Leukotriene E4 causes pulmonary vasoconstriction,not inhibited by meclofenamate

Leukotriene E₄ (LTE₄) appears to be a rather stable product of the lipoxygenase pathway. Its action in the pulmonary circulation is unknown. Therefore we investigated its effect on the circulation of isolated rat lungs perfused with a cell- and plasma-free solution. Synthetic LTE₄ in doses from .15 μg to 5μg/ .25 ml .9% NaCl injected as a bolus in the pulmonary artery during normoxia caused a fast, transient perfusion pressure increase within seconds. This was followed by a slow rise in baseline perfusion pressure (normoxia) over 25 min. In addition, 5 μm LTE₄ caused edematogenic lung damage. Injection of 1.5 μg LTE₄ during hypoxic vasoconstriction caused fast, transient pressure rises, similar to normoxic conditions. 6-keto-PGF_1α and TXB₂ were measured in the lung effluent before and after LTE₄ injection. Neither 6-keto-PGF_1α nor TXB₂ production changed after LTE₄ injection. Meclofenamate (.5 μg/ml) increased the fast, transient and the slow, sustained pressure rise. We conclude that LTE₄ caused direct pulmonary vasoconstriction unrelated to cycloxygenase products.     

Effects of arachidonic acid and prostaglandin F2 alpha in isolated rat lungs

Isolated rat lungs were ventilated and perfused by saline-Ficoll perfusate at a constant flow. The baseline perfusion pressure (PAP) correlated with the concentration of 6-keto-PGF1 alpha the stable metabolite of PGI2 (r = 0.83) and with the 6-keto-PGF1 alpha/TXB2 ratio (r = 0.82). A bolus of 10 micrograms exogenous arachidonic acid (AA) injected into the arterial cannula of the isolated lungs caused significant decrease in pulmonary vascular resistance (PVR) which was followed by a progressive increase of PVR and edema formation. Changes in perfusion pressure induced by AA injection also correlated with concentrations of the stable metabolites (6-keto-PGF1 alpha: r = -0.77, TxB2: -0.76), and their ratio: (6-keto-PGF1 alpha/TXB2: r = -0.73). Injection of 10 and 100 micrograms of PGF2 alpha into the pulmonary artery stimulated the dose-dependent production of TXB2 and 6-keto-PGF1 alpha. No significant correlations were found between the perfusion pressure (PAP) which was increased by the PGF2 alpha and the concentrations of the former stable metabolites. The results show that AA has a biphasic effect on the isolated lung vasculature even in low dose. The most potent vasoactive metabolites of cyclooxygenase, prostacyclin and thromboxane A2 influence substantially not only the basal but also the increased tone of the pulmonary vessels.     

Dose-dependent effects of a pyridoquinazoline thromboxane synthetase inhibitor on arachidonic acid metabolites and hemodynamics during E. coli endotoxemia in anesthetized sheep

We investigated the effects of a new pyridoquinazoline thromboxane synthetase inhibitor infused before administering Escherichia Coli endotoxin into 18 anesthetized sheep with lung lymph fistulas. In normal sheep increasing plasma Ro 23-3423 concentrations were associated with increased plasma levels of 6-keto-PGF1 alpha, a reduced systemic vascular resistance (SVR, r = -0.80) and systemic arterial pressure (SAP, r = -0.92), the mean SAP falling from 80 to 50 mm Hg at the 20 and 30 mg/kg doses. Endotoxin infused into normal sheep caused transient pulmonary vasoconstriction associated with increased TxB2 and 6-keto-PGF1 alpha levels while vasoconstriction and TxB2 increase were significantly inhibited by pretreatment with Ro 23-3423 in a dose-dependent manner. When compared to controls, plasma and lymph levels of 6-keto-PGF1 alpha, PGF2 alpha and PGE2 after endotoxin infusion were increased several-fold by administering Ro 23-3423 up to plasma levels of 10 micrograms/ml. Doses over 30 mg/kg with blood levels above 10 micrograms/ml reduced plasma and lymph levels of 6-keto-PGF1 alpha, PGF2 alpha and PGE2, suggesting cyclooxygenase blockade at this dose. The peak 6-keto-PGF1 alpha levels at 60 min after endotoxin infusion in sheep with Ro-23-3423 levels below 10 micrograms/ml were associated with the greatest systemic hypotension due to a reduced SVR (r = -0.86). After endotoxin infusion the leukotrienes B4, C4, D4 and E4 in lung lymph were assayed by radioimmunoassay and high pressure liquid chromatography and remained at baseline values.     

Acute hypoxia alters eicosanoid production of perfused pulmonary artery endothelial cells in culture.

Hypoxia alters vascular tone which regulates regional blood flow in the pulmonary circulation. Endothelial derived eicosanoids alter vascular tone and blood flow and have been implicated as modulators of hypoxic pulmonary vasoconstriction. Eicosanoid production was measured in cultured bovine pulmonary endothelial cells during constant flow and pressure perfusion at two oxygen tensions (hypoxia: 4% O2, 5% CO2, 91% N2; normoxia: 21% O2, 5% CO2, 74% N2). Endothelial cells were grown to confluence on microcarrier beads. Cell cartridges (N = 8) containing 2 ml of microcarrier beads (congruent to 5 x 10(6) cells) were constantly perfused (3 ml/min) with Krebs' solutions (pH 7.4, T 37 degrees C) equilibrated with each gas mixture. After a ten minute equilibration period, lipids were extracted (C18 Sep Pak) from twenty minute aliquots of perfusate over three hours (nine aliquots per cartridge). Eicosanoids (6-keto PGF1 alpha; TXB2; and total leukotriene [LT - LTC4, LTD4, LTE4, LTF4]) were assayed by radioimmunoassay. Eicosanoid production did not vary over time. 6-keto PGF1 alpha production was increased during hypoxia (normoxia 291 +/- 27 vs hypoxia 395 +/- 35 ng/min/gm protein; p less than 0.01). Thromboxane production (normoxia 19 +/- 2 vs hypoxia 20 +/- 2 ng/min/gm protein) and total leukotriene production (normoxia 363 +/- 35 vs hypoxia 329 +/- 29 ng/min/gm protein) did not change with hypoxia. These data demonstrated that oxygen increased endothelial prostacyclin production but did not effect thromboxane or leukotriene production.     

Arachidonic acid causes cyclooxygenase-dependent and -independent pulmonary vasodilation

In this study we examined the action of arachidonic acid in the isolated rat lung perfused with a cell- and protein-free physiological salt solution. When pulmonary vascular tone was elevated by hypoxia, bolus injection of a large dose of arachidonic acid (75 micrograms) caused transient vasoconstriction followed by vasodilation. When arachidonic acid (100 micrograms) was injected during normoxia and at base-line perfusion pressure (low vascular tone) or when vascular tone was elevated by KCl, arachidonic acid (50 micrograms) caused only vasoconstriction. Doses less than 7.5 micrograms caused vasodilation only when injected during hypoxic vasoconstriction and subsequent blunting of either angiotensin II- or hypoxia-induced pulmonary vasoconstriction. The higher doses of arachidonic acid (7.5 and 75 micrograms), but not the lower doses (7.5-750 ng), caused increases in effluent 6-ketoprostaglandin F1 alpha, thromboxane B2, and prostaglandin E2 and F2 alpha. 6-Ketoprostaglandin F1 alpha was the major cyclooxygenase product. Meclofenamate (10(-5) M) blocked the increased metabolite synthesis over the entire dose range of arachidonic acid tested (7.5 ng-75 micrograms). Because vasodilation immediately after arachidonic acid was cyclooxygenase-independent, we investigated whether this effect was due to the unsaturated fatty acid properties of arachidonic acid and compared its action with that of oleic acid and docosahexaenoic acid. Because neither compound mimicked the vasodilation observed with arachidonic acid, we concluded that the cyclooxygenase-independent action of arachidonic acid could not be explained by unsaturated fatty acid properties per se. Because 1-aminobenzotriazole, a cytochrome P-450 inhibitor, partially inhibited the immediate arachidonic acid-induced pulmonary vasodilation, we concluded that cytochrome P-450-dependent metabolites can account for some of the cyclooxygenase-independent vasodilation of arachidonic acid.     

Effect of LY171883 on endotoxin-induced lung injury in pigs

We evaluated the role of sulfidopeptide leukotrienes as mediators of endotoxin-induced respiratory failure in pigs. Escherichia coli endotoxin (055-B5) was infused intravenously into anesthetized 10- to 14-wk-old pigs at 5 micrograms/kg the 1st h followed by 2 micrograms.kg-1.h-1 for 3 h in the presence and absence of LY171883, a specific leukotriene D4 (LTD4)/LTE4 receptor antagonist. Endotoxin caused hemoconcentration, granulocytopenia, decreased cardiac index, systemic hypotension, pulmonary hypertension, increased pulmonary vascular resistance, bronchoconstriction, hypoxemia, increased permeability of the alveolar-capillary membrane, pulmonary edema, and increased plasma concentrations of thromboxane B2 (TxB2), prostaglandin F2 alpha (PGF2 alpha), and 6-keto-PGF1 alpha. LY171883 did not modify endotoxin-induced cardiopulmonary and hematologic abnormalities, except for a modest attenuation of pulmonary hypertension (at 1 h) and increased pulmonary vascular resistance (at 1-2 h). Ex vivo stimulation of whole blood with calcium ionophore caused large increases in plasma concentrations of TxB2, PGF2 alpha, and LTB4. These increases were not significantly modified in blood derived from pigs treated with LY171883, indicating no inhibition of cyclooxygenase or 5-lipoxygenase. We conclude that LTD4 and LTE4 are not important mediators of endotoxin-induced lung injury in anesthetized pigs, although they may contribute modestly to pulmonary vasoconstriction.     

Relevance of vasoactive mediators for the blood pressure effects of intravenous arachidonic acid injection in rats.

Vasopressor response and release of eicosanoids following intravenous injection of arachidonic acid (AA) were examined in normotensive rats. AA administration caused a rapid initial fall of arterial pressure followed by a brief rise and a subsequent prolonged fall in anesthetized rats. Immediately after AA injection the blood levels of TXB2 and 6-keto-PGF1 alpha, the stable metabolites of TXA2 and prostacyclin, rose, from 1.52 +/- 0.23 ng/ml to 176.4 +/- 42.6 ng/ml and from 4.05 +/- 0.67 ng/ml to 171.4 +/- 31.2 ng/ml, respectively. Blood pressure behaviour and eicosanoid blood level were influenced by different inhibitors and antagonists of vasoactive mediators. The cyclooxygenase inhibitor acetylsalicylic acid completely eliminated the second blood pressure depression after AA injection and simultaneously diminished TXB2 and 6-keto-PGF1 alpha formation in murine blood, whereas the TXA2 receptor antagonist BM 13.177 prevented the return of the blood pressure to preinjection level after the initial brief fall in arterial pressure. Although the TXA2 synthase inhibitor HOE 944 markedly inhibited TXB2 formation, no influence on AA-induced blood pressure changes could be registered. The receptor antagonist of platelet activating factor BN 52021 and the serotonin and histamine receptor antagonist cyproheptadine also reduced TXB2 amounts, in murine blood without any effects on blood pressure behaviour.     

Effect of endotoxemia on hypoxic pulmonary vasoconstriction in unanesthetized sheep

This study examined the effect of acute endotoxemia on hypoxic pulmonary vasoconstriction (HPV) in awake sheep. Thirteen sheep were chronically instrumented with Silastic catheters in the pulmonary artery, left atrium, jugular vein, and carotid artery; with a Swan-Ganz catheter in the main pulmonary artery; with a chronic lung lymph fistula; and with a tracheostomy. Base-line HPV was determined by measuring the change in pulmonary vascular resistance (PVR) while sheep breathed 12% O2 for 7 min. Concentrations of immunoreactive 6-keto-PGF1 alpha and thromboxane B2 (TXB2) were measured in lung lymph during the hypoxic challenge. Escherichia coli endotoxin (0.2-0.5 micrograms/kg) was infused intravenously. Four hours after endotoxemia, HPV was measured. In five sheep, meclofenamate was infused at 4.5 h after endotoxemia and HPV measured again. During the base-line hypoxic challenge, PVR increased by 36 +/- 9% (mean +/- SE). There was no significant change in lung lymph 6-keto-PGF1 alpha or TXB2 levels with hypoxia. Twelve of the 13 sheep showed a decrease in HPV 4 h after endotoxemia; the mean change in PVR with hypoxia was -8 +/- 5%, which was significantly (P less than 0.05) reduced compared with base-line HPV. The infusion of meclofenamate at 4.5 h after endotoxin did not restore HPV.     

Acetylcholine induces vasodilation and prostacyclin synthesis in rat lungs

Acetylcholine causes pulmonary vasodilation, but its mechanism of action is unclear. We hypothesized that acetylcholine-induced pulmonary vasodilation might be associated with prostacyclin formation. Therefore, we used isolated rat lungs perfused with a recirculating cell- and plasma-free physiological salt solution to study the effect of acetylcholine infusion on pulmonary perfusion pressure, vascular responsiveness and lung prostacyclin production. Acetylcholine (20 micrograms infused over 1 minute) caused immediate vasodilation during ongoing hypoxic vasoconstriction and prolonged depression of subsequent hypoxic and angiotensin II-induced vasoconstrictions. Both effects of acetylcholine were abolished by atropine pretreatment. The prolonged acetylcholine effect, but not the immediate response, was blocked by meclofenamate, an inhibitor of cyclooxygenase. The prolonged effect, but not the immediate response, of acetylcholine was associated with an increase in perfusate 6-keto-PGF1 alpha concentration. The acetylcholine stimulated increase in 6-keto-PGF1 alpha production was inhibited by meclofenamate and by atropine. Thus, blockade of prostacyclin production corresponded with blockade of the prolonged acetylcholine effect. In conclusion, acetylcholine caused in isolated rat lungs an immediate vasodilation and a prolonged, time-dependent depression of vascular responsiveness. Whereas both acetylcholine effects were under muscarinic receptor control, only the prolonged effect depended on the cyclooxygenase pathway and, presumably, prostacyclin synthesis.     

Prolonged pulmonary hypertension caused by platelet-activating factor and leukotriene C4 in the rat lung.

Platelet-activating factor (PAF) and leukotrienes (LTs) are potent pulmonary hypertensive and inflammatory mediators produced by the lung. Previously we showed that a rapid injection of PAF into the pulmonary artery of an isolated rat lung produced an extended elevation in mean pulmonary arterial pressure (PAP). The objective of the present study was to determine whether the extended pressor response induced by PAF was caused by prolonged activation of the 5-lipoxygenase pathway or slow clearance of LTs from the lung parenchyma. Rat lungs were perfused with a nonrecirculating physiological salt solution that contained indomethacin and albumin. Five minutes after a rapid injection of PAF into the pulmonary artery catheter, the following elevations (mean % above baseline) were observed: PAP (83%), LTB4 (3,260%), LTC4 (1,490%), LTD4 (970%), and LTE4 (1,500%). At 20 min these levels declined but were still significantly elevated above baseline. The 5-lipoxygenase inhibitor diethylcarbamazine (DEC), administered before the PAF injection, inhibited the elevations of PAP and all LTs. DEC administration that began 5 min after PAF reduced PAP and only LTC4 levels at 20 min in comparison to lungs with no DEC. The 5-lipoxygenase-activating protein inhibitor MK886, administered orally 2-6 h before perfusion, also inhibited the pressor response to PAF as well as LT production, as did DEC. We conclude that 1) the extended pulmonary hypertension induced by PAF was caused mainly by prolonged activation of 5-lipoxygenase with LTC4 production, 2) the relative overall lung clearance of LTB4, LTD4, and LTE4 was slower than that of LTC4, and 3) LTB4, LTD4, and LTE4 had no appreciable pressor effect.     

Effects of imidazole and indomethacin on fluid balance in isolated sheep lungs

We determined the effects of extracorporeal perfusion with a constant flow (75 ml . min-1 . kg-1) of autologous blood on hemodynamics and fluid balance in sheep lungs isolated in situ. After 5 min, perfusate leukocyte and platelet counts fell by two-thirds. Pulmonary arterial pressure (Ppa) increased to a maximum of 32.0 +/- 3.4 Torr at 30 min and thereafter fell. Lung lymph flow (QL), measured from the superior thoracic duct, and perfusate thromboxane B2 (TXB2) concentrations followed similar time courses but lagged behind Ppa, reaching maxima of 4.1 +/- 1.2 ml/h and 2.22 +/- 0.02 ng/ml at 60 min. Lung weight gain, measured as the opposite of the weight change of the extracorporeal reservoir, and perfusate 6-ketoprostaglandin F1 alpha (6-keto-PGF1 alpha) concentration increased rapidly during the first 60 min and then more gradually. After 210 min, weight gain was 224 +/- 40 g and 6-keto-PGF1 alpha concentration, 4.99 +/- 0.01 ng/ml. The ratio of lymph to plasma oncotic pressure (pi L/pi P) at 30 min was 0.61 +/- 0.06 and did not change significantly. Imidazole (5 mM) reduced the changes in TXB2, Ppa, QL, and weight and platelet count but did not alter 6-keto-PGF1 alpha, pi L/pi P, or leukocyte count. Indomethacin (0.056 mM) reduced TXB2, 6-keto-PGF1 alpha, and the early increases in weight, Ppa, and QL but did not alter the time courses of leukocyte or platelet counts. Late in perfusion, however, Ppa and QL were greater than in either untreated or imidazole-treated lungs.(ABSTRACT TRUNCATED AT 250 WORDS)     

Prostanoids and hemodynamics in man before and during cardiopulmonary bypass

The plasma concentration of 6-keto-PGF1 alpha, the stable degradation product of prostacyclin, was similar in the radial and pulmonary arteries and in the coronary sinus before and after the induction of the anesthesia in patients undergoing coronary artery bypass surgery. After the beginning of the mechanical ventilation and anesthesia the pulmonary vascular resistance decreased although no changes were detected in the plasma levels of 6-keto-PGF1 alpha or TXB2. During the prebypass period after the sternotomy and cannulation of the large vessels the plasma level of 6-keto-PGF1 alpha was increased similarly in the radial and pulmonary arteries and even more in the coronary sinus. During the cardiopulmonary bypass the concentration of 6-keto-PGF1 alpha remained at the increased level as compared to the values before the anesthesia. This indicates that pulmonary circulation is perhaps not the main source of prostacyclin in man. The plasma level of TXB2 was increased during the prebypass period significantly only in the coronary sinus, but during the bypass also in the radial artery. The concentration ratio of 6-keto-PGF1 alpha/TXB2 was increased significantly during the prebypass period in the radial and pulmonary arteries. At the same time the pulmonary vascular resistance was, however, returned to the preanesthesia level and was thus not decreased. The vascular resistance in the systemic circulation was increased during the prebypass period. The plasma level of 6-keto-PGF1 alpha or TXB2 in the radial and pulmonary arteries did not correlate significantly with the total vascular resistance in the systemic and pulmonary circulation, respectively. The vascular resistance in the coronary circulation did not correlate significantly with TXB2 level in the radial artery or coronary sinus. There was, however, a slight positive correlation between the blood flow and the concentration of TXB2 in the coronary sinus (r = 0.76, P less than 0.01). Coronary sinus flow did, however, not correlate with the plasma level of 6-keto-PGF1 alpha in the radial artery or coronary sinus. These results indicate that the detected plasma concentrations of prostacyclin and thromboxane A2 have no significant effects on the total vascular resistance in vivo.     

Regional pulmonary blood flow during 96 hours of hypoxia in conscious sheep

The effects of acute hypoxia on regional pulmonary perfusion have been studied previously in anesthetized, artificially ventilated sheep (J. Appl. Physiol. 56: 338-342, 1984). That study indicated that a rise in pulmonary arterial pressure was associated with a shift of pulmonary blood flow toward dorsal (nondependent) areas of the lung. This study examined the relationship between the pulmonary arterial pressor response and regional pulmonary blood flow in five conscious, standing ewes during 96 h of normobaric hypoxia. The sheep were made hypoxic by N2 dilution in an environmental chamber [arterial O2 tension (PaO2) = 37-42 Torr, arterial CO2 tension (PaCO2) = 25-30 Torr]. Regional pulmonary blood flow was calculated by injecting 15-micron radiolabeled microspheres into the superior vena cava during normoxia and at 24-h intervals of hypoxia. Pulmonary arterial pressure increased from 12 Torr during normoxia to 19-22 Torr throughout hypoxia (alpha less than 0.049). Pulmonary blood flow, expressed as %QCO or ml X min-1 X g-1, did not shift among dorsal and ventral regions during hypoxia (alpha greater than 0.25); nor were there interlobar shifts of blood flow (alpha greater than 0.10). These data suggest that conscious, standing sheep do not demonstrate a shift in pulmonary blood flow during 96 h of normobaric hypoxia even though pulmonary arterial pressure rises 7-10 Torr. We question whether global hypoxic pulmonary vasoconstriction is, by itself, beneficial to the sheep.     

Effect of fenoldopam on preconstricted isolated salt-perfused rat lungs

Using an in situ isolated salt-perfused rat lung preparation, we investigated the pulmonary vascular response to fenoldopam (a highly selective dopamine (DA1) agonist) infused at six different doses ranging from 0.1 to 10,000 micrograms/kg, during prostaglandin F2 alpha- (PGF2 alpha) induced pulmonary vasoconstriction. These experiments were repeated after selective DA1-blockade with SCH 23390. Twelve experiments were performed to evaluate the effect of fenoldopam on base-line hemodynamics. Sixty experiments were performed after PGF2 alpha vasoconstriction. Thirty lung preparations were pretreated with SCH 23390. PGF2 alpha was infused into the pulmonary inflow catheter at 2.5 micrograms.kg-1.min-1 to give a sustained rise in mean pulmonary arterial pressure (5.0 +/- 1.0 mmHg). Fenoldopam, at doses of 0.1, 1, 10, 100, 1,000, or 10,000 micrograms/kg, was injected into the pulmonary artery (n = 5 blocked and n = 5 unblocked at each dose). Fenoldopam had no effect on hemodynamics in the absence of PGF2 alpha. In the unblocked group, after PGF2 alpha vasoconstriction, fenoldopam infusion resulted in a dose-dependent decrease in the mean pulmonary arterial pressure with a dose-response curve characteristic for a drug-receptor interaction [Response = -1.0 (log Dose) -1.6]. In the DA1-blocked group after PGE2 alpha vasoconstriction, the dose-response curve was shifted to the right but parallel to the unblocked group, indicating competitive receptor blockade [Response -0.8 (log Dose) -0.05]. We conclude that vasodilatory DA1-receptors are responsible for the observed results.     

Does leukotriene C4 mediate hypoxic vasoconstriction in isolated ferret lungs?

To evaluate leukotriene (LT) C4 as a mediator of hypoxic pulmonary vasoconstriction, we examined the effects of FPL55712, a putative LT antagonist, and indomethacin, a cyclooxygenase inhibitor, on vasopressor responses to LTC4 and hypoxia (inspired O2 tension = 25 Torr) in isolated ferret lungs perfused with a constant flow (50 ml.kg-1.min-1). Pulmonary arterial injections of LTC4 caused dose-related increases in pulmonary arterial pressure during perfusion with physiological salt solution containing Ficoll (4 g/dl). FPL55712 caused concentration-related inhibition of the pressor response to LTC4 (0.6 micrograms). Although 10 micrograms/ml FPL55712 inhibited the LTC4 pressor response by 61%, it did not alter the response to hypoxia. At 100 microgram/ml, FPL55712 inhibited the responses to LTC4 and hypoxia by 73 and 71%, respectively, but also attenuated the vasoconstrictor responses to prostaglandin F2 alpha (78% at 8 micrograms), phenylephrine (68% at 100 micrograms), and KCl (51% at 40 mM). At 0.5 microgram/ml, indomethacin significantly attenuated the pressor response to arachidonic acid but did not alter responses to LTC4 or hypoxia. These results suggest that in isolated ferret lungs 1) the vasoconstrictor response to LTC4 did not depend on release of cyclooxygenase products and 2) LTC4 did not mediate hypoxic vasoconstriction.     

Actions of lipoxygenase metabolites in isolated rat lungs

Leukotrienes constrict smooth muscle and could be important for the regulation of the pulmonary circulation. We examined the production and action of lipoxygenase metabolites in isolated lungs, where we controlled the perfusing fluid used. Arachidonate injected into isolated rat lungs perfused with cell- and protein-free physiological salt solution caused a transient pressor response. Following indomethacin, arachidonate caused a delayed slow pressure rise followed by edema. The lung effluent contracted the guinea pig ileum. High-pressure liquid chromatography (HPLC) analysis of the perfusate demonstrated the presence of leukotrienes (LTC4 and LTD4). Diethylcarbamazine, a leukotriene synthesis inhibitor, prevented the slow pressure rise and edema seen after indomethacin plus arachidonate. In lungs perfused with cell- and protein-free physiological salt solution, LTC4, but not LTD4, caused a transient pressure rise followed by a sustained pressure rise. The sustained rise was abolished by a leukotriene-receptor blocker (FPL 55712) but not by indomethacin. In blood-perfused lungs, LTC4 caused only the transient pressure rise that was not blocked by FPL 55712. In lungs perfused with physiological salt solution containing albumin, LTC4 had no effect. We concluded that 1) perfused nonsensitized rat lungs produced LTC4 and LTD4; 2) LTC4 may be a major pulmonary vasoconstrictor; and 3) albumin binding limits the pressor effect of LTC4.     

Selective inhibition of arachidonic acid metabolite release from human lung tissue by antiinflammatory steroids

The effects of antiinflammatory steroids on arachidonic acid metabolite release from human lung fragments were analyzed. Incubation of lung fragments for 24 hr with 10(-6) M dexamethasone inhibited the net release of the prostacyclin metabolite 6-keto-PGF1 alpha, PGE2, and PGF2 alpha from lung fragments stimulated with anti-IgE but failed to inhibit the anti-IgE-induced release of PGD2, TXB2, and iLTC4. The IC50 of dexamethasone for inhibition of both spontaneous and anti-IgE-induced 6-keto-PGF1 alpha release was approximately 2 X 10(-8) M, and a 6-hr preincubation with the drug was required for 50% inhibition of prostaglandin release. Other agents were tested for activity in stimulating arachidonic acid metabolite release from human lung fragments. FMLP (fmet-leu-phe) stimulated the release of all metabolites tested (6-keto-PGF1 alpha, PGD2, PGE2, PGF2 alpha, TXB2, iLTC4); platelet-activating factor (PAF), but not lysoPAF, stimulated the release of PGD2, TXB2, and iLTC4. In contrast to the case with anti-IgE, where dexamethasone failed to inhibit net PGD2 and TXB2 release, the steroid inhibited the release of these metabolites stimulated by both FMLP and PAF. The steroid inhibited iLTC4 release induced by the highest concentration of PAF (10(-6)M) but did not inhibit iLTC4 release stimulated by either 10(-7) M PAF, FMLP, or anti-IgE. Because neither FMLP nor PAF caused the release of PGD2 or TXB2 from purified human lung mast cells, and because they also failed to induce histamine release from lung fragments, it is suggested that these stimuli produce PGD2 and TXB2 release in lung fragments through an action on a cell distinct from the mast cell. This suggestion is supported by the selective inhibition of the release of these arachidonic acid metabolites by dexamethasone. We suggest that the inhibitory action of steroids on arachidonic acid metabolite in human lung fragments contributes to their therapeutic efficacy in pulmonary diseases.     

Flow-mediated release of nitric oxide in isolated, perfused rabbit lungs.

The effects of changing perfusate flow on lung nitric oxide (NO) production and pulmonary arterial pressure (Ppa) were tested during normoxia and hypoxia and after N(G)-monomethyl-L-arginine (L-NMMA) treatment during normoxia in both blood- and buffer-perfused rabbit lungs. Exhaled NO (eNO) was unaltered by changing perfusate flow in blood-perfused lungs. In buffer-perfused lungs, bolus injections of ACh into the pulmonary artery evoked a transient increase in eNO from 67 +/- 3 (SE) to 83 +/- 7 parts/billion with decrease in Ppa, whereas perfusate NO metabolites (pNOx) remained unchanged. Stepwise increments in flow from 25 to 150 ml/min caused corresponding stepwise elevations in eNO production (46 +/- 2 to 73 +/- 3 nl/min) without changes in pNOx during normoxia. Despite a reduction in the baseline level of eNO, flow-dependent increases in eNO were still observed during hypoxia. L-NMMA caused declines in both eNO and pNOx with a rise in Ppa. Pulmonary vascular conductance progressively increased with increasing flow during normoxia and hypoxia. However, L-NMMA blocked the flow-dependent increase in conductance over the range of 50-150 ml/min of flow. In the more physiological conditions of blood perfusion, eNO does not reflect endothelial NO production. However, from the buffer perfusion study, we suggest that endothelial NO production secondary to increasing flow, may contribute to capillary recruitment and/or shear stress-induced vasodilation.     

The concentrations of 6-keto-PGF1 alpha and TXB2 in plasma samples from patients with benign and malignant tumours of the breast

Peripheral plasma concentrations of 6-keto-PGF1 alpha and TXB2 were measured in patients with benign and malignant tumours of the breast, in patients with non-gynecological diseases, and in healthy female controls. The values were significantly higher in female patients with malignant tumours of the breast than in healthy controls (146 +/- 28 vs 13 +/- 2.5 pg/ml for 6-keto-PGF1 alpha p less than 0.01 and 78 +/- 17 vs 11 +/- 2 pg/ml for TXB2, p less than 0.01). Benign tumours of the breast were also associated with significantly raised plasma levels of 6-keto-PGF1 alpha and TXB2 compared to normal controls (52 +/- 5 vs 13 +/- 2.5 pg/ml for 6-keto-PGF1 alpha, p less than 0.01 and 26 +/- 5 vs 11 +/- 2 pg/ml for TXB2, p less than 0.05). The high levels of 6-keto-PGF1 alpha and TXB2 were not found to be correlated with clinical and histopathological data. The surgical removal of the primary tumour has apparently no effect on the plasma concentrations of 6-keto-PGF1 alpha and TXB2 over a follow-up period of 9 days after operation. The lack of alterations in the ratio of TXB2:6-keto-PGF1 alpha in the cancer patients and other subjects studied before and after surgery is indicative of the regulatory power of metabolic systems to preserve the homeostatic balance.     

Decreased pulmonary vascular responsiveness in rats raised on an essential fatty acid deficient diet

Leukotriene C4 is produced during hypoxic pulmonary vasoconstriction and leukotriene inhibitors preferentially inhibit the hypoxic pressor response in rats. If lipoxygenase products are important in hypoxic vasoconstriction, then an animal deficient in arachidonic acid should have a blunted hypoxic pressor response. We investigated if vascular responsiveness was decreased in vascular rings and isolated perfused lungs from rats raised on an essential fatty acid deficient diet (EFAD) compared to rats raised on a normal diet. Rats raised on the EFAD diet had decreased esterified plasma arachidonic acid and increased 5-, 8-, 11-eicosatrienoic acid compared to rats raised on the normal diet (control). Compared to the time matched responses in control isolated perfused lungs the pressor responses to angiotensin II and alveolar hypoxia were blunted in lungs from the arachidonate deficient rats. This decreased pulmonary vascular responsiveness was not affected by the addition of indomethacin or arachidonic acid to the lung perfusate. Similarly, the pulmonary artery rings from arachidonate deficient rats demonstrated decreased reactivity to norepinephrine compared to rings from control rats. In contrast, the tension increases to norepinephrine were greater in aortic rings from the arachidonate deficient rats compared to control. Stimulated lung tissue from the arachidonate deficient animals produced less slow reacting substance and platelet activating factor like material but the same amount of 6-keto-PGF1 alpha and TXB2 compared to control lungs. Thus there is an association between altered vascular responsiveness and impairment of stimulated production of slow reacting substance and platelet activating factor like material in rats raised on an EFAD diet.