Changes in vascular permeability with ischemic time, temperature, and inspired oxygen fraction in isolated rabbit lungs

An extracellular oxygen carrier during prolonged pulmonary preservation improves post-transplant lung function

BACKGROUND

The use of a novel extracellular oxygen carrier (EOC) preservation additive known as HEMO2Life has recently been shown to lead to a superior preservation of different types of solid organs. Our study aimed to investigate the effect of this EOC on extending lung preservation time and its mechanism of action.

METHODS

Donor pigs were randomly allocated to either of the following 2 groups (n = 6 per group): (1) 36 hours cold preservation or (2) 36 hours cold preservation with 1 g/liter of EOC. The lungs were evaluated through 12 hours of normothermic ex vivo lung perfusion (EVLP) followed by a left-single lung transplant into a recipient pig. Grafts were reperfused for 4 hours, followed by right pulmonary artery clamping to assess graft oxygenation function.

RESULTS

During EVLP assessment, EOC-treated lungs showed improvements in physiologic parameters, whereas the control lungs deteriorated. After a total of 48 hours of preservation (36 hours cold + 12 hours normothermic EVLP), transplanted grafts in the treatment group displayed significantly better oxygenation than in the controls (PaO2/FiO2: 437 ± 36 mm Hg vs 343 ± 27 mm Hg, p = 0.041). In addition, the use of EOC led to significantly less edema formation (wet-to-dry ratio: 4.95 ± 0.29 vs 6.05 ± 0.33, p = 0.026), less apoptotic cell death (p = 0.041), improved tight junction preservation (p = 0.002), and lower levels of circulating IL-6 within recipient plasma (p = 0.004) compared with non-use of EOC in the control group after transplantation.

CONCLUSION

The use of an EOC during an extended pulmonary preservation period led to significantly superior early post-transplant lung function.

[Single-lung transplant and primary graft failure]

OBJECTIVE

To quantify primary graft failure (PGF) and its impact on perioperative and early mortality in single-lung transplant (SLT).

METHOD

We analyzed 35 SLT procedures performed using similar techniques. PGF was defined as a PaO2/FiO2 coefficient lower than 200 mmHg during the first 72 hours or ventilation assistance lasting longer than 5 days attributable to primary lung dysfunction. We defined perioperative mortality as occurring within 30 days of surgery and early mortality within 90 days.

RESULTS

Twenty-five men and 10 women received lungs, 22 for pulmonary fibrosis and 13 for emphysema; the mean age was 53.26 10.77 years. Twenty right SLTs were performed and 15 left SLTs. Twenty-nine donors were men and 6 were women, with a mean age of 29.31 12.33 years. Twenty-six died from cranial trauma, 8 from stroke and 1 from a brain tumor. The mean time of intubation was 1.69 1.35 days. The mean PaO2 was 470.71 70.82 mmHg. The mean time of ischemia was 201.77 62.64 minutes. Four patients (11.42%) developed PGF and 3 died during the perioperative period. Two additional patients died within the early postoperative period. Survival was 91.4% at one month and 85.5% at three months. The cause of donor death was the only variable that influenced the development of PGF.

CONCLUSION

We observed a low incidence of PGF and of perioperative and early mortality, with one and three month survival rates similar to those reported internationally.

Optimal alveolar oxygen concentration for cold storage of the lung

BACKGROUND

Ischemia of the lung is different from that of solid organs because the lung contains gas in the alveoli. However, the optimal gas composition in the alveoli during cold storage remains uncertain. We investigated the relationship between the alveolar oxygen concentration and reperfusion injury.

METHODS

The lungs inflated with 0% O2, 5% O2, room air, 50% O2, or 100% O2 were reperfused after 8 hR storage at 4 degrees C and pulmonary functions were measured for 120 min using an ex vivo rat lung model. The levels of high-energy phosphate and lipid peroxidation of the lung were analyzed after a PA flush, preservation, and reperfusion. Additionally, respiration of the mitochondria in the lungs was measured after preservation.

RESULTS

The pulmonary functions were significantly superior in the 5% O2 group than those in the 0% O2, 50% O2, and 100% O2 groups. Pulmonary edema developed in the 0% O2, 50% O2, and 100% O2 groups, but not in the 5% O2 group. After preservation, the energy level in the lungs decreased only in the 0% O2 group. Although lipid peroxidation of the lungs did not increase in any group after preservation, significant increases were observed in the room air, 50% O2 and 100% O2 groups after reperfusion. State 3 and 4 ratios of the mitochondrial respiration significantly decreased in the lungs of the room air, 50% O2 and 100% O2 groups.

CONCLUSIONS

Although the cold-preserved lungs require oxygen, hyperoxygenation induced mitochondrial dysfunction and increased lipid peroxidation and led to deleterious lung function after reperfusion. Therefore, hypoxic conditions that can maintain the energy level of the lung during cold storage would be optimal.

Ischemia-reperfusion lung injury in rabbits: mechanisms of injury and protection

To study the mechanisms responsible for ischemia-reperfusion lung injury, we developed an anesthetized rabbit model in which the effects of lung deflation, lung inflation, alveolar gas composition, hypothermia, and neutrophils on reperfusion pulmonary edema could be studied. Rabbits were anesthetized and ventilated, and the left pulmonary hilum was clamped for either 2 or 4 h. Next, the left lung was reperfused and ventilated with 100% oxygen. As indexes of lung injury, we measured arterial oxygenation, extravascular lung water, and the influx of a vascular protein (131I-labeled albumin) into the extravascular space of the lungs. The principal results were that 1) all rabbits with the deflation of the lung during ischemia for 4 h died of fulminant pulmonary edema within 1 h of reperfusion; 2) inflation of the ischemic lung with either 100% oxygen, air, or 100% nitrogen prevented the reperfusion lung injury; 3) hypothermia at 6-8 degreesC also prevented the reperfusion lung injury; 4) although circulating neutrophils declined during reperfusion lung injury, there was no increase in interleukin-8 levels in the plasma or the pulmonary edema fluid, and, furthermore, neutrophil depletion did not prevent the reperfusion injury; and 5) ultrastructural studies demonstrated injury to both the lung endothelium and the alveolar epithelium after reperfusion in deflated lungs, whereas the inflated lungs had no detectable injury. In summary, ischemia-reperfusion injury to the rabbit lung can be prevented by either hypothermia or lung inflation with either air, oxygen, or nitrogen.

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.

When does the lung die? Kfc, cell viability, and adenine nucleotide changes in the circulation-arrested rat lung

Lungs harvested from cadaveric circulation-arrested donors may increase the donor pool for lung transplantation. To determine the degree and time course of ischemia-reperfusion injury, we evaluated the effect of O2 ventilation on capillary permeability [capillary filtration coefficient (Kfc)], cell viability, and total adenine nucleotide (TAN) levels in in situ circulation-arrested rat lungs. Kfc increased with increasing postmortem ischemic time (r = 0.88). Lungs ventilated with O2 1 h postmortem had similar Kfc and wet-to-dry ratios as controls. Nonventilated lungs had threefold (P < 0.05) and sevenfold (P < 0.0001) increases in Kfc at 30 and 60 min postmortem compared with controls. Cell viability decreased in all groups except for 30-min postmortem O2-ventilated lungs. TAN levels decreased with increasing ischemic time, particularly in nonventilated lungs. Loss of adenine nucleotides correlated with increasing Kfc values (r = 0.76). This study indicates that lungs retrieved 1 h postmortem may have normal Kfc with preharvest O2 ventilation. The relationship between Kfc and TAN suggests that vascular permeability may be related to lung TAN levels.

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.

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

BACKGROUND

Early allograft dysfunction remains a frequently encountered problem in clinical lung transplantation. Lung ischemia-reperfusion injury is associated with increased vascular permeability, which may be due in part to oxygen (O2) free radicals. However, it is not clear whether O2 free radicals are produced during ischemia under storage conditions in clinical lung transplantation.

METHODS

Using an isolated ex vivo rabbit lung model, we studied the effects of preservation temperature on pulmonary capillary filtration coefficient (Kf) and lipid peroxidation in rabbit lungs inflated with 100% O2 after preservation with or without the O2 free radical scavenger dimethylthiourea. New Zealand white rabbits weighing 2.7 to 3.1 kg were intubated and ventilated with room air or 100% O2 (tidal volume = 25 mL). After heparinization and sternotomy, the pulmonary artery was flushed with low-potassium-dextran-1% glucose solution (200 mL). The heart-lung block was excised, submerged, and stored for 24 hours at 1 degree or 10 degrees C. After 24-hour preservation, the heart-lung block was suspended from a strain-gauge force transducer and ventilated with room air. The pulmonary artery cannula was connected to a reservoir of hetastarch solution. The lungs were flushed briefly with the hetastarch solution, and the reservoir was raised sequentially at 8-minute intervals to achieve 1.0 to 1.5 mm Hg increments in pulmonary artery pressure. Lung weight gain, airway pressure, pulmonary artery pressure, and left atrial pressure were measured continuously. The slope of steady-state lung weight gain was used to determine Kf (g.min-1.cm H2O-1 x 100 g-1 wet weight).

RESULTS

Twenty-four-hour lung preservation at both 1 degree and 10 degrees C increased Kf. A similar increase in Kf was observed in lungs stored at 1 degree C while inflated with 100% O2. However, a significant increase in Kf was observed when lungs inflated with 100% O2 were stored at 10 degrees C. This increase in Kf was ameliorated by dimethylthiourea. Thiobarbituric acid-reactive substance levels were increased in lungs stored at 10 degrees C while inflated with 100% O2. This finding was eliminated by dimethylthiourea.

CONCLUSIONS

These results indicate that free radical injury occurs during the ischemic phase when lungs are stored at moderate hypothermia while inflated with 100% O2.