Carlos H.R. Boasquevisque

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.

Ex Vivo Adenoviral-Mediated Gene Transfer to Lung Isografts During Cold Preservation

BACKGROUND Although whole-organ gene transfer has been reported in heart and liver transplant models, it has not been well characterized in lung grafts. The aim of this study was to determine the feasibility of ex vivo gene transfer to rat lung isografts during cold preservation using an adenoviral vector. METHODS F344 rats, divided into four groups, underwent orthotopic left lung transplantation. In group I, lung grafts were flushed with adenovirus carrying the beta-galactosidase gene. After storage at 10 degrees C, grafts were implanted in recipient animals. Group II underwent the same procedure but graft storage was at 4 degrees C. Groups III (10 degrees C) and IV (4 degrees C) served as controls. On postoperative day 5, recipients were sacrificed, and native and transplanted lungs were examined. RESULTS In group I, all animals showed successful, albeit patchy, gene expression. This occurred in 2 of 4 animals in group II, the other 2 showing no expression. Transduced cells were consistent morphologically with endothelial cells and pneumocytes. A minimal mononuclear inflammatory infiltrate was present. Control groups showed no transduction. CONCLUSIONS It is feasible to perform ex vivo adenoviral-mediated gene transfer to rat lung isografts during cold preservation.

Liposome-mediated gene transfer to lung isografts

OBJECTIVES Our objective were to determine the feasibility, efficacy, and safety of in vivo and ex vivo liposome-mediated gene transfer to lung isografts. METHODS Fischer rats were divided into three main groups: (1) Nontransplant setting: Liposome-chloramphenicol acetyl transferase cDNA was intravenously injected, and lungs were harvested at different time points: 2, 6, 12, and 24 hours; 2, 5, 8, and 21 days (n = 3). Chloramphenicol acetyl transferase activity was determined in lungs, hearts, livers, and kidneys. The distribution and type of transfected cells were evaluated by in situ hybridization. Lung toxicity was assessed by arterial oxygen tension, histology, and tumor necrosis factor-alpha levels. (2) In vivo graft transfection: Left lungs were transplanted 6 hours, 4 hours, and 15 minutes after intravenous injection and were assessed for chloramphenicol acetyl transferase activity and arterial oxygen tension on postoperative day 2. (3) Ex vivo graft transfection: Grafts were infused ex vivo with either 660 micrograms (n = 3) or 330 micrograms (n = 3) of DNA complexed to liposomes and stored at 10 degrees C for 4 hours. Chloramphenicol acetyl transferase activity was assessed 44 hours after transplantation. RESULTS Transgene expression was detected in endothelial cells, macrophages, and interstitial cells. Chloramphenicol acetyl transferase activity was present as early as 2 hours, increased significantly between 6 hours and 8 days, and then decreased to minimal levels by 21 days. Chloramphenicol acetyl transferase activity was greatest in donor lungs and hearts and minimal in livers and kidneys. Arterial oxygen tension was normal in treated animals. Inflammation was minimal, and tumor necrosis factor-alpha levels increased only sevenfold in treated animals. CONCLUSION In vivo and ex vivo liposome-mediated gene transfer to lung isografts allows significant transgene expression with minimal effects on graft function.

Transforming growth factor–β1 gene transfer ameliorates acute lung allograft rejection

BACKGROUND The aim of the current work was to study the feasibility of functional gene transfer using the gene encoding for transforming growth factor-beta1, a known immunosuppressive cytokine, on rat lung allograft function in the setting of acute rejection. METHODS The rat left lung transplant technique was used in all experiments, with Brown Norway donor rats and Fischer recipient rats. After harvest, left lungs were transfected ex vivo with either sense or antisense transforming growth factor-beta1 constructs complexed to cationic lipids, then implanted into recipients. On postoperative days 2, 5, and 7, animals were put to death, arterial oxygenation measured, and acute rejection graded histologically. RESULTS On postoperative day 2, there were no differences in acute rejection or lung function between animals treated with transforming growth factor-beta1 and control animals. On postoperative day 5, oxygenation was significantly improved in grafts transfected with the transforming growth factor-beta1 sense construct compared with antisense controls (arterial oxygen tension = 411 +/- 198 vs 103 +/- 85 mm Hg, respectively; P =.002). Acute rejection scores from lung allografts were also significantly improved, corresponding to decreases in both vascular and airway rejection (vascular rejection scores: 2.0 +/- 0. 5 vs 2.8 +/- 0.6; P =.04; airway rejection scores: 1.3 +/- 0.7 vs 2. 3 +/- 0.8, respectively; P =.02). The amelioration of acute rejection was temporary and decreased by postoperative day 7. CONCLUSIONS The feasibility of using gene transfer techniques to introduce novel functional genes in the setting of lung transplantation is demonstrated. In this model of rat lung allograft rejection, gene transfer of transforming growth factor-beta1 resulted in temporary but significant improvements in lung allograft function and acute rejection pathology.

Liposome-mediated gene transfer in rat lung transplantation: A comparison between the in vivo and ex vivo approaches

OBJECTIVE We compared the efficacy of in vivo and ex vivo liposome transfection in rat lung transplantation. METHODS (1) Chloramphenicol acetyltransferase group: Fischer rats underwent isogeneic transplantation (n = 4 per group). Recipients were put to death on postoperative day 2 for chloramphenicol acetyltransferase activity. Ex vivo setting: Grafts received cDNA complexed or not with liposomes and were transplanted after 1.5 or 10 hours at 10 degreesC. In vivo setting: Donors were intravenously injected with cDNA complexed or not with liposomes. Lungs were harvested after 1.5 or 10 hours, preserved at 10 degreesC, and transplanted. (2) Transforming growth factor-beta1 group: Brown-Norway rats served as donors and Fischer rats as recipients. All grafts were preserved for 3 hours at 10 degreesC. On postoperative day 5, arterial oxygenation and histologic rejection scores were assessed. Ex vivo setting: Grafts received transforming growth factor-beta1 sense (n = 8) or antisense (n = 7) complexed with liposomes or cDNA alone (n = 5). In vivo setting: Donors were intravenously injected with liposome:transforming growth factor-beta1 sense cDNA (n = 7). Exposure time was 3 hours. RESULTS (1) Chloramphenicol acetyltransferase-transfection was superior in the ex vivo group but was not statistically different for longer exposure times. (2) Transforming growth factor-beta1-arterial oxygenation was superior in the ex vivo liposome:sense group. cDNA alone was inefficient. Rejection scores were not statistically different between ex vivo and in vivo liposome:sense groups but were better when the ex vivo liposome:sense group was compared with the cDNA alone or the antisense groups. CONCLUSIONS (1) With current liposome technology, the ex vivo route is superior to the in vivo approach; (2) cDNA alone does not provide transgene expression at levels to produce a functional effect.

Exhaled Nitric Oxide Correlates With Experimental Lung Transplant Rejection

BACKGROUND Increased nitric oxide production accompanies acute lung allograft rejection. Transforming growth factor-beta1 is an immunosuppressive cytokine capable of ameliorating acute rejection. The purpose of this study was to determine whether exhaled nitric oxide (eNO) concentrations correlated with the degree of acute rejection. METHODS A model of acute lung transplant rejection in the rat was developed, and concentrations of eNO were measured at the time of animal sacrifice. In group 1 (partial immunosuppression), donor lungs were pretreated with transforming growth factor-beta1 before implantation. In group 2 (fulminant acute rejection), no immunosuppression was used. In group 3 (full immunosuppression), recipients received cyclosporine. Group 4 were normal rats. RESULTS When measured from both lungs, eNO concentrations were 4.97+/-0.68 versus 6.73+/-2.90 ppb for groups 1 and 2, respectively (p = 0.58). When measured selectively from transplanted left lungs, eNO concentrations were 8.61+/-0.97 versus 42.14+/-7.27 ppb, respectively (p<0.001). In groups 3 and 4, eNO concentrations were 1.02+/-0.21 and 1.51+/-0.74 ppb, respectively. CONCLUSIONS Exhaled nitric oxide is elevated in fulminant acute rejection, is reduced after partial immunosuppression using transforming growth factor-beta1 gene therapy, and is in the normal range in cyclosporine-treated animals. The measurement of eNO correlates with the degree of acute lung allograft rejection and may serve as a noninvasive measure of acute lung transplant rejection in the clinical setting.

Ex vivo liposome-mediated gene transfer to lung isografts

OBJECTIVE Gene therapy is a promising strategy to modify ischemia-reperfusion injury and rejection after transplantation. We evaluated variables that may affect ex vivo gene transfer to rat lung isografts. METHODS Left lungs were harvested and perfused via the pulmonary vein with chloramphenicol acetyltransferase complementary deoxyribonucleic acid complexed with cationic liposomes. Several variables were examined: (1) Influence of temperature: In group I (n = 4), grafts were stored for 4 hours at 23 degrees C and transplanted. Chloramphenicol acetyltransferase activity was assessed on postoperative day 2. In groups II and III (n = 4), grafts were stored at 10 degrees and 4 degrees C, respectively. Arterial oxygen tension and inflammatory infiltrate were also determined. (2) Influence of storage time: Grafts were preserved at 10 degrees C for 1, 2, 3, 4 (n = 4), and 10 hours (n = 5). chloramphenicol acetyltransferase activity was assessed on postoperative day 2. (3) Rapidity and duration of transgene expression: Grafts were preserved at 10 degrees C for 1 hour and then transplanted. Chloramphenicol acetyltransferase activity was assessed 2, 4, 6, 12, and 24 hours and 2, 7, 14, 21, and 28 days after implantation. RESULTS Chloramphenicol acetyltransferase expression was apparently less in lungs transfected at 4 degrees C than in those transfected at 10 degrees and 23 degrees C. Storage for 1 hour at 10 degrees C was sufficient to yield significant expression. Increasing the exposure time to 10 hours did not increase toxicity. There were no differences in arterial oxygen tension between transfected and nontransfected lungs. Chloramphenicol acetyltransferase expression was detected for at least 28 days. CONCLUSION Ex vivo liposome-mediated transfection of lung isografts can be achieved after a short time of cold storage, with minimal toxicity.

Recombinant kunitz protease inhibitor ameliorates reperfusion injury in rat lung transplantation

BACKGROUND Recombinant Kunitz protease inhibitor (rKPI-BG022) is more homologous to human Kunitz protease inhibitor than is aprotinin. Because aprotinin has been reported to inhibit free radicals, we hypothesized that rKPI would ameliorate reperfusion injury caused by free radicals. We examined its effect and the timing of administration in an in vivo rat lung transplantation model. METHODS All lungs were flushed with low-potassium dextran-1% glucose solution and stored for 24 hours at 4 degrees C, then orthotopic left lung transplantations were performed. Rats were divided into 4 groups (n=6) as follows: group 1 served as control; in Group 2, rKPI was added to the flush solution (10 micromol/L); in group 3, rKPI (5 mg/kg) was administered intravenously to the recipient just after reperfusion; and in group 4, rKPI was added to the flush solution (10 micromol/L) and rKPI (5 mg/kg) was administered intravenously to the recipient just after reperfusion. Twenty-four hours after transplantation, the right main pulmonary artery and right main bronchus were ligated, and the rats were ventilated with 100% O2 for 5 minutes. Peak airway pressure, blood gas analysis, serum lipid peroxide level, tissue myeloperoxidase activity, and wet-dry weight ratio were measured. RESULTS The partial oxygen tension values of group 2 were higher than those of groups 1 and 4 (groups 1, 2, and 4: 104.8+/-15.8, 245.1+/-49.0, 101.4+/-4.5 mm Hg, respectively; p < 0.01). The partial carbon dioxide tension values of groups 3 and 4 were lower than those of group 1 (groups 1, 3, and 4: 74.5+/-5.7, 42.0+/-11.0, 46.0+/-8.4 mm Hg, respectively; p < 0.05). Peak airway pressures were lower in groups 2 and 3 than in groups 1 and 4 (groups 1, 2, 3, and 4: 22.5+/-0.5, 18.2+/-0.5, 19.2+/-0.8, 22.5+/-1.1 mm Hg; p < 0.01). Serum lipid peroxide levels in groups 2 and 3 were lower than those of groups 1 and 4 (groups 1, 2, 3, and 4: 0.793+/-0.037, 0.577+/-0.069, 0.560+/-0.029, and 0.785+/-0.053 nmol/mL, respectively; groups 2 and 3 vs group 1, and group 3 vs group 4: p < 0.01; group 2 vs group 4: p < 0.05). There were no differences in wet-dry weight ratio and tissue myeloperoxidase activity between the groups. CONCLUSION Recombinant Kunitz protease inhibitor ameliorates reperfusion injury caused by free radicals in an in vivo rat lung transplantation model. Administration of rKPI through the flush solution and intravenous injection after reperfusion were effective separately, but the combination of the two administrations was not effective.

Successful in vivo and ex vivo transfection of pulmonary artery segments in lung isografts

OBJECTIVE Gene transfer to lung grafts may be useful in ameliorating ischemia-reperfusion injury and rejection. Efficient gene transfection to the whole organ may prove problematic. Proximal pulmonary artery endothelial transfection might provide beneficial downstream effects on the whole graft. The aim of this study was to determine the feasibility of transfecting proximal pulmonary artery segments in lung isografts. METHODS Male Fischer rats were divided into six groups. In vivo transfection: In group I (n = 7), a proximal segment of the left pulmonary artery was isolated and injected with saline solution by means of a catheter inserted through the right ventricle. After an exposure period of 20 minutes, clamps were removed and blood flow was restored. In group II (n = 7), the isolated arterial segments were injected with adenovirus carrying the Escherichia coli LacZ gene encoding for beta-galactosidase. Ex vivo transfection: In group III (n = 5), arterial segments were injected ex vivo with saline solution and in group IV (n = 5) with the adenovirus construct. In group V (n = 6), arteries were injected with saline solution and in group VI (n = 11) with liposome chloramphenicol acetyl transferase cDNA. In groups I to IV, animals were killed on postoperative day 3 and transgene expression was assessed by Bluo-Gal staining. In groups V and VI, animals were killed on postoperative day 2 and transgene expression was assessed by chloramphenicol acetyl transferase activity assay. RESULTS Transgene expression was detected grossly and microscopically in endothelial and smooth muscle cells of pulmonary artery segments from all surviving animals of groups II and IV. In group VI, chloramphenicol acetyl transferase activity was significant in all assessed arterial segments. CONCLUSION Significant transgene expression is observed in proximal pulmonary artery segments after both in vivo and ex vivo exposure.

Isolated lung liposome-mediated gene transfer produces organ-specific transgenic expression

BACKGROUND Gene therapy is a promising strategy for the treatment of inoperable pulmonary tumors and rejection after lung transplantation. However, unlike ex vivo administration, intravenous in vivo transfection lacks organ specificity and has a limited duration of expression. The objectives of this study were to limit transfection to a single lung and to increase the duration of gene expression in vivo. METHODS Sixteen male Fisher rats were anesthetized and divided into two groups. Animals in group I (n = 7) received an intrajugular administration of 1,320 microg of chloramphenicol acetyl transferase (CAT) complementary DNA complexed with cationic liposomes. Animals in group II (n = 9) received 660 microg of CAT complementary DNA complexed with cationic liposomes into the pulmonary artery of an isolated left lung over 10 minutes. After 40 minutes of incubation, the lung was flushed with 10 mL of normal saline solution, and the perfusate was suctioned through a left pulmonary venotomy. The circulation to the left lung was then restored. After 48 hours, the animals were divided into subgroups (a and b) and CAT activity was assessed in the lungs, hearts, livers, and kidneys of groups Ia (n = 3) and IIa (n = 5). After 21 days, CAT activity was assessed in the left lungs of groups Ib (n = 4) and IIb (n = 4). RESULTS After 48 hours, animals that had received intravenous administration of CAT cDNA showed strong expression in the lungs and hearts and negligible expression in the livers and kidneys. In contrast, animals in group IIa, which had received isolated left lung perfusion of CAT cDNA showed expression only in the left lung. After 21 days, the left lungs of animals in group Ib, which had received intravenous administration of CAT complementary DNA, showed no CAT expression, but the left lungs of animals in group IIb, which had received isolated left lung perfusion of CAT complementary DNA, exhibited strong CAT expression. CONCLUSIONS Compared with intravenous administration, isolated lung liposome-mediated gene transfer provides prolonged organ-specific gene expression. This provides a useful model to study the effects of gene therapy on pulmonary tumors, which may have further application when gene therapy is used in clinical practice.