. These data show that harvest vasodilation by itself is insufficient to enhance lung preservation and that PGE1 enhances lung preservation by stimulating the cAMP-dependent protein kinase and promoting non-vasodilatory mechanisms of pulmonary protection.

Heart and Heart-Lung Transplantation: An Update

Heart and heart-lung transplantation have been established as effective treatments for a wide variety of end-stage cardiopulmonary diseases. Recent years have seen refinements in surgical techniques for cardiopulmonary replacement as well as the selection and postoperative care of thoracic transplant recipients. Despite substantial clinical progress, however, significant problems remain, particularly donor organ shortage, graft rejection, opportunistic infection, and limited organ preservation techniques. Basic and clinical research are currently addressing these problems. In this brief review, we provide an update of our experiences with heart and heart-lung transplantation in the West (particularly at Stanford University), an outline of the active issues in the field, and some thoughts about the development of thoracic transplantation in Asia.

Prostaglandin E1 or prostacyclin in Euro-Collins solution fails to improve lung preservation

BACKGROUND

In search of the ideal composition of the flush solution for pulmonary preservation, we studied the effects of prostaglandin E1 (PGE1) and prostacyclin as an additive to Euro-Collins solution (ECS) on pulmonary hemodynamics and gas exchange in a porcine single lung transplantation model using extracorporeal circulation and right heart bypass.

METHODS

Twenty-two pigs served as donors. The animals were randomized to receive either modified ECS alone (control group, n = 8), ECS with 100 micrograms/L of PGE1 (PGE1 group, n = 6), or ECS with 200 micrograms/L of prostacyclin (prostacyclin group, n = 8). Left lung transplantation was performed in 22 recipients after approximately 4 hours of cold ischemia.

RESULTS

Carbon dioxide elimination was significantly depressed in the two prostaglandin groups, and the use of PGE1 was associated with a significant decrease in arterial oxygen tension compared with the control group. Both drugs were inefficient in alleviating the increase in pulmonary vascular resistance after transplantation.

CONCLUSION

The use of prostaglandins as constituents of the flush solution was not followed by any improvement of early graft function after cold ischemia.

Lung preservation with Euro-Collins, University of Wisconsin, Wallwork, and low-potassium-dextran solution. Université++ Paris-Sud Lung Transplant Group

Using isolated rat lungs, we compared prevention of ischemia-reperfusion injury provided by flushing the lungs with modified Euro-Collins solution (EC), University of Wisconsin solution (UW), low-potassium-dextran solution (LPD), or Wallwork solution (WA). After 4 hours' and 6 hours' cold ischemia, reperfusion injury was assessed on the basis of changes in filtration coefficients (Kfc) and pressure-flow curves, characterized by the slope of the curves (incremental resistance) and the extrapolation of this slope to zero flow (pulmonary pressure intercept [Ppi]). After 4 hours, Kfc and Ppi were higher with EC than with UW, LPD, and WA, and the incremental resistance was higher with EC and UW. After 6 hours, Kfc and incremental resistance Ppi were higher with LPD than with WA. Because ischemia-reperfusion injury is associated with decreased endothelial synthesis of prostacyclin and nitric oxide, we tested whether the addition of prostacyclin or the nitric oxide precursor L-arginine to WA would improve preservation. The Kfc and Ppi were lower with both treatments. In conclusion, ischemia-reperfusion injury was best prevented by using WA. The favorable effect of prostacyclin or L-arginine emphasizes the role played by endothelial dysfunction in ischemia-reperfusion injury.

Eliminating the strong pulmonary vasoconstriction caused by Euro-Collins solution

Single-flush perfusion with Euro-Collins solution (ECS), after pretreatment with prostaglandin E1 or prostacyclin, is at most centers the standard procedure for preservation of lungs for transplantation. In a previous study, we showed that the high potassium content of ECS causes strong pulmonary vasoconstriction at temperatures higher than 20 degrees C. In the present study, five drugs used as pretreatment and added to the perfusate were compared for their ability to counteract ECS-induced constriction of porcine pulmonary arteries: papaverine reduced the vasoconstrictive effect by 92% +/- 4%; nifedipine, by 62% +/- 6%; the thromboxane A2 receptor antagonist daltroban, by 15% +/- 4%; and prostaglandin E1, by 12% +/- 4%. On the other hand, prostacyclin not only failed to reduce ECS-induced vasoconstriction but at the highest concentration tested, enhanced it by 37% +/- 7%. The combination of papaverine (10(-4) mol/L) and nifedipine (10(-6.5) mol/L) was the only pretreatment to abolish ECS-induced vasoconstriction; moreover, it has no adverse effect on endothelial function. Neither prostaglandin E1 nor prostacyclin effectively counteracts ECS-induced vasoconstriction, though they may have other beneficial effects.

Lung preservation: a review of current practice and future directions

During the past 10 years, pulmonary transplantation has emerged as a successful mode of surgical therapy for suitable patients with end-stage lung disease. Current preservation techniques of donor lungs for subsequent transplantation include core-cooling and single flush perfusion. The relative merits of these are described. These methods are essentially restricted to 6 hours of ischemia. Research in lung preservation is aimed not only at extending the safe period of ischemia but also at improving the quality of preservation. Areas of interest include the ideal composition of the perfusate, relevant pharmacologic additives, and the best conditions for preservation and harvesting. Advantages and disadvantages of the various animal models are listed in addition to the methods used in assessing the quality of preservation. There have been major advances in experimental lung preservation during the past 10 years, and we are possibly on the threshold of incorporating some of these into clinical practice. Among the most important are the adoption of colloid-based perfusates, the more widespread use of free radical scavengers, and the use of leukocyte depletion.

Alterations in pulmonary surfactant composition and activity after experimental lung transplantation

Pulmonary surfactant facilitates breathing by reducing the surface tension at the air/liquid interface. We examined the effect of experimental lung transplantation on the phospholipid pool sizes of alveolar surfactant large and small aggregates, the composition of the large aggregates, the surface tension-reducing ability of lipid extract surfactant, and the leakage of serum proteins into the lung. A double-lung block from the donor animal was stored for 2 or 12 h after perfusion with either Euro-Collins solution or University of Wisconsin solution. The right donor lung was lavaged immediately after the storage period to determine the effects of storage on pulmonary surfactant. The left donor lung was transplanted. The recipient animal, containing its own native right lung and the transplanted left lung, was reperfused for 6 h. After the reperfusion period, the transplanted left lung and the native right lung were lavaged. After an ischemic time of 12 h, impaired gas exchange was observed in the transplanted lung as well as the native lung during the 6 h of reperfusion. This impaired gas exchange was associated with several significant changes in pulmonary surfactant: (1) total serum protein in the lung lavage was increased, (2) the small to large surfactant aggregate ratio was increased, (3) sphingomyelin content was increased and phosphatidylglycerol content was decreased in large aggregates, and (4) the surfactant-associated protein A content was decreased in large aggregates. No significant differences were observed between the results obtained with Euro-Collins and University of Wisconsin solutions.(ABSTRACT TRUNCATED AT 250 WORDS)

Vascular and interstitial effect of University of Wisconsin solution on canine lung

Belzer's University of Wisconsin cold storage solution (UWCSS) has proved useful in extending the shelf life of organs in extrathoracic transplantation and more recently has also been shown to be useful in heart transplantation. I investigated the effect of 4 degrees C UWCSS on the vascular and interstitial properties of the lung to see whether it affected the pulmonary microcirculation or caused pulmonary edema. Infusion of UWCSS was associated with a slight decrease in oxygen tension, but the final oxygen tension was no different from that previously demonstrated with Euro-Collins solution. Vascular conductance was not affected by UWCSS, but average vascular closure increased slightly, indicating that increased vascular tone occurs. This effect is similar to but less than that previously observed with Euro-Collins solution. Based on comparisons of wet to dry weight ratios, estimates of interstitial compliance, transvascular fluid flux, and microvascular filtration coefficient, it does not appear that UWCSS causes pulmonary edema. Further investigation into the usefulness of UWCSS in lung transplantation is therefore warranted.

University of Wisconsin solution for pulmonary preservation in a rat transplant model

University of Wisconsin and modified Euro-Collins solutions for pulmonary preservation were compared in a rat orthotopic left lung isotransplant model. Heart-lung blocks of donor rats were flushed with and preserved in one of the preservation solutions at 0 degrees C. After 6 or 12 hours of cold ischemia, the left lungs were transplanted into recipient rats and reperfused for 1 hour. Pulmonary function was assessed by measuring oxygen and carbon dioxide tensions in arterial blood after removal of the right lung. Lipid peroxide concentrations were measured as thiobarbiturate acid-reactive substances. The ratios of wet to dry weight of grafts after ischemia and after reperfusion were calculated. Histologic changes of ischemia-reperfusion injury of the lung tissue were evaluated using a graded scale. Oxygen tension after 6 hours of preservation followed by reperfusion was significantly higher with University of Wisconsin solution (308.8 +/- 81.1 mm Hg) than with Euro-Collins solution (50.8 +/- 17.8 mm Hg; p less than 0.001). Carbon dioxide tension in the University of Wisconsin solution group was also significantly lower than in the Euro-Collins solution group (28.2 +/- 2.3 versus 46.0 +/- 4.5 mm Hg; p less than 0.05). Lipid peroxide concentration after 6 hours' preservation in University of Wisconsin solution was significantly lower (0.88 +/- 0.07 mumol/g) than that in Euro-Collins solution (1.26 +/- 0.12 mumol/g; p less than 0.05). After 12 hours of preservation only lipid peroxide concentration with University of Wisconsin solution was significantly lower (1.30 +/- 0.09 mumol/g) than with Euro-Collins solution (1.71 +/- 0.15 mumol/g; p less than 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)