We determined the effects of 8-epiprostaglandin (PG) F2 alpha, a noncyclooxygenase free radical-catalyzed product of arachidonic acid, on pulmonary vascular tone, its potency, and its mechanism of action. 8-Epi-PGF2 alpha (0.5-20 micrograms) was injected into the pulmonary artery (PA) catheter of 10 rabbits whose lungs were perfused in situ with Krebs-Henseleit buffer solution with 3% bovine serum albumin. PA pressure increased from a baseline of 13.5 +/- 0.6 to 25.6 +/- 2.0 cmH2O with 20 micrograms 8-epi-PGF2 alpha. 8-Epi-PGF2 alpha caused a rapid rise in PA pressure followed by a gradual decline over 40-60 min to baseline levels. Double vascular occlusion revealed a twofold increase in arterial resistance at peak rise in PA pressure. The rise in PA pressure with 20 micrograms 8-epi-PGF2 alpha was fivefold greater than with 20 micrograms of the cyclooxygenase-derived prostaglandin PGF2 alpha. The PA pressure response to 8-epi-PGF2 alpha was not altered by either cyclooxygenase block-ade with 150 microM meclofenamate or alpha-receptor blockade with 70 microM phentolamine, but was fully prevented by 40 microM SQ 29548, a thromboxane receptor antagonist. We conclude that in rabbits 8-epi-PGF2 alpha is a potent vasoconstrictor of the pulmonary vasculature, which appears to be due to the activation of SQ 29548-responsive thromboxane receptors.
The effects of 8-epi-prostaglandin (PG) F2 alpha, a recently discovered noncyclooxygenase free radical-catalyzed product of arachidonic acid, on pulmonary vascular and airway tone, its potency, and its mechanism of action were studied. Progressively increasing bolus doses (1.0, 5.0, 10.0, and 20.0 micrograms) of 8-epi-PGF2 alpha were injected into the pulmonary artery catheter of 18 isolated rat lungs, and a single dose (40.0 micrograms) was injected into 7 additional rat lungs. The lungs were perfused with Krebs-Henseleit buffer solution containing 3% bovine serum albumin at 50 ml.kg-1.min-1 during ventilation with 21% O2-5% CO2-74% N2. 8-Epi-PGF2 alpha caused rapid pulmonary vascular and airway constrictor responses, which were followed by a gradual return over 10 min to baseline levels. Double vascular occlusion at peak rise in pulmonary arterial pressure (Ppa) revealed a 28% increase in arterial resistance. The rise in Ppa with 20 micrograms of 8-epi-PGF2 alpha was approximately twofold greater than with 20 micrograms of the cyclooxygenase-derived prostaglandin PGF2 alpha. The addition of 100 microM N-nitro-L-arginine, a blocker of endothelium-derived relaxing factor, in the perfusate potentiated the rise in Ppa by 244%. Injection of 40 micrograms of rat atrial natriuretic factor at peak response to 20 micrograms of 8-epi-PGF2 alpha accelerated the return to baseline Ppa, resistance to airflow across the lung, and dynamic lung compliance values.(ABSTRACT TRUNCATED AT 250 WORDS)
Nitric oxide (NO) is a potent endogenous vasodilator. Its role in the normal and stressed pulmonary circulation is unclear. To better understand the importance of endogenous NO in normal physiological responses, we studied the effects of altered NO availability on the change in pulmonary vascular tone that accompanies exercise. In paired studies we measured blood flow and pressures in the pulmonary circulation at rest and during treadmill exercise at a speed of 4 mph with and without (a) NW-nitro-L-arginine, 20 mg/kg intravenously, a selective inhibitor of NO synthase; (b) L-arginine, 200 mg/kg intravenously, substrate for NO synthase; (c) combination of the inhibitor and substrate; and (d) inhalation of NO > 30 ppm, to determine if endogenous release of NO elicits maximal vasodilation. In addition, we sought to determine the site of NO effect in the pulmonary circulation by preconstriction with either U-44619 or hypoxia (fraction of inspired 02 = 0.12) using a distal wedged pulmonary catheter technique. NO synthase inhibition raised pulmonary vascular tone equally at rest and exercise. L-Arginine reversed the effects of NO synthase inhibition but had no independent effect. NO inhalation did not reduce pulmonary vascular tone at rest or enhance the usual reduction in pulmonary vascular resistance with exercise. The effect of NO synthase inhibition was in pulmonary vessels upstream from small veins, suggesting that endogenous NO dilates primarily small arteries and veins at rest. We conclude that, in sheep, endogenous NO has a basal vasodilator function that persists during, but is not enhanced by, exercise. (J. Clin. Invest. 1994Invest. . 94:2275Invest. -2282
During strenuous exercise in sheep, lung lymph flow increases within seconds and rises to levels 7- to 10-fold over baseline. Concomitant with the flow increase, the lymph protein content rapidly decreases to levels consistent with severe capillary hypertension. This pattern of clearance of filtered fluid is quite different than is seen with the passive capillary hypertension that results from mechanical obstruction of the mitral valve. In passive capillary hypertension, the increase in lymph flow and reduction in lymph protein content develop over several hours. The purpose of this study was to discover if these observed differences in edema clearance are related to the hyperpnea that accompanies exercise. Sheep were instrumented for continuous measurement of pulmonary arterial, left atrial, and systemic pressures, cardiac output by ultrasound, lung lymph flow, and ventilation. First, hemodynamics, ventilatory, and lymph clearance variables were measured during moderate exercise at 2.8 mph on a treadmill. Second, on a separate occasion, sheep were induced to hyperventilate to the same minute ventilation as during exercise, using modest CO2 stimulation. Lymph flow and hemodynamics were unaffected by this hyperpnea. The third arm of the experiment was to raise pulmonary microvascular pressure at rest to the level seen with exercise by means of a balloon catheter placed in the mitral valve. Lymph flow rose and protein content decreased slowly and to a lower degree than seen with exercise despite a comparable microvascular pressure. Finally, left atrial hypertension and induced hyperpnea were combined in sheep at rest, and the resulting lymph flow and protein content were the same as seen with exercise at similar pressures and ventilation. We conclude that hyperpnea is a major mechanism of interstitial liquid clearance during exercise, and may be largely responsible for preventing pulmonary edema that might occur at the high microvascular pressures of strenuous exercise.
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