Separate effects of ischemia and reperfusion on vascular permeability in ventilated ferret lungs.

In systemic organs, ischemia-reperfusion injury is thought to occur during reperfusion, when oxygen is reintroduced to hypoxic ischemic tissue. In contrast, the ventilated lung may be more susceptible to injury during ischemia, before reperfusion, because oxygen tension will be high during ischemia and decrease with reperfusion. To evaluate this possibility, we compared the effects of hyperoxic ischemia alone and hyperoxic ischemia with normoxic reperfusion on vascular permeability in isolated ferret lungs. Permeability was estimated by measurement of filtration coefficient (Kf) and osmotic reflection coefficient for albumin (sigma alb), using methods that did not require reperfusion to make these measurements. Kf and sigma alb in control lungs (n = 5), which were ventilated with 14% O2-5% CO2 after minimal (15 +/- 1 min) ischemia, averaged 0.033 +/- 0.004 g.min-1.mmHg-1.100 g-1 and 0.69 +/- 0.07, respectively. These values did not differ from those reported in normal in vivo lungs of other species. The effects of short (54 +/- 9 min, n = 10) and long (180 min, n = 7) ischemia were evaluated in lungs ventilated with 95% O2-5% CO2. Kf and sigma alb did not change after short ischemia (Kf = 0.051 +/- 0.006 g.min-1.mmHg-1.100 g-1, sigma alb = 0.69 +/- 0.07) but increased significantly after long ischemia (Kf = 0.233 +/- 0.049 g.min-1 x mmHg-1 x 100 g-1, sigma alb = 0.36 +/- 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)     

Protective effect of lung inflation in reperfusion-induced lung microvascular injury

We used the isolated-perfused rat lung model to study the influence of pulmonary ventilation and surfactant instillation on the development of postreperfusion lung microvascular injury. We hypothesized that the state of lung inflation during ischemia contributes to the development of the injury during reperfusion. Pulmonary microvascular injury was assessed by continuously monitoring the wet lung weight and measuring the vessel wall (125)I-labeled albumin ((125)I-albumin) permeability-surface area product (PS). Sprague-Dawley rats (n = 24) were divided into one control group and five experimental groups (n = 4 rats per group). Control lungs were continuously ventilated with 20% O(2) and perfused for 120 min. All lung preparations were ventilated with 20% O(2) before the ischemia period and during the reperfusion period. The various groups differed only in the ventilatory gas mixtures used during the flow cessation: group I, ventilated with 20% O(2); group II, ventilated with 100% N(2); group III, lungs remained collapsed and unventilated; group IV, same as group III but pretreated with surfactant (4 ml/kg) instilled into the airway; and group V, same as group III but saline (4 ml/kg) was instilled into the airway. Control lungs remained isogravimetric with baseline (125)I-albumin PS value of 4.9 +/- 0.3 x 10(-3) ml x min(-1) x g wet lung wt(-1). Lung wet weight in group III increased by 1.45 +/- 0.35 g and albumin PS increased to 17.7 +/- 2.3 x 10(-3), indicating development of vascular injury during the reperfusion period. Lung wet weight and albumin PS did not increase in groups I and II, indicating that ventilation by either 20% O(2) or 100% N(2) prevented vascular injury. Pretreatment of collapsed lungs with surfactant before cessation of flow also prevented the vascular injury, whereas pretreatment with saline vehicle had no effect. These results indicate that the state of lung inflation during ischemia (irrespective of gas mixture used) and supplementation of surfactant prevent reperfusion-induced lung microvascular injury.     

O2 radicals mediate reperfusion lung injury in ischemic O2-ventilated canine pulmonary lobe

This study was undertaken to determine whether lung injury after a period of ischemia reperfusion is caused by O2 ventilation during ischemia and whether this injury is mediated by reactive O2 metabolites. Isolated canine left lower pulmonary lobes were subjected to room temperature ischemia for 6 h while being ventilated with either 100% O2, room air, or 100% N2. After the ischemic period, all lobes were perfused with autologous blood and ventilated with 100% O2 for an additional 4 h. In lobes ventilated with 100% O2 during the ischemic period, massive weight gain (228%) occurred 4 h after reperfusion. A marked increase in pulmonary shunt was noted. Lobes ventilated with room air behaved similarly. In contrast, lobes ventilated with 100% N2 gained significantly less weight (54%) and did not manifest any increase in pulmonary shunt. When lobes ventilated with 100% O2 or room air were pretreated with superoxide dismutase (SOD), the injury was significantly reduced. Pressure-volume deflation study of lobes, after ischemia only, demonstrated that ventilation with 100% O2 and with 100% N2 both equally decreased pulmonary compliance. We conclude that lung ischemia-reperfusion injury is related to O2 ventilation during ischemia and that injury can be prevented by administration of SOD or ventilation with 100% N2. This suggests that the injury is related to O2 metabolites produced during O2 ventilation in the absence of the circulation.     

Hypoxic pulmonary vasoconstriction does not affect hydrostatic pulmonary edema formation

We studied the effects of regional hypoxic pulmonary vasoconstriction (HPV) on lobar flow diversion in the presence of hydrostatic pulmonary edema. Ten anesthetized dogs with the left lower lobe (LLL) suspended in a net for continuous weighing were ventilated with a bronchial divider so the LLL could be ventilated with either 100% O2 or a hypoxic gas mixture (90% N2-5% CO2-5% O2). A balloon was inflated in the left atrium until hydrostatic pulmonary edema occurred, as evidenced by a continuous increase in LLL weight. Left lower lobe flow (QLLL) was measured by electromagnetic flow meter and cardiac output (QT) by thermal dilution. At a left atrial pressure of 30 +/- 5 mmHg, ventilation of the LLL with the hypoxic gas mixture caused QLLL/QT to decrease from 17 +/- 4 to 11 +/- 3% (P less than 0.05), pulmonary arterial pressure to increase from 35 +/- 5 to 37 +/- 6 mmHg (P less than 0.05), and no significant change in rate of LLL weight gain. Gravimetric confirmation of our results was provided by experiments in four animals where the LLL was ventilated with an hypoxic gas mixture for 2 h while the right lung was ventilated with 100% O2. In these animals there was no difference in bloodless lung water between the LLL and right lower lobe. We conclude that in the presence of left atrial pressures high enough to cause hydrostatic pulmonary edema, HPV causes significant flow diversion from an hypoxic lobe but the decrease in flow does not affect edema formation.     

Generation of 5-lipoxygenase metabolites following pulmonary reperfusion in isolated rabbit lungs.

We characterized the release of arachidonic acid (AA) metabolites in lung effluent following lung ischemia-reperfusion since they may contribute to the pathophysiology of reperfusion lung injury. The left pulmonary artery of rabbits (N = 5) was occluded for 24 hrs with a surgically implanted vascular clip. At 24 hrs, the heart and lungs were removed en bloc and perfused with Ringers-albumin (0.5 gm%) at 60 ml/min while statically inflated with 95% O2-5% CO2. The lipid fraction of the lung effluent was concentrated using the Bligh-Dyer extraction and analyzed by gradient RP-HPLC. Samples obtained in the first minute of reperfusion showed significant increases in LTB4 (+180%), LTC4 (+3600%), 15-HETE (+370%), 5-HPETE (+270%), PGE2 (+140%), 6-keto-PGF1 alpha (+110%) and 12-HHT (+160%) compared to the effluent from the right control lung. The reperfusion-induced increases in LTB4, LTC4, LTD4 and 15-HETE were inhibited greater than or equal to 70% by pretreatment with the 5-LO inhibitors L663,536 or L651,392. The increases in lipid concentrations corresponded to significantly increased pulmonary arterial pressure from a baseline value of 9.5 +/- 0.3 to 29.3 +/- 2.9 (cmH2O) during the first min of reperfusion. The pulmonary arterial pressure remained elevated for at least 20 min of reperfusion. Reperfusion also resulted in PMN uptake (assessed by lung tissue myeloperoxidase content) in the reperfused lung versus control lung (25.0 +/- 2.4 vs. 10.5 +/- 2.5 units). The generation of lipoxygenase metabolites during the initial phase of reperfusion may contribute to post-reperfusion PMN uptake and pulmonary vasoconstriction.     

Increased lung expansion alters lung growth but not alveolar epithelial cell differentiation in newborn lambs

Although increased lung expansion markedly alters lung growth and epithelial cell differentiation during fetal life, the effect of increasing lung expansion after birth is unknown. We hypothesized that increased basal lung expansion, caused by ventilating newborn lambs with a positive end-expiratory pressure (PEEP), would stimulate lung growth and alter alveolar epithelial cell (AEC) proportions and decrease surfactant protein mRNA levels. Two groups of lambs were sedated and ventilated with either 0 cmH(2)O PEEP (controls, n = 5) or 10 cmH(2)O PEEP (n = 5) for 48 h beginning at 15 +/- 1 days after normal term birth. A further group of nonventilated 2-wk-old lambs was used for comparison. We determined wet and dry lung weights, DNA and protein content, a labeling index for proliferating cells, surfactant protein mRNA expression, and proportions of AECs using electron microscopy. Although ventilating lambs for 48 h with 10 cmH(2)O PEEP did not affect total lung DNA or protein, it significantly increased the proportion of proliferating cells in the lung when compared with nonventilated 2-wk-old controls and lambs ventilated with 0 cmH(2)O PEEP (control: 2.6 +/- 0.5%; 0 PEEP: 1.9 +/- 0.3%; 10 PEEP: 3.5 +/- 0.3%). In contrast, no differences were observed in AEC proportions or surfactant protein mRNA levels between either of the ventilated groups. This study demonstrates that increases in end-expiratory lung volumes, induced by the application of PEEP, lead to increased lung growth in mechanically ventilated 2-wk-old lambs but do not alter the proportions of AECs.     

Increase in alveolar antioxidant levels in hyperoxic and anoxic ventilated rabbit lungs during ischemia

Increases in free radicals are believed to play a central role in the development of pulmonary ischemia/reperfusion (I-R) injury, leading to microvascular leakage and deterioration of pulmonary surfactant. Continued ventilation during ischemia offers significant protection against I-R injury, but the impact of alveolar oxygen supply both on lung injury and on radical generation is still unclear. We investigated the influence of hyperoxic (95% O2) and anoxic (0% O2) ventilation during ischemia on alveolar antioxidant status and surfactant properties in isolated rabbit lungs. Normoxic and hyperoxic ventilated, buffer-perfused lungs (n = 5 or 6) and native lungs (n = 6) served as controls. As compared with controls, biophysical and biochemical surfactant properties were not altered in anoxic as well as hyperoxic ventilated ischemic (2, 3, and 4 h) lungs. Assessment of several antioxidants (reduced glutathione (GSH), alpha-tocopherol (vitamin E), retinol (vitamin A), ascorbic acid (vitamin C), uric acid, and plasmalogens (1-O-alkenyl-2-acyl-phospholipids)) in bronchoalveolar lavage fluid (BALF) revealed a significant increase in antioxidant compounds under anoxic and hyperoxic ventilation, with maximum levels occuring after 3 h of ischemia. For example, GSH increased to 5.1 +/- 0.8 microM (mean +/- SE, p <.001) after 3 h of anoxic ventilated ischemia and to 2.7 +/- 0.2 microM (p <.01) after hyperoxic ventilated ischemia compared with native controls (1.3 +/- 0.2 microM), but did not significantly change under anoxic and hyperoxic ventilation alone. In parallel, under ischemic conditions, oxidized glutathione (GSSG) increased during hyperoxic (3 h: 0.81 +/- 0.04 microM, p <.001), but remained unchanged during anoxic (3 h: 0.31 +/- 0.04 microM) ventilation compared with native controls (0.22 +/- 0.02 microM), whereas F2-isoprostanes were elevated under both hyperoxic (3 h: 63 +/- 15 pM, p <.01) and anoxic (3 h: 50 +/- 9 pM, p <.01) ventilation compared with native controls (16 +/- 4 pM). We conclude that oxidative stress is increased in the lung alveolar lining layer during ischemia, during both anoxic and hyperoxic ventilation. This is paralleled by an increase rather than a decrease in alveolar antioxidant levels, suggested to reflect an adaptive response to oxidative stress during ischemia.     

Pulmonary venous pressure increases during alveolar hypoxia in isolated lungs of newborn pigs.

The purpose of this study was to determine whether pulmonary venous pressure increases during alveolar hypoxia in lungs of newborn pigs. We isolated and perfused with blood the lungs from seven newborn pigs, 6-7 days old. We maintained blood flow constant at 50 ml.min-1.kg-1 and continuously monitored pulmonary arterial and left atrial pressures. Using the micropuncture technique, we measured pressures in 10 to 60-microns-diam venules during inflation with normoxic (21% O2-69-74% N2-5-10% CO2) and hypoxic (90-95% N2-5-10% CO2) gas mixtures. PO2 was 142 +/- 21 Torr during normoxia and 20 +/- 4 Torr during hypoxia. During micropuncture we inflated the lungs to a constant airway pressure of 5 cmH2O and kept left atrial pressure greater than airway pressure (zone 3). During hypoxia, pulmonary arterial pressure increased by 69 +/- 24% and pressure in small venules increased by 40 +/- 23%. These results are similar to those obtained with newborn lambs and ferrets but differ from results with newborn rabbits. The site of hypoxic vasoconstriction in newborn lungs is species dependent.     

Role of anti-L-selectin antibody in burn and smoke inhalation injury in sheep

We hypothesized that the antibody neutralization of L-selectin would decrease the pulmonary abnormalities characteristic of burn and smoke inhalation injury. Three groups of sheep (n = 18) were prepared and randomized: the LAM-(1-3) group (n = 6) was injected intravenously with 1 mg/kg of leukocyte adhesion molecule (LAM)-(1-3) (mouse monoclonal antibody against L-selectin) 1 h after the injury, the control group (n = 6) was not injured or treated, and the nontreatment group (n = 6) was injured but not treated. All animals were mechanically ventilated during the 48-h experimental period. The ratio of arterial PO2 to inspired O2 fraction decreased in the LAM-(1-3) and nontreatment groups. Lung lymph flow and pulmonary microvascular permeability were elevated after injury. This elevation was significantly reduced when LAM-(1-3) was administered 1 h after injury. Nitrate/nitrite (NO(x)) amounts in plasma and lung lymph increased significantly after the combined injury. These changes were attenuated by posttreatment with LAM-(1-3). These results suggest that the changes in pulmonary transvascular fluid flux result from injury of lung endothelium by polymorphonuclear leukocytes. In conclusion, posttreatment with the antibody for L-selectin improved lung lymph flow and permeability index. L-selectin appears to be principally involved in the increased pulmonary transvascular fluid flux observed with burn/smoke insult. L-selectin may be a useful target in the treatment of acute lung injury after burn and smoke inhalation.     

Response of the bronchial circulation to acute hypoxemia and hypercarbia in the dog

We have examined the effect of acute hypoxemia and hypercarbia on bronchial blood flow (Qbr) in 10 anesthetized, ventilated, open-chest dogs using a modification of the radioactive microsphere technique. After surgery, dogs were divided into two groups of five. Group 1 was ventilated for 30 min with each of the following gas mixtures: 1) room air; 2) 15% O2-85% N2; 3) 10% O2-90% N2, and group 2 with 1) room air; 2) 5% CO2-30% O2-65% N2; 3) 10% CO2-30% O2-60% N2. Measurements of pulmonary arterial, left atrial and aortic pressures, cardiac output, and blood gases were made before injection of 46Sc-, 153Gd-, and 103Ru-labeled microspheres into the left atrium as a marker of Qbr. After the final measurements, dogs were killed and the lungs removed and the parenchyma stripped off the large and small airways of the left lung. Knowing the radioactivity in the trachea, bronchi, parenchyma, and in the blood from the reference-flow sample and also the aortic and left atrial pressures, total and regional Qbr, and bronchovascular resistance (BVR) were calculated. Results showed that acute hypoxemia (10% O2) caused a significant (P less than 0.05) decrease in Qbr and increase in BVR and acute hypercarbia (10% CO2) caused a significant (P less than 0.05) increase in Qbr and decrease in BVR.     

Linear relationship between VO2max and VO2max decrement during exposure to acute hypoxia

The purpose of these experiments is to test the hypothesis that exercise-induced hypoxemia at sea level in highly trained athletes might be exacerbated during acute hypoxia and therefore result in correspondingly larger decrements in maximal O2 uptake (VO2max) compared with less trained individuals. Thirteen healthy male volunteers were divided into two groups according to their level of fitness: 1) trained endurance athletes (T) (n = 7), with a VO2max range of 56-75 ml.kg-1.min-1 and 2) untrained individuals (UT) (n = 6), with a VO2max range of 33-49 ml.kg-1.min-1. Subjects performed two incremental cycle ergometry tests to determine VO2max under hypoxic conditions [14% O2-86% N2, barometric pressure (PB) = 760 Torr] and normoxic conditions (21% O2-79% N2, PB = 760 Torr). Tests were single blind, randomly administered, and separated by at least 72 h. Mean percent oxyhemoglobin saturation (%SaO2) during maximal exercise under hypoxic conditions was significantly (P less than 0.05) lower in the T group (77%) compared with the UT group (86%). Furthermore, the T group exhibited larger decrements (P less than 0.05) in VO2max (normoxic-hypoxic) compared with the UT group. Finally, a significant linear correlation (r = 0.94) existed between normoxic VO2max (ml.kg-1.min-1) and delta VO2max (normoxic-hypoxic). These data suggest that highly T endurance athletes suffer more severe gas exchange impairments during acute exposure to hypoxia than UT individuals, and this may explain a portion of the observed variance in delta VO2max among individuals during acute altitude or hypoxia exposure.     

Low-dose dopamine hastens onset of gut ischemia in a porcine model of hemorrhagic shock.

Gut metabolism may become anaerobic before the whole body during progressive phlebotomy in dogs. Because dopamine has selective mesenteric vasodilator effects, we asked whether dopamine could delay onset of bowel ischemia during hemorrhagic shock. We studied whole body and gut O2 consumption (VO2) and O2 delivery (QO2) using progressive phlebotomy in anesthetized pigs. Nine pigs received a dopamine infusion of 2 micrograms.kg-1.min-1, whereas a control group of seven pigs received equivalent saline infusion. Onset of ischemia in whole body and gut was determined as critical O2 delivery (QO2c), the intersection point of biphasic regression on plots of VO2-QO2 relationships. Blood flow and O2 extraction were measured as mechanisms of gut ischemia for entire in situ small and large gut using a superior mesenteric venous fistula. Dopamine hastened onset of gut ischemia relative to onset of whole body ischemia (gut critical point in terms of whole body QO2 9.9 +/- 2.1 ml O2.kg-1.min-1, whole body QO2c 7.8 +/- 0.7 ml O2.kg-1.min-1, P less than 0.01). In contrast, onset of gut ischemia in control animals occurred at same time as onset of whole body ischemia (gut critical point in terms of whole body QO2 7.4 +/- 2.3 ml O2.kg-1.min-1, whole body QO2c 7.1 +/- 2.7 ml O2.kg-1.min-1, P = not significant). Hastening of onset of gut ischemia in dopamine-treated animals was associated with decreased ability of gut to extract O2. Low-dose dopamine was not protective against gut ischemia during shock but rather caused earlier onset of gut ischemia during hemorrhagic shock.     

Oxygen delivery and utilization in hypothermic dogs

Hypothermia produces a decrease in metabolic rate that may be beneficial under conditions of reduced O2 delivery (Do2). Another effect of hypothermia is to increase the affinity of hemoglobin for O2, which can adversely affect the release of O2 to the tissues. To determine the overall effect of hypothermia on the ability of the peripheral tissues to extract O2 from blood, we compared the response to hypoxemia of hypothermic dogs (n = 8) and of normothermic controls (n = 8). The animals were anesthetized, mechanically ventilated, and paralyzed to prevent shivering. The inspired concentration of O2 was progressively reduced until the dogs died. The core temperatures of the control and hypothermic dogs were 37.7 +/- 0.3 and 30.5 +/- 0.1 degree C, respectively (P less than 0.01). The O2 consumption (VO2) of the control dogs was significantly greater than that of the hypothermic dogs (P less than 0.05), being 4.7 +/- 0.4 and 3.2 +/- 0.3 ml X min-1 X kg-1, respectively. Hypothermia produced a left shift of the oxyhemoglobin dissociation curve (ODC) to a PO2 at which hemoglobin is half-saturated with O2 of 19.8 +/- 0.7 Torr (control = 32.4 +/- 0.7 Torr, P less than 0.01). The O2 delivery at which the VO2 becomes supply dependent (DO2crit) was 8.5 ml X min-1 X kg-1 for control and 6.2 ml X min-1 X kg-1 for hypothermia. The hypothermic dogs maintained their base-line VO2's at lower arterial PO2's than control.(ABSTRACT TRUNCATED AT 250 WORDS)     

Venous air embolism in swine: transport of gas bubbles through the pulmonary circulation

The assumption that the lung is an effective filter for gas bubbles is of importance for certain occupations (e.g., divers, astronauts) as well as in the accomplishment of several medical procedures. The filtering capacity was tested in pigs by use of continuous air infusion into the right ventricle and a transesophageal echocardiographic transducer for detection of air in the left atrium. Twenty pigs, anesthetized with pentobarbital sodium and mechanically ventilated, were divided into groups that received air at infusion rates of 0.05 (group 1a, n = 7), 0.10 (group 2, n = 6), and 0.20 (group 3, n = 5) ml.kg-1.min-1. Two pigs served as controls. The breakthrough incidence was 0, 67, and 100%, respectively. Group 1a received a second infusion of 0.10 ml.kg-1.min-1 (group 1b, n = 7), and spillover of bubbles occurred in only 14% of these pigs. Infusion of gas caused a maximum increase in mean pulmonary arterial pressure (PAP) of 129 +/- 9% to 39.2 +/- 1.3 (SE) mmHg, with no significant difference between the groups. Breakthrough was observed only in animals with a dramatic reduction in mean arterial pressure and a PAP that returned to almost-normal values at spillover time. Our results suggest that the threshold value for breakthrough of air bubbles in pigs is reduced compared with that in dogs. The hemodynamic consequences at a given infusion rate are, however, greatly enhanced.     

Interaction of chemical and high vascular pressure injury in isolated canine lung

Because both chemical and mechanical insults to the lung may occur concomitantly with trauma, we hypothesized that the pressure threshold for vascular pressure-induced (mechanical) injury would be decreased after a chemical insult to the lung. Normal isolated canine lung lobes (N, n = 14) and those injured with either airway acid instillation (AAI, n = 18) or intravascular oleic acid (OA, n = 25) were exposed to short (5-min) periods of elevated venous pressure (HiPv) ranging from 19 to 130 cmH2O. Before the HiPv stress, the capillary filtration coefficient (Kf,c) was 0.12 +/- 0.01, 0.27 +/- 0.03, and 0.31 +/- 0.02 ml.min-1.cmH2O-1 x 100 g-1 and the isogravimetric capillary pressure (Pc,i) was 9.2 +/- 0.3, 6.8 +/- 0.5, and 6.5 +/- 0.3 cmH2O in N, AAI, and OA lungs, respectively. However, the pattern of response to HiPv was similar in all groups: Kf,c was no different from the pre-HiPv value when the peak venous pressure (Pv) remained less than 55 cmH2O, but it increased reversibly when peak Pv exceeded 55 cmH2O (P less than 0.05). The reflection coefficient (sigma) for total proteins measured after pressure exposure averaged 0.60 +/- 0.03, 0.32 +/- 0.04, and 0.37 +/- 0.09 for N, AAI, and OA lobes respectively. However, in contrast to the result expected if pore stretching had occurred at high pressure, in all groups the sigma measured during the HiPv stress when Pv exceeded 55 cmH2O was significantly larger than that measured during the recovery period.(ABSTRACT TRUNCATED AT 250 WORDS)     

Chest wall restriction limits high airway pressure-induced lung injury in young rabbits

High peak inspiratory pressures (PIP) during mechanical ventilation can induce lung injury. In the present study we compare the respective roles of high tidal volume with high PIP in intact immature rabbits to determine whether the increase in capillary permeability is the result of overdistension of the lung or direct pressure effects. New Zealand White rabbits were assigned to one of three protocols, which produced different degrees of inspiratory volume limitation: intact closed-chest animals (CC), closed-chest animals with a full-body plaster cast (C), and isolated excised lungs (IL). The intact animals were ventilated at 15, 30, or 45 cmH2O PIP for 1 h, and the lungs of the CC and C groups were placed in an isolated lung perfusion system. Microvascular permeability was evaluated using the capillary filtration coefficient (Kfc). Base-line Kfc for isolated lungs before ventilation was 0.33 +/- 0.31 ml.min-1.cmH2O-1.100g-1 and was not different from the Kfc in the CC group ventilated with 15 cmH2O PIP. Kfc increased by 850% after ventilation with only 15 cmH2O PIP in the unrestricted IL group, and in the CC group Kfc increased by 31% after 30 cmH2O PIP and 430% after 45 cmH2O PIP. Inspiratory volume limitation by the plaster cast in the C group prevented any significant increase in Kfc at the PIP values used. These data indicate that volume distension of the lung rather than high PIP per se produces microvascular damage in the immature rabbit lung.     

Effects of increased pulmonary vascular tone on gas exchange in canine oleic acid pulmonary edema

Pulmonary gas exchange was investigated before and after an increase in pulmonary vascular tone induced by administration of acetylsalicylic acid (ASA), indomethacin, or almitrine in 32 pentobarbital-anesthetized and ventilated (fraction of inspired O2 0.4) dogs with oleic acid lung injury. Pulmonary vascular tone was evaluated by five-point pulmonary arterial pressure (PAP)/cardiac index (Q) plots and intrapulmonary shunt was measured using a SF6 infusion. PAP/Q plots were rectilinear in all experimental conditions. In control dogs (n = 8), oleic acid (0.09 ml/kg iv) increased PAP over the range of Q studied (1-5 l.min-1.m-2). At the same Q, arterial PO2 fell from 186 +/- 11 to 65 +/- 8 (SE) Torr and intrapulmonary shunt rose from 5 +/- 1 to 50 +/- 6% 90 min after oleic acid injection. These changes remained stable during the generation of two consecutive PAP/Q plots. ASA (1 g iv, n = 8), indomethacin (2 mg/kg iv, n = 8), and almitrine (8 micrograms.kg-1.min-1 iv, n = 8) produced a further increase in PAP at each level of Q. ASA and indomethacin, respectively, increased arterial PO2 from 61 +/- 4 to 70 +/- 3 Torr (P less than 0.05) and from 70 +/- 6 to 86 +/- 6 Torr (P less than 0.05) and decreased intrapulmonary shunt from 61 +/- 5 to 44 +/- 4% (P less than 0.05) and from 44 +/- 5 to 29 +/- 4% (P less than 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)     

Sites of leakage in three models of acute lung injury

Fluid leaking from arterial and venous extra-alveolar vessels (EAV's) may account for up to 60% of the total transvascular fluid flux when edema occurs in the setting of normal vascular permeability. We determined if the permeability and relative contribution of EAV's was altered after inducing acute lung injury in rabbits by administering oleic acid (0.1 ml/kg) into the pulmonary artery, HCl (5 ml/kg of 0.1 N) into the trachea, or air emboli (0.03 ml.kg-1.min-1) into the right atrium for 90 min. Subsequently, the lungs were excised and continuously weighed while they were maintained in a warmed, humidified chamber with alveolar and pulmonary vascular pressures controlled and the lungs either ventilated or distended with 5% CO2 in air. The vascular system was filled with autologous blood and saline (1:1) to which papaverine (0.1 mg/ml) was added to inhibit vasospasm. Vascular pressures were referenced to the lung base. After a transient hydrostatic stress to maximize recruitment, vascular pressures were set at 5 cmH2O, and lungs were allowed to become isogravimetric (30-60 min). A fluid filtration coefficient (Kf) was determined by the use of a modification of the method of Drake and colleagues [Am. J. Physiol. 234 (Heart Circ. Physiol. 3): H266-H274, 1978]. EAV's were isolated by zoning techniques. In control preparations arterial and venous EAV's accounted for 26% (n = 9) and 38% (n = 11) of the total leakage, respectively. In all three models Kf increased two- to fourfold when the lungs were in zone 3 (alveolar vessels and arterial and venous EAV's contributing to the leakage).(ABSTRACT TRUNCATED AT 250 WORDS)     

Filtration coefficient obtained by stepwise pressure elevation in isolated dog lung

The base-line capillary filtration coefficient (Kf) obtained from rates of lobe weight gain during stepwise vascular pressure elevation is reported to be threefold greater in isolated than in intact dog lung. To further evaluate the stepwise pressure elevation technique, we obtained Kf in control and oleic acid-injured isolated lung. The left lower lung lobe was removed, placed on a balance, ventilated, and pump perfused with autogenous blood. Saline (n = 6) or oleic acid (n = 6) was infused, and rate of lobe weight gain was obtained during stepwise pressure elevation. Kf averaged 0.071 +/- 0.012 and 0.243 +/- 0.027 ml X min-1 X Torr-1 X 100 g-1 in the control and injured lobes, respectively. Stepwise pressure elevation can yield a base-line Kf in isolated lung similar to Kf's obtained from this and other gravimetric methods in intact and isolated lung. Furthermore, Kf increased severalfold following lung injury with oleic acid. The stepwise pressure elevation technique for Kf determination in isolated lung can be a useful tool for quantitating changes in vascular permeability.     

PET evaluation of pulmonary vascular permeability: a structure-function correlation

We compared regional measurements of the pulmonary transcapillary escape rate (rPTCER) for 68Ga-transferrin, obtained by positron emission tomography (PET), with morphometric data obtained from corresponding tissue samples in six anesthetized mechanically ventilated dogs, 1 h after oleic acid administration to either the left caudal lobe (0.015 ml/kg; Lobar group, n = 3) or the right atrium (0.08 ml/kg; Diffuse group, n = 3). Data were obtained from 48 regions in both injured and control lobes (right caudal lobes from the Lobar group). The volume density of edematous or hemorrhagic alveoli at the light-microscopic level was directly related to rPTCER (r = 0.82 for regions with rPTCER values less than 700 x 10(-4) min-1). Likewise, the relative surface of abnormal capillary endothelium and alveolar epithelium at the electron-microscopic level correlated well with rPTCER (r = 0.87 for regions with rPTCER less than 1,200 X 10(-4) min-1). We conclude that the rPTCER measurements obtained with PET reflect the morphological heterogeneity present in oleic acid-damaged lung tissue. Thus rPTCER measurements should be useful as a noninvasive quantitative index of lung injury. Furthermore, the tomographic image display of rPTCER may allow PET to be used as a "physiological probe" to guide tissue excision for later histological evaluation when lung injury is heterogeneous.