Extended preservation of the ischemic canine lung by ventilation with PEEP

Hyperinflation during lung preservation and increased reperfusion injury1

BACKGROUND

Reperfusion injury after lung transplantation remains a perplexing and unpredictable problem. Most surgeons preserve the lung inflated, but the amount of inflation that should be used is not well documented. Therefore, we studied the effect of high inflation during organ preservation on lung function during reperfusion. Our hypothesis is that donor lung hyperinflation during storage contributes to early allograft dysfunction during reperfusion.

METHODS

To test our hypothesis we used an isolated, blood-perfused, ventilated rabbit lung model. Group I lungs (control) underwent immediate reperfusion after harvest. Group II lungs (low-inflation, maintained at 6 mmHg airway pressure) and group III lungs (high-inflation, maintained at 20 mmHg airway pressure) were stored for 4 h in 4 degrees C Euro-Collins solution after harvest. All lungs were then reperfused with whole blood for 1 h, and measurements of arterial oxygenation (PO2, mmHg), pulmonary artery pressure (PAP, mmHg), peak inspiratory pressure (PIP, cm H2O), and wet-to-dry weight ratio (WTD) were obtained.

RESULTS

Throughout the 1 h reperfusion period group III lungs had significantly lower oxygenation compared to groups I and II. In addition, throughout reperfusion, group III lungs showed significantly higher PAP and PIP compared to group II. WTD did not differ significantly between groups, however, there was a trend toward increased edema in group III.

CONCLUSIONS

These results indicate that high inflation during cold storage results in acute pulmonary dysfunction. Careful monitoring of airway inflation pressure during storage, especially to prevent hyperinflation, should be maintained in the current practice for lung transplantation.

Non-heart-beating donors

The widespread application of lung transplantation is limited by the shortage of suitable donor organs resulting in longer waiting times for listed patients with a substantial risk of dying before transplantation. To overcome this critical organ shortage, some transplant programs have now begun to explore the use of lungs from circulation-arrested donors, so called non-heart-beating donors (NHBDs). This review outlines the different categories of NHBDs, the relevant published experimental data that support the use of lungs coming from these donors and the clinical experience worldwide so far. Techniques for NHBD lung preservation and pretransplant functional assessment are reviewed. Ethical issues involved in transplanting lungs from asystolic donors are discussed.

Lung transplantation from ventilated non-heart-beating donors: experimental study in a neonatal swine model

BACKGROUND/PURPOSE

A shortage of transplantable lungs is a constant and frustrating reality. The use of organs retrieved from ventilated non-heart-beating donors (VNHBD) may alleviate this problem. The purpose of this work was to assess lung function of donor grafts subjected to different time lengths of in situ warm ischemia (WIT).

METHODS

Twenty piglets weighing between 6 and 8 kg were allocated randomly to the following study groups: Sham (n = 5), heart-beating donors, non warm ischemia; I-30 (n = 5), I-60 (n = 5) and I-90 (n = 5), VNHBD-WIT of 30, 60, and 90 minutes, respectively. Recipients were rendered dependent on the single left transplanted lung by clamping right pulmonary artery and bronchus 1 hour after transplantation. Assessment of pulmonary function was monitored hourly by hemodynamic, oxygenation, and pulmonary mechanic measurements during a period of 6 hours after reperfusion. Lung grafts were weighed pre- and posttransplantation.

RESULTS

Final mean lung weight was significantly greater in VNHBD (92.5+/-3.1 v Sham values 75.6 g+/-2.4; P < .01). Cold ischemic time averaged 80.1+/-2.7 minutes. After right lung exclusion, hemodynamic changes consisted of a sustained increase in pulmonary vascular resistance and a reduction in cardiac output. Lung mechanics also deteriorated with a gradual rise in airway resistance and a fall in compliance.

CONCLUSIONS

These data suggest that posttransplantation lung graft function from VNHBD with up to 90 minutes of WIT, is preserved and equivalent to those achieved by grafts harvested after heart-beating donation.

Effect of ventilation on vascular permeability and cyclic nucleotide concentrations in ischemic sheep lungs

Ventilation during ischemia attenuates ischemia-reperfusion lung injury, but the mechanism is unknown. Increasing tissue cyclic nucleotide levels has been shown to attenuate lung ischemia-reperfusion injury. We hypothesized that ventilation prevented increased pulmonary vascular permeability during ischemia by increasing lung cyclic nucleotide concentrations. To test this hypothesis, we measured vascular permeability and cGMP and cAMP concentrations in ischemic (75 min) sheep lungs that were ventilated (12 ml/kg tidal volume) or statically inflated with the same positive end-expiratory pressure (5 Torr). The reflection coefficient for albumin (sigmaalb) was 0.54 +/- 0.07 and 0.74 +/- 0. 02 (SE) in nonventilated and ventilated lungs, respectively (n = 5, P < 0.05). Filtration coefficients and capillary blood gas tensions were not different. The effect of ventilation was not mediated by cyclic compression of alveolar capillaries, because negative-pressure ventilation (n = 4) also was protective (sigmaalb = 0.78 +/- 0.09). The final cGMP concentration was less in nonventilated than in ventilated lungs (0.02 +/- 0.02 and 0.49 +/- 0. 18 nmol/g blood-free dry wt, respectively, n = 5, P < 0.05). cAMP concentrations were not different between groups or over time. Sodium nitroprusside increased cGMP (1.97 +/- 0.35 nmol/g blood-free dry wt) and sigmaalb (0.81 +/- 0.09) in nonventilated lungs (n = 5, P < 0.05). Isoproterenol increased cAMP in nonventilated lungs (n = 4, P < 0.05) but had no effect on sigmaalb. The nitric oxide synthase inhibitor NG-nitro-L-arginine methyl ester had no effect on lung cGMP (n = 9) or sigmaalb (n = 16) in ventilated lungs but did increase pulmonary vascular resistance threefold (P < 0.05) in perfused sheep lungs (n = 3). These results suggest that ventilation during ischemia prevented an increase in pulmonary vascular protein permeability, possibly through maintenance of lung cGMP by a nitric oxide-independent mechanism.

Warm ischemic tolerance in collapsed pulmonary grafts is limited to 1 hour

OBJECTIVE

To determine the length of warm ischemic tolerance in pulmonary grafts from non-heart-beating donors.

SUMMARY BACKGROUND DATA

If lungs could be retrieved for transplant after circulatory arrest, the shortage of donors might be significantly alleviated. Great concern, however, exists about the length of tolerable warm ischemia before cold preservation of pulmonary grafts retrieved from such non-heart-beating donors.

METHODS

The authors compared the influence of an increasing postmortem interval on graft function in an isolated, room air-ventilated rabbit lung model during blood reperfusion up to 4 hours. Four groups of cadavers (four animals per group) were studied. In group 1, lungs were immediately reperfused. In the other groups, cadavers with lungs deflated were left at room temperature for 1 hour (group 2), 2 hours (group 3), or 4 hours (group 4).

RESULTS

Pulmonary vascular resistance was enhanced in all ischemic groups compared with the control group. An increase was noted with longer postmortem intervals in peak airway pressure and in weight gain. A concomitant decline was observed in the venoarterial oxygen pressure gradient caused by progressive edema formation, as reflected by the wet-to-dry weight ratio at the end of reperfusion.

CONCLUSIONS

Warm ischemia resulted in increased pulmonary vascular resistance. Graft function in lungs retrieved 1 hour after death was not significantly worse than in nonischemic lungs. Therefore, 60 minutes of warm ischemia with the lung collapsed may be tolerated before cold storage. Further studies are necessary to investigate whether lungs retrieved from non-heart-beating donors will become a realistic alternative for transplant.

Warm ischemic time tolerance after ventilated non-heart-beating lung donation in piglets

OBJECTIVE

The availability of lungs for transplantation could be ameliorated with the use of organs retrieved from ventilated non-heart-beating donors (VNHBD). The aim of this work is to determine the limit to tolerable in situ warm ischemia time (WIT) for lung grafts after circulation is stopped.

METHODS

Twenty piglets underwent left lung allotransplantation. Animals were randomly allocated based on the donor's status before lung harvesting into the following study groups: Sham (n = 5), Heart-beating donors-non-warm ischemia; I-30 (n = 5), I-60 (n = 5) and I-90 (n = 5), VNHBD-WIT of 30, 60 and 90 min, respectively. Right pulmonary artery and bronchus were permanently occluded one hour after transplantation. Assessment of pulmonary function was monitored hourly by hemodynamic, oxygenation and pulmonary mechanic measurements during a period of 6 h after reperfusion. Lung grafts were weighed pre- and post-transplantation.

RESULTS

Cold ischemic time was similar for all groups, and averaged 80.1+/-2.7 min. Final mean lung weight was significantly greater in VNHBD (92.5+/-3.1 g vs. Sham values 75.6+/-2.4 g, P < 0.01). After right lung exclusion, hemodynamic changes consisted of a sustained increase in pulmonary vascular resistance and a reduction in cardiac output. Lung mechanics also modified, with a rise in airway resistance and a fall in compliance.

CONCLUSIONS

Post-transplantation lung graft function from VNHBD with up to 90 min of WIT, is equivalent to those achieved by grafts harvested after heart-beating donation. This method may be a promising strategy of increasing the pulmonary donor pool.

Vascular distension and continued ventilation are protective in lung ischemia/reperfusion

Biophysical factors have been implicated in the development of pulmonary ischemia-reperfusion injury. In isolated rabbit lungs, the impact of vascular and alveolar distension, with and without alveolar oxygen supply, was investigated. With interruption of both perfusion (zero intravascular pressure) and ventilation, reperfusion after 120 min of warm ischemia resulted in transient pulmonary hypertension, with largely unchanged microvascular pressures, followed by a dramatic leakage response with approximately 10-fold increased capillary filtration coefficients (Kfc) and severe edema. Maintenance of vascular distension during ischemia (intravascular pressure of approximately 2 to 3 mm Hg) reduced the hypertension and fully suppressed the leakage. Employing ischemic periods of 180 and 240 min, ventilation of the lungs with 21 or 100% oxygen > ventilation with nitrogen during perfusion stop, but not static anoxic inflation, further enhanced the protective effect of vascular distension. At optimal biophysical support (vascular distension and ongoing normoxic ventilation), even 240 min of warm ischemia was tolerated with only moderate Kfc increase. We conclude that biophysical factors exert marked influence on pulmonary ischemia-reperfusion injury. Maintenance of vascular distension possesses strong protective potency, further enhanced by continued ventilation and alveolar oxygen supply during ischemia. These results may have important implications for organ preservation in lung transplantation.

Hyperinflation of canine lung allografts during storage increases reperfusion pulmonary edema

The optimal state of inflation for lung allografts during preservation is not known. We previously showed that hyperinflation of canine lung allografts during storage improved posttransplant graft function as measured during 10 minutes of contralateral pulmonary artery occlusion. However, we have also shown that hyperinflation during storage increases pulmonary capillary permeability. It is possible that short-term total cardiac perfusion through the transplanted left lung (for assessment) may not adequately reproduce the clinical situation. The purpose of this study was to assess the effects of hyperinflation during storage in a canine left single-lung transplantation model in which all perfusion was continuously directed to the graft after implantation. Twenty canine left single-lung transplants were done. The lungs of donor animals were ventilated at a tidal volume of 750 ml and an inspired oxygen fraction of 100%. Donor lungs were flushed with modified Euro-Collins solution and the trachea occluded at end inspiration. For donors in groups I and III, the trachea was sealed at that postinflation volume. In groups II and IV, 200 cc of air was withdrawn from the endotracheal tube under positive pressure and the trachea sealed at the lower tidal volume. Lungs were then extracted and stored at 1 degree C for 12 hours. After the preservation period, left lung transplants were performed. After implantation in all groups, the right pulmonary artery was ligated. In groups I and II, the right bronchus was ligated and in groups III and IV the right bronchus was kept open. Subsequent allograft gas exchange and hemodynamics were assessed during a 6-hour period of reperfusion. After assessment, both lungs were excised, wet/dry lung weight ratio was calculated, and histologic examination was done. During the 6-hour assessment, lungs stored in a state of hyperinflation (groups I and III) showed rapid deterioration of gas exchange. At the final assessment, arterial oxygen tension and alveolar-arterial oxygen gradient of groups I and III were significantly worse than those of groups II and IV (group I versus group II: arterial oxygen tension 87.5 +/- 15.0 versus 373.8 +/- 65.5 mm Hg, alveolar-arterial oxygen gradient 564.4 +/- 13.2 versus 298.6 +/- 69.3 mm Hg, p < 0.05; group III versus group IV: arterial oxygen tension 245.4 +/- 33.0 versus 543.6 +/- 41.8 mm Hg, alveolar-arterial oxygen gradient 392.5 +/- 35.6 versus 120.5 +/- 34.7 mm Hg, p < 0.01). We conclude that donor lung hyperinflation during storage does not provide better posttransplant allograft function when perfusion is limited only to the allograft.

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.

Effect of inflation on adenosine triphosphate catabolism and lactate production during normothermic lung ischemia

Although few biochemical data comparing adenosine triphosphate (ATP) catabolism or lactate production in isolated deflated versus inflated lung tissue are available, most transplant centers preserve their donor lungs inflated. We measured ATP level (using high-performance liquid chromatography), energy charge, and lactate level during 2 hours of normothermic ischemia in deflated lung tissue (n = 6), in lung tissue inflated with room air (n = 6), and in lung tissue inflated with 100% oxygen (n = 6). To determine the onset of anaerobic metabolism in lung tissue inflated with 100% O2, ATP and lactate levels were measured in another group (n = 6) during 8 hours of normothermic ischemia. Rabbit lungs were flushed in situ with a modified Krebs-Henseleit solution (60 mL/kg). They were isolated and immersed in 0.9% NaCl at 37 degrees C. In deflated lung tissue, ATP level (control value, 9.4 +/- 0.58 mumol/g dry wt) decreased and lactate level (control value, 5.6 +/- 1.16 mumol/g dry wt) increased after 15 minutes of ischemia (ATP, 5.2 +/- 0.86 mumol/g dry wt; lactate, 13.3 +/- 1.58 mumol/g dry wt). When the lung was stored inflated with room air, ATP breakdown and increase of lactate concentration only occurred after 90 minutes of normothermic ischemia (at 60 minutes: ATP, 8.0 +/- 0.58 mumol/g dry wt; lactate, 6.3 +/- 1.1 mumol/g dry wt). In lungs stored inflated with 100% O2, ATP breakdown and lactate accumulation only occurred after 5 hours of normothermic ischemia (at 4 hours: ATP, 8.1 +/- 0.74 mumol/g dry wt; lactate, 5.9 +/- 1.28 mumol/g dry wt).(ABSTRACT TRUNCATED AT 250 WORDS)

An evaluation of the tolerance of the autotransplanted canine lung against warm ischemia

Left lung autotransplantation was performed in mongrel dogs to examine the limitation of tolerance of the deflated lung against warm ischemia in a warm ischemic time (WIT) range of 60-360 minutes. The animals were divided into the 4 following groups according to the duration of WIT and the use of heparin: Group 1; WIT 60-120 min., heparin (-), Group 2; WIT 120-240 min., heparin (+), Group 3; WIT 240-360 min., heparin (+), and Group 4; WIT 240-360 min., heparin (-). All the Group 1 animals tolerated a right pulmonary artery ligation on the 6th postoperative day, but some of the Group 2 animals died immediately after the reimplantation due to pulmonary edema. All the Groups 3 and 4 animals died. The PaO2 values during the right pulmonary artery occlusion, immediately after the reimplantation, correlated well with the survival of the animals. The maximum tolerable WIT of the deflated dog lung was considered to be 120 minutes.

Lung transplantation in the rat: I. Technique and survival

For immunogenetic and economical reasons, an operative technique for lung transplantation in the rat was developed. With the use of an operation microscope and 8-0, 9-0, and 10-0 sutures, the left pulmonary artery, vein, and brochus were anastomosed. The mean operation time was 4 hours; the mean graft ischemia time, 87 minutes. After frequent failures initially, due to anesthetic problems and lack of experience with microsurgical operative technique, a final peroperative survival of about 80% was obtained. Postoperative mortality approximated 50%. The main cause of postoperative death was thrombus formation at the site of an anastomosis. In a final series of 28 isogeneic transplantations, proper data for a one-month follow-up was obtained from 36% of the animals that underwent operation, a percentage comparable with initial canine pulmonary and rat renal transplantation studies. Left lung transplantation in the rat proved to be technically feasible and may provide an immunogenetically well defined and economically advantageous animal model in lung transplantation research.

Pulmonary haemodynamics and function immediately after canine left lower lobe preservation

After temporary reimplantation of the left lower lobe in dogs, the effects of various preservation techniques on the canine lung were assessed. Vascular resistance, shunt fraction, weight gain, and airway pressure were found to reflect and predict the effectiveness of various preservation techniques compared with reported survival data.

Lung preservation techniques

Some of the barriers to successful lung transplantation include the lack of acceptable methods for ischemic protection and the absence of reliable systems for preservation. The lung response to 60 minutes of warm ischemia basically consists of alveolar-capillary edema and disruption, mitochondria swelling, interstitial hemorrhage, significantly depressed pulmonary function, elevation of pulmonary vascular resistance, and considerable drop in levels of glucose, phospholipids, and adenosine triphosphate. The tolerance to warm ischemia increases to several hours with the use of different systems of ventilatory assistance with or without positive end-expiratory pressure. Several methods of preservation have been attempted: hypothermia, hyperbaria, and hypothermic pulsatile or nonpulsatile perfusion. Hypothermic pulsatile perfusion appears to offer longer periods of protection than the other methods. Longer periods of ischemia and extended preservation may be made possible by advances in the use of drug protection during warm ischemia and the utilization of intracellular colloid or noncolloid solutions for hypothermic storage or hypothermic pulsatile perfusion.