Toxic oxygen metabolites increase microvascular permeability in isolated perfused rat lungs: the effect of methylprednisolone

Toxic oxygen metabolites (TOM) have been suggested to be mediators of permeability edema associated with the adult respiratory distress syndrome (ARDS). Because corticosteroids have possible beneficial effects in ARDS, we have examined the effect of methylprednisolone (MP) on TOM-induced lung edema in isolated, plasma-perfused rat lungs. TOM were generated by adding xanthine oxidase (XO) and hypoxanthine (HX) to the perfusate. Microvascular permeability was assessed by fluid filtration rate (FFR). FFR was determined before and 30 min after administration of XO and HX by measuring the weight increase of the lungs for the last 3 min during a standard 5 min elevation of the outlet pressure. MP was administered in two different ways: 1) Added to the perfusate 5 or 60 min before XO and HX (0.1 and 1 mg ml-1), and 2) given as pretreatment to the rats 12 and 2 hr before preparation of the lungs (40 mg kg -1). XO and HX significantly increased FFR compared to lungs perfused with untreated plasma. Pretreatment with MP significantly attenuated the increase in FFR caused by XO and HX. Addition of MP to the perfusate also inhibited the effect of TOM. This latter protection occurred irrespective of when MP was added before XO and HX. However, when the highest dose of MP was added 5 min before XO and HX, there was a loss of the protective effect. In summary, this study provides evidence that MP may directly prevent microvascular injury induced by TOM in isolated perfused rat lungs. The effect was dependent on the dose of MP applied, but not on when MP was administered prior to exposure to TOM.     

beta-adrenergic stimulation restores rat lung ability to clear edema in ventilator-associated lung injury

Mechanical ventilation with high tidal volume (HVT) causes lung injury and decreases the lung's ability to clear edema in rats. beta-adrenergic agonists increase active Na(+) transport and lung edema clearance in normal rat lungs by stimulating apical Na(+) channels and basolateral Na,K-ATPase in alveolar epithelial cells. We studied whether beta-adrenergic agonists could restore lung edema clearance in rats ventilated with HVT (40 ml/kg, peak airway pressure of 35 cm H(2)O) for 40 min. The ability of rat lungs to clear edema decreased by approximately 50% after 40 min of HVT ventilation. Terbutaline (TERB) and isoproterenol (ISO) increased lung edema clearance in control nonventilated rats (from 0.50 +/- 0. 02 ml/h to 0.81 +/- 0.04 ml/h and 0.99 +/- 0.05 ml/h, respectively) and restored the lung's ability to clear edema in HVT ventilated rats (from 0.25 +/- 0.03 ml/h to 0.64 +/- 0.02 ml/h and 0.88 +/- 0. 09 ml/h, respectively). Disruption of cell microtubular transport system by colchicine inhibited the stimulatory effects of ISO in HVT ventilated rats, whereas beta-lumicolchicine did not affect beta-adrenergic stimulation. The Na,K-ATPase alpha(1)- and beta(1)-subunit mRNA steady state levels were not affected by incubation with ISO for 60 min in alveolar type II cells isolated from control and HVT ventilated rats. The data suggest that beta-adrenergic agonists increased alveolar fluid reabsorption in rats ventilated with HVT by promoting recruitment of ion-transporting proteins from intracellular pools to the plasma membrane of alveolar epithelial cells.     

Monohydroxyeicosatetraenoic acids (5-HETE and 15-HETE) induce pulmonary vasoconstriction and edema

5-, 15-, and 12-HETE (monohydroxyeicosatetraenoic acids) are products of the lipoxygenation of arachidonic acid. We investigated their role as possible mediators of pulmonary vasoactivity and pulmonary edema. Pulmonary artery pressure (Ppa), capillary pressure (Pcap), the change in lung wet weight (delta wt) from baseline, and capillary filtration coefficient (Kf) (as a measure of vascular permeability) were determined following an intravenous injection of each mono-HETE in lungs perfused at constant flow with either a phosphate-buffered Ringer's-albumin solution (PBR) or diluted blood. Injection of 2 micrograms of each compound into the pulmonary artery of lungs perfused with either PBR or diluted blood did not produce any effect. However, in PBR-perfused lungs, 4 micrograms 15-HETE induced increases in Ppa, Pcap, and lung wet weight (p less than 0.05), which were greater than the increases observed after 4 micrograms 5-HETE. Kf increased following both 5- and 15-HETE. The pulmonary vasoconstrictor and edemagenic responses were attenuated by increasing perfusate albumin concentration from 0.5 to 1.5 g%. In contrast, 12-HETE (4 micrograms) had no effect on these parameters. In blood-perfused lungs, the pulmonary vascular responses to all HETE compounds (4 micrograms) were attenuated. In both Ringer's-albumin-perfused and blood-perfused lungs, the relative magnitude of the hemodynamic and fluid filtration responses to each mono-HETE were as follows: 15-HETE greater than 5-HETE greater than 12-HETE. In conclusion, the pulmonary vasoconstrictor and edemagenic effects of 5- and 15-HETE occur independently of blood-formed elements. 15-HETE causes greater pulmonary vasoconstriction and edema than 5-HETE. Both 5- and 15-HETE induce pulmonary edema, probably as a result of increased lung vascular permeability. The results indicate that 5- and 15-HETE are potent pulmonary inflammatory mediators.     

Effect of endothelial injury on the responses of isolated guinea pig pulmonary venules to reduced oxygen tension

The influence of the endothelium on pulmonary venular responses to reduced oxygen tension has not been defined. To examine this question, endothelial injury was induced in small guinea pig pulmonary artery and venule segments (effective lumen radius, 174 +/- 5 and 122 +/- 2 microns, respectively) by perfusion with either a mixture of hypoxanthine (5 mM) and xanthine oxidase (0.05 U/ml) (HX/XO) or collagenase (2 mg/ml). HX/XO significantly (p less than 0.05) reduced the relaxation of precontracted pulmonary arteries by acetylcholine (ACH), bradykinin (BK), and A-23187, and the relaxations were restored by including superoxide dismutase (40 micrograms/ml) in the HX/XO solution. However, neither HX/XO nor collagenase affected vasodilation induced by ACH, BK, and A-23187 in precontracted pulmonary venules. In contrast, HX/XO significantly (p less than 0.05) augmented the sustained contraction of pulmonary venules to hypoxia (HX/XO, 3.2 +/- 1.0 mg/mm; control, 1.0 +/- 0.5 mg/mm) and anoxia (HX/XO, 35.1 +/- 6.6 mg/mm; control, 20.3 +/- 4.0 mg/mm). Collagenase also significantly (p less than 0.05) enhanced the anoxic contractions (collagenase, 36.0 +/- 3.7 mg/mm; control, 20.9 +/- 6.8 mg/mm). Superoxide dismutase (40 micrograms/ml) and catalase (323 micrograms/ml) abolished HX-XO-induced augmentation of the hypoxic and anoxic contractions of pulmonary venules. Collagenase removed 54 +/- 8% of the venular endothelium (control, 5 +/- 1%), whereas HX/XO-exposed endothelial cells contained numerous craters. Neither gossypol (5 microM) nor methylene blue (10 microM) affected pulmonary venular contractions to reduced PO2. Endothelial damage augments the PO2-dependent contractions of the pulmonary venule, and this augmentation does not appear to be due to decreased release of endothelium-derived relaxing factor.     

C3a57-77, a C-terminal peptide, causes thromboxane-dependent pulmonary vascular constriction in isolated perfused rat lungs

Pulmonary hypertension occurs after the intravascular activation of complement. However, it is unclear which activated complement fragments are responsible for the pulmonary vascular constriction. We investigated the 21-carboxy-terminal peptide of C3a (C3a57-77) to see if it would cause pulmonary vascular constriction when infused into isolated buffer-perfused rat lungs. Injection of C3a57-77 (225 to 450 micrograms) caused mean pulmonary arterial pressure (Ppa) to rapidly increase. However, the response was transient, with Ppa returning to baseline within 10 min of its administration. C3a57-77 also resulted in an increase in lung effluent thromboxane B2 (TXB2), concomitant with the peak increase in Ppa. C3a57-77 did not affect the amount of 6-keto-PGF1 alpha in the same effluent samples. Indomethacin inhibited the C3a57-77-induced pulmonary artery pressor response and the associated TXB2 production. Indomethacin also decreased lung effluent 6-keto-PGF1 alpha. The thromboxane synthetase inhibitors CGS 13080 and U63,357 inhibited the C3a57-77-induced pulmonary artery pressor response and TXB2 production without affecting 6-keto-PGF1 alpha. These inhibitors did not inhibit pulmonary artery pressor responses to angiotensin II. Tachyphylaxis to C3a57-77 occurred because a second dose of C3a57-77 administered to the same lung failed to cause a pulmonary artery pressor response or TXB2 production. The loss of the pressor response was not due to a C3a57-77-induced decrease in pulmonary vascular responsiveness because pressor responses elicited by angiotensin II were not altered by lung contact with C3a57-77. Thus, C3a57-77 caused thromboxane-dependent pulmonary vascular constriction in isolated buffer perfused rat lungs.     

Catecholamine clearance from alveolar spaces of rat and human lungs

BACKGROUND: Although aerosolized beta-adrenergic agonists have been used as a therapy for the resolution of pulmonary edema, the mechanisms of catecholamine clearance from the alveolar spaces of the lung are not well known. OBJECTIVE: To determine whether catecholamine clearance from the alveolar spaces is correlated with the fluid transport capacity of the lung. METHODS: Albumin solution containing epinephrine (10(-7)M) or norepinephrine (10(-7)M) was instilled into the alveolar spaces of isolated rat and human lungs. Alveolar fluid clearance rate was estimated by the progressive increase in the albumin concentration over 1 h. Catecholamine clearance rate was estimated by the changes in catecholamine concentration and alveolar fluid volume over 1 h. RESULTS: The norepinephrine clearance rate was faster than the epinephrine clearance rate in the rat and human lungs. In the rat lungs, amiloride (a sodium channel blocker) caused a greater decrease in alveolar fluid clearance and epinephrine clearance rate than propranolol (a nonselective beta-adrenergic antagonist). Although propranolol and phentolamine (an alpha-adrenergic antagonist), and 5-(N-ethyl-N-isoprophyl)amiloride (a Na+/H+ antiport blocker) changed neither the alveolar fluid clearance nor the norepinephrine clearance rate, amiloride and benzamil (a sodium channel blocker) decreased both clearance rates. As in the rat lungs, amiloride decreased alveolar fluid and norepinephrine clearance rates in the human lungs. CONCLUSION: These results indicate that the catecholamine clearance rate from the alveolar spaces is correlated with alveolar fluid clearance in rat and human lungs.     

Effect of edema on segmental vascular resistance in isolated perfused rat lungs

We have determined the effect of hydrostatic edema on total and segmental vascular resistances in the rat lung. Lungs of 12 adult rats, body weight 515 +/- 42 g, were isolated and perfused with blood. To investigate the role of vasoactivity on edema effects, we studied two groups of lungs; group I (n = 6) were untreated and group II (n = 6) were treated with papaverine hydrochloride to paralyze the vasculature. Initially blood flow was adjusted to keep pulmonary artery pressure approximately 15 cmH2O, left atrial and airway pressures being 8 and 7 cmH2O, respectively, and then kept unchanged thereafter (18 +/- 3 ml/kg/min). Hydrostatic edema was induced by raising venous pressure and pulmonary artery pressure measured continuously. In 4 lungs from each group, during baseline and after the development of severe edema, we partitioned the pulmonary circulation into arteries, microvessels, and veins by measuring pressures in 20-50 microns diameter subpleural arterioles and venules with the micropipette-Servonull method. Baseline total vascular resistance was similar in the two groups. Interstitial and early alveolar edema did not affect pulmonary vascular pressures. With severe edema (W/D ratio: 17 +/- 2), pressures in pulmonary artery and arterioles increased significantly in both groups; venular pressures did not change. Total resistance increased by 250% in group I and by 224% in group II lungs. Arterial resistance increased 3-5-fold in both groups, as did microvascular resistance. Venous resistances also increased in both groups, although to a lesser extent. The increase in total and segmental vascular resistances was not significantly different in the two groups of lungs. We conclude that in isolated rat lungs only severe edema results in an increase in total vascular resistance, mainly due to an increase in arterial and microvascular resistances, with a smaller increase in venous resistance. This appears to be a mechanical effect of edema on the vasculature and not a result of active vasomotion.     

The effects of controlled oxygen therapy on ventricular function in patients with stable and decompensated cor pulmonale

We made simultaneous measurements of pulmonary hemodynamics, cardiac output, and right ventricular ejection fraction (RVEF) to assess the right ventricular function in 14 patients with pulmonary arterial hypertension as a result of chronic obstructive pulmonary disease (COPD). From these measurements, the right ventricular end-systolic pressure/volume relationship could be calculated and used to assess right ventricular contractility. Eight of the patients were clinically stable, without edema, and 6 presented acutely with gross edema, indicating decompensated cor pulmonale. Measurements were made at rest, while breathing air and oxygen. Although mean pulmonary arterial pressure (Ppa) was similar in those with (Ppa = 33 +/- 6 mm Hg) and without edema (Ppa = 30 +/- 8 mm Hg, p greater than 0.05), RVEF was lower in edematous (RVEF = 0.23 +/- 0.11) compared with non-edematous patients (RVEF = 0.47 +/- 0.04, p less than 0.01). Cardiac output was normal in both groups. The mean right ventricular end-systolic pressure/volume ratio (P/V) was lower in those patients with edema (P/V = 0.41 +/- 0.27), as compared with those without edema (P/V = 1.69 +/- 0.35, p less than 0.05), as a result of an increase in right ventricular end-systolic volume index. Similarly, left ventricular end-systolic volumes were higher in edematous than in non-edematous patients. Breathing 1 to 3 L/min of oxygen for 30 min decreased total pulmonary vascular resistance (p less than 0.05) in those patients without edema, but not in patients with edema. Oxygen did not change RVEF, left ventricular ejection fraction (LVEF), or the ventricular end-systolic P/V relationships.(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of 5-HT2 receptor inhibition in pulmonary embolization

We examined the role of serotonin at the 5-HT2 receptor site after pulmonary embolization for changes in hemodynamics, gas exchange, and lung water. Pulmonary embolization was induced using 0.75 gm/kg autologous clot in anesthetized artificially ventilated dogs. Pulmonary vascular resistance rose by 5 min from 3.4 +/- 1.5 to 14.2 +/- 2.1 mm Hg/liter/min (p less than 0.001), arterial oxygenation decreased from 91 +/- 5 to 68 +/- 5 mm Hg (p less than 0.01), platelet count decreased from 201 +/- 64 to 141 +/- 32 ml X 10(3), and the wet to dry weight lung ratio increased from 2.59 +/- 0.34 to 4.21 +/- 0.21 (p less than 0.001). Inhibition by ketanserin, a selective serotonergic inhibitor at the 5-HT2 receptor site substantially attenuated the increase in pulmonary vascular resistance from 3.6 +/- 1.4 to 8.0 +/- 2.5 mm Hg/liter/min, ablated the hypoxemia and platelet reduction and inhibited the formation of pulmonary edema. Infusion of serotonin simulated only some of the above changes as the pulmonary vascular resistance increased from 3.16 +/- 1.6 to 13.5 +/- 4.1 mm Hg/liter/min (P less than 0.01) and the oxygenation decreased from 96 +/- 5 to 57 +/- 4 mm Hg (P less than 0.01). Serotonin infusion, however, did not cause pulmonary edema. The administration of ketanserin ablated the increase in pulmonary vascular resistance and the hypoxemia following serotonin infusion. We conclude that following pulmonary embolization, serotonin at the 5-HT2 receptor is responsible for the fall in PaO2 and partially responsible for the increased pulmonary vascular resistance. Although ketanserin inhibits the formation of pulmonary edema following pulmonary embolization, serotonin does not seem to be directly responsible.     

β肾上腺素能受体激动剂对离体大鼠肺泡液体清除率的作用

目的探讨β1肾上腺素能受体激动剂地诺帕明、β2肾上腺素能受体激动剂特布他林、β3肾上腺素能受体激动剂BRL37344对离体大鼠肺泡液体清除率(AFC)的作用及机制。方法5%白蛋白等渗生理盐水溶液和不同药物混合后灌注到离体大鼠的肺泡腔内,根据灌注前及其孵育1h后白蛋白浓度的变化来计算大鼠AFC。结果基础AFC为6.9%±2.2%,地诺帕明、特布他林、BRL37344可显著提高AFC(分别为17.1%±2.4%、19.5%±1.2%、19.9%±2.5%)。β1肾上腺素能受体阻滞剂Atenolol可完全抑制地诺帕明提高AFC(6.1%±0.9%)的作用,但不能阻滞特布他林和BRL37344的作用。β2肾上腺素能受体阻滞剂ICI118551完全抑制了特布他林和BRL37344提高AFC(分别为5.7%±0.6%和7.8%±2.6%)的作用,部分抑制了地诺帕明的作用(AFC为12.7%±1.8%)。β3肾上腺素能受体阻滞剂SR59230A部分抑制了BRL37344和特布他林的作用(AFC分别为13.8%±3.1%和14.5%±3.4%),但不能阻滞地诺帕明的作用。结论地诺帕明、特布他林、BRL37344可以显著提高大鼠的AFC。但地诺帕明和特布他林是分别通过β1、β2肾上腺素能受体起作用;而BRL37344可能是通过β2肾上腺素能受体调节的。ICI118551和SR59230A可能分别具有抑制β1或β2肾上腺素能受体的作用。     

Serotonin receptors in rat lung

Mammalian lungs have been shown to store and to inactivate serotonin by an active process involving uptake and metabolism. Serotonin has direct action on lung including constrictor effects of pulmonary vascular and tracheobronchial smooth muscle suggesting the presence of serotonin receptors in lung. We have identified several serotonin binding receptors in rat lung. Two separate binding sites are present in a purified mitochondrial fraction. Saturation analysis of (3H)-serotonin binding to outer mitochondrial membranes exhibits temperature-dependent association kinetics and demonstrates a single, high affinity, high capacity binding (dissociation constant = 8.3 +/- 1.2 nM, maximum binding capacity = 0.819 +/- 0.046 pmol/mg protein). The dissociation constant of inner mitochondrial membrane demonstrates a low affinity, low capacity site (dissociation constant = 25.2 +/- 2.2 nM, maximum binding capacity = 0.453 +/- 0.037 pmol/mg protein). The purified microsomal fraction of lung exhibits a moderate affinity, high capacity binding site for (3H)-serotonin (dissociation constant = 14.8 +/- 1.6 nM, maximum binding capacity = 0.760 +/- 0.03 pmol/mg protein). In addition to the lung being the major site for its inactivation, the presence of several specific serotonin receptors may be related to some of the known serotonin actions in lung and may suggest other unknown actions of this amine.     

Denopamine stimulates alveolar fluid clearance via cystic fibrosis transmembrane conductance regulator in rat lungs

OBJECTIVE: The objective of this study was to test the hypothesis that cystic fibrosis transmembrane conductance regulator (CFTR) plays a role in beta(1)-adrenergic agonist-stimulated alveolar fluid clearance. METHODS: Isotonic 5% albumin solutions containing different pharmacological agents were instilled into the alveolar spaces of the isolated rat lungs. The lungs were inflated with 100% oxygen at an airway pressure of 7 cm H(2)O and placed in a humidified incubator at 37 degrees C. Alveolar fluid clearance was estimated by the progressive increase in the albumin concentration over 1 h. To test the hypothesis, we determined whether CFTR Cl(-) channel inhibitors (glibenclamide and CFTR(inh)-172) inhibited the effect of denopamine, a beta(1)-adrenergic agonist, on stimulation of alveolar fluid clearance in the isolated rat lungs. RESULTS: Denopamine increased alveolar fluid clearance in a dose-dependent manner. Atenolol, a beta(1)-adrenergic antagonist, abolished the effects of denopamine on stimulation of alveolar fluid clearance. Although glibenclamide alone or CFTR(inh)-172 alone did not change basal alveolar fluid clearance, these CFTR inhibitors inhibited the effect of denopamine on alveolar fluid clearance. CONCLUSION: CFTR plays a role in beta(1)-adrenergic agonist-stimulated alveolar fluid clearance in rat lungs.     

Activation of EGF receptors mediates pulmonary vasoconstriction induced by residual oil fly ash.

Residual oil fly ash (ROFA) is a constituent of pollutant particles that can produce lung injury and activate protein tyrosine phosphorylation cascade. In this study, we determined whether or not protein tyrosine phosphorylation caused lung injury, and if so, identified critical tyrosinephosphorylated proteins that mediated the injury. ROFA was instilled intratracheally into perfused rabbit lungs and injury responses, including increase in pulmonary artery pressure (Ppa), lung weight gain, as well as release of interleukin (IL)-1beta, IL-6, IL-8, and nitrite/nitrate were measured. ROFA increased Ppa and IL-1beta, but inhibited nitrite/nitrate accumulation. Vanadyl sulfate at concentration equivalent to the amount of vanadium detected in the perfusate of ROFA-treated lungs induced similar changes. ROFA enhanced tyrosine phosphorylation of lung proteins, including a 170-kDa protein, likely the epidermal growth factor (EGF) receptor as shown by immunoprecipitation. Pretreatment with genistein, a tyrosine kinase inhibitor, blocked the increase in Ppa and tyrosine phosphorylation of the 170-kDa protein. Intravascular administration of human EGF increased Ppa, and pretreatment with PD153035, an EGF receptor-specific tyrosine kinase inhibitor, attenuated ROFA-induced pulmonary vasoconstriction. These results indicate that tyrosine phosphorylation of EGF receptors in the lung, possibly as a result of inhibition of protein tyrosine phosphatases, mediates constriction of pulmonary vessels induced by ROFA.     

Influence of melatonin on free radical-induced changes in rat pancreatic beta-cells in vitro

Free radicals may produce cytotoxicity to pancreatic islets under pathophysiological conditions. The aim of our in vitro investigations was to compare functional and morphological changes in pancreatic beta-cells induced by reactive oxygen species (ROS) generated by alloxan or xanthine oxidase/hypoxanthine (XO/HX), respectively. We demonstrate that short-term exposure to alloxan or to XO/HX leads to a temporarily elevated insulin release from isolated pancreatic islets. On application of alloxan, this effect is caused by beta-cell necrosis and can be prevented by administration of melatonin, while in contrast, XO/HX did not lead to long-term morphological changes in the majority of the cells. Among the cells destroyed by alloxan, only necrosis could be detected, while in contrast, some apoptotic cells were identified by the terminal deoxynucleotidyl transferase-mediated dUTP-biotin nick end labeling (TUNEL) reaction and electron microscopic examinations of cells treated with XO/HX. Melatonin was able to prevent the changes caused by alloxan, but failed to influence the alterations caused by XO/HX. Using electron spin resonance and lipid peroxidation assay, respectively, it was confirmed that melatonin effectively detoxifies hydroxyl radicals. Therefore, we believe that hydroxyl radicals are the toxic principle of alloxan, but not of XO/HX toxicity.     

Ultrastructural alterations in intraalveolar surfactant subtypes after experimental ischemia and reperfusion.

Ischemia and reperfusion (I/R) result in surfactant dysfunction. Whether the impairment of surfactant is a consequence or a cause of intraalveolar edema formation is still unknown. The cumulative effects of lung perfusion, ischemic storage, and subsequent reperfusion on surfactant ultrastructure and pulmonary function were studied in a rat isolated perfused lung model. The left lungs were fixed for electron microscopy by vascular perfusion either immediately after excision (control; n = 5) or after perfusion with modified Euro-Collins solution (EC), storage for 2 h at 4 degrees C in EC, and reperfusion for 40 min (n = 5). A stereological approach was chosen to discriminate between intraalveolar surfactant subtypes of edematous regions and regions free of edema. Intraalveolar edema seen after I/R in the EC group occupied 36 +/- 6% (mean +/- SEM) of the gas exchange region as compared with control lungs (1 +/- 1%; p = 0.008). Relative intraalveolar surfactant composition showed a decrease in surface active tubular myelin (3 +/- 1 versus 12 +/- 0%; p = 0.008) and an increase in inactive unilamellar forms (83 +/- 2 versus 64 +/- 5%; p = 0.008) in the EC group. These changes occurred both in edematous (tubular myelin, 3 +/- 1%; unilamellar forms, 88 +/- 6%) and in nonedematous regions (tubular myelin, 4 +/- 3%; unilamellar forms, 77 +/- 5%). The ultrastructural changes in surfactant were associated with an increase in peak inspiratory pressure during reperfusion. In conclusion, surfactant alterations seen after I/R are not directly related to the presence of edema fluid in the alveoli. Disturbances in intraalveolar surfactant after I/R are not merely the result of inactivation due to plasma protein leakage but may instead be responsible for an increased permeability of the blood-air barrier, resulting in a vicious cycle of intraalveolar edema formation and progressing surfactant impairment.     

Alveolar liquid clearance and sodium channel expression are decreased in transplanted canine lungs

To determine the impact of transplantation-associated injury on the clearance mechanisms of pulmonary edema, we created a canine single lung transplant model. After 3 hours of preservation and 4 hours of reperfusion, right native lungs and left transplanted lungs were used to measure alveolar liquid clearance (ALC) in ex vivo liquid-filled lung preparations. We also examined the role of the pulmonary circulation in edema clearance in in vivo liquid-filled lungs between 4 and 8 hours of reperfusion. To study molecular modifications in ALC, we also measured expression levels of the epithelial sodium channel (ENaC) and sodium-potassium-adenosine triphosphatase (ATPase). We found that ALC was significantly lower in transplanted than in right native lungs ex vivo (p < 0.05) and that transplanted lungs did not respond to the beta-adrenergic agonist terbutaline. Our in vivo study confirmed the ex vivo results. Molecular analyses revealed that ENaC messenger RNA but not sodium-potassium-ATPase was significantly decreased in transplanted lungs (p < 0.01). Furthermore, there was a significant decrease in ENaC protein expression. Therefore, we conclude that the current investigation indicates that the lung injury caused by lung preservation and transplantation significantly reduces the edema clearance ability of transplanted lungs.     

Glutathione decreases the pulmonary reimplantation response in canine lung autotransplants

The pulmonary reimplantation response (PRR) is a form of membrane permeability pulmonary edema occurring in lung transplants. The severity of the PRR reflects the quality and duration of lung graft preservation. Free radicals formed during ischemia with reperfusion in the autotransplanted dog lung may play a role in producing PRR. We hypothesized that the addition of reduced glutathione (GSH) to the preservative solution could decrease PRR if hydroperoxides are being formed. Six dogs underwent left lung autotransplantation after the lung was flushed with Euro-Collins solution (EC). These dogs demonstrated radiographic and histopathologic evidence of bilateral pulmonary edema, greatest in the transplanted left lung. They also had increases in lung wet to dry weight (W/D) ratios in both lungs (left, 12.0 +/- 0.9; right, 10.1 +/- 0.8) as compared with a group of five unmanipulated control animals (left, 6.0 +/- 0.5; right, 7.0 +/- 0.4). Malondialdehyde (MDA) concentrations were significantly increased in the transplanted left lungs (14 +/- 4) from this group as compared with the controls (5 +/- 7). Five additional dogs underwent left lung autotransplantation with GSH added to the EC cryopreservation fluid. These animals did not develop histologic or radiographic evidence of pulmonary edema, and W/D ratios as well as MDA concentrations were not different from those in controls. To evaluate the effect of ischemia alone on changes in lung GSH concentrations, ten additional dogs underwent left pneumonectomy. Left lungs were cryopreserved in EC + GSH. In five of the animals, the right lung was removed and preserved in EC alone. In the other five animals, the right lung remained in vivo for 3 h and was then removed. Lung GSH concentrations were doubled after 3 h of ischemia when incubated in EC + GSH compared to in vivo controls and to EC-treated lungs. These data suggest that GSH added to the preservation fluid prevents PRR following transplantation and that lung GSH concentrations actually increase during preservation prior to reimplantation and reperfusion if the lung graft is exposed to GSH in the preservation fluid.     

Effects of intraalveolar oxygen concentration on alveolar fluid absorption and metabolism in isolated rat lungs.

We evaluated the effects of intraalveolar oxygen concentration on alveolar fluid absorption and metabolism in isolated rat lungs. Alveolar fluid absorption was determined by measuring increase in albumin concentration in the instillate solution during 2 h of incubation. Oxidative phosphorylation was assessed by gas analysis of the solution. Glycolysis was assessed by determining glucose escape and lactate release in the solution. We found that alveolar fluid absorption did not change under hyperoxic and hypoxic experimental environments (range 100-10% oxygen). Glycolysis was reduced under hyperoxia and stimulated under hypoxia, however, lung ATP content did not change. When oxidative phosphorylation was inhibited by NaCN, both alveolar fluid absorption and lung ATP content were reduced. Our data indicate that isolated rat lungs maintain optimal energy production for alveolar fluid absorption by stimulating glycolysis, even though glycolysis alone is not enough. We conclude that alveolar fluid absorption determined in isolated rat lungs is not influenced by intraalveolar oxygen concentration in the range above 10% oxygen.     

Exhaled nitric oxide in high-altitude pulmonary edema: role in the regulation of pulmonary vascular tone and evidence for a role against inflammation

High-altitude pulmonary edema (HAPE) is a life-threatening condition occurring in predisposed subjects at altitudes above 2,500 m. It is not clear whether, in addition to hemodynamic factors and defective alveolar fluid clearance, inflammation plays a pathogenic role in HAPE. We therefore made serial measurements of exhaled pulmonary nitric oxide (NO), a marker of airway inflammation, in 28 HAPE-prone and 24 control subjects during high-altitude exposure (4,559 m). To examine the relationship between pulmonary NO synthesis and pulmonary vascular tone, we also measured systolic pulmonary artery pressure (Ppa). In the 13 subjects who developed HAPE, exhaled NO did not show any tendency to increase during the development of lung edema. Throughout the entire sojourn at high altitude, pulmonary exhaled NO was roughly 30% lower in HAPE-prone than in control subjects, and there existed an inverse relationship between Ppa and exhaled NO (r = -0.51, p < 0.001). These findings suggest that HAPE is not preceded by airway inflammation. Reduced exhaled NO may be related to altered pulmonary NO synthesis and/or transport and clearance, and the data in our study could be consistent with the novel concept that in HAPE-prone subjects, a defect in pulmonary epithelial NO synthesis may contribute to exaggerated hypoxic pulmonary vasoconstriction and in turn to pulmonary edema.