6-ketoprostaglandin-f1-alpha and furegrelate

The effects of furegrelate (a thromboxane synthase inhibitor), indomethacin, and the combination on urine volume (V), para-aminohippurate clearance (CPAH), and mean arterial pressure (MAP) before and after intravenous furosemide were examined in Sprague-Dawley rats. Prior to furosemide, none of the treatments changed MAP, V, or CPAH. Furosemide increased urine volume from 16 +/- 7 to 148 +/- 25 microL.min-1. Concomitant administration of furegrelate or indomethacin did not affect furosemide-induced diuresis, but the combination of indomethacin, furegrelate, and furosemide caused increased diuresis (to 254 +/- 40 microliters.min-1, p < 0.05, compared with furosemide alone). Furosemide alone or with the other drugs had no effect on mean arterial pressure. CPAH was increased from 3.0 +/- 0.4 to 4.6 +/- 0.8 ml.min-1.100g-1 (p < 0.05, n = 6) by furosemide, and to an even greater extent (6.7 +/- 0.8, n = 6) after pretreatment with furegrelate. Pretreatment with indomethacin alone or in combination with furegrelate abolished the furosemide-induced CPAH increment. Urine excretion of the prostacyclin hydrolysis product 6-ketoprostaglandin F1 alpha was increased by furosemide in the presence of furegrelate. Given that the transient renal vasodilation with furosemide is due to prostanoid precursor release, these results are consistent with redirection of arachidonate metabolism toward vasodilator prostaglandins by furegrelate.

Topics: 6-Ketoprostaglandin F1 alpha; Animals; Benzofurans; Diuresis; Drug Interactions; Furosemide; Indomethacin; Kidney; Male; p-Aminohippuric Acid; Rats; Rats, Sprague-Dawley; Thromboxane-A Synthase; Vasodilation

We investigated if cyclooxygenase metabolites of arachidonic acid were involved in ischemia-reperfusion lung injury by determining if inhibition of their production attenuated the injury. Isolated rat lungs were perfused with physiologic salt solution osmotically stabilized with Ficoll until circulating blood elements were not detected in lung effluent. Ischemia was induced by stopping ventilation and perfusion for 90 min. Lung ventilation and perfusion were then resumed. Ischemia-reperfusion resulted in the production of prostacyclin and thromboxane assessed by lung effluent and tissue measurements of their respective stable metabolites, 6-keto-PGF1 alpha thromboxane B2 (TxB2). In contrast, prostaglandin F2 alpha did not increase. Ischemia-reperfusion also caused lung injury as assessed by increased lung 125I-BSA accumulation compared with nonischemic control lungs. Addition of the cyclooxygenase inhibitors, indomethacin, or flubiprofen to the lung perfusate before and after ischemia inhibited lung injury as well as the production of 6-keto-PGF1 alpha and TxB2. Addition of a thromboxane synthetase inhibitor (U 63557A) reduced lung injury as well as TxB2 formation without affecting the production of 6-keto-PGF1 alpha. The attenuation of lung injury was not explained by direct H2O2 removal by indomethacin, flubiprofen, or U 63557A because the concentrations of the inhibitors used in the isolated lung experiments did not remove exogenously added H2O2 from buffer in vitro. We conclude that cyclooxygenase metabolites of arachidonic acid are involved in ischemia-reperfusion injury to isolated rat lungs.

Topics: 6-Ketoprostaglandin F1 alpha; Animals; Benzofurans; Blood Pressure; Cyclooxygenase Inhibitors; Dinoprost; Flurbiprofen; Hydrogen Peroxide; Indomethacin; Lung; Male; Prostaglandin-Endoperoxide Synthases; Pulmonary Artery; Rats; Rats, Inbred Strains; Reperfusion Injury; Thromboxane B2; Thromboxane-A Synthase

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.

Topics: 6-Ketoprostaglandin F1 alpha; Animals; Benzofurans; Blood Pressure; Complement C3a; Cyclooxygenase Inhibitors; Imidazoles; In Vitro Techniques; Indomethacin; Lung; Male; Peptide Fragments; Perfusion; Pyridines; Rats; Thromboxane B2; Thromboxane-A Synthase; Vasoconstriction

Previous studies demonstrate endothelium-dependent leukotriene D4 (LTD4)-induced relaxation of canine coronary arterial rings in vitro. We now show that coronary occlusion followed by reperfusion attenuates (P less than 0.01) the relaxation of canine coronary artery rings in response to LTD4 as well as acetylcholine (ACh), suggesting loss of endothelium-dependent coronary reactivity (n = 6 dogs). Since superoxide anions have been shown to cause breakdown of endothelium-derived relaxing factor (EDRF), we wondered whether treatment of dogs with superoxide anion scavenger superoxide dismutase (SOD) would modulate the effects of LTD4 and ACh on reperfused coronary artery rings. Indeed, treatment of dogs (n = 5) with SOD before coronary reperfusion resulted in preservation of LTD4- and ACh-induced relaxation of coronary rings. Treatment of another five dogs with selective thromboxane-synthetase blocker U 63557A before coronary reperfusion also resulted in preservation of coronary ring relaxation in response to LTD4 and ACh. To determine the mechanism of U 63557A-induced preservation of coronary reactivity, canine neutrophil superoxide anion generation in the presence of U 63557A was measured. Although U 63557A had no effect on superoxide anion generation in neutrophils alone, it markedly (P less than 0.02) inhibited superoxide anion generation in neutrophils in the presence of platelets, most likely via shunting of accumulated cyclic endoperoxide in platelets toward formation of prostacyclin, which inhibits neutrophil superoxide anion production. Thus SOD and U 63557A protect against loss of endothelium-mediated vascular relaxation by LTD4 and ACh after coronary occlusion and reperfusion.

Topics: 6-Ketoprostaglandin F1 alpha; Acetylcholine; Animals; Benzofurans; Blood Platelets; Coronary Vessels; Dogs; Female; Male; Muscle, Smooth, Vascular; Myocardial Reperfusion; Neutrophils; Recombinant Proteins; Reference Values; SRS-A; Superoxide Dismutase; Superoxides; Thromboxane A2; Thromboxane-A Synthase; Vasodilation

One hundred NZB/W F1 female mice were studied to compare the effects of a thromboxane synthase inhibitor (TSI), a stable prostacyclin analog (iloprost) and prostaglandin E1 (PGE1) in the evolution of the nephritis. At 10 weeks of age mice were randomly assigned to cohorts of 20 to receive either no treatment, vehicle control, PGE1, iloprost or TSI. Proteinuria, mortality, systemic blood pressure, renal immune complex deposition, urinary TX B2 and 6 keto PGF1 alpha levels were measured. Mice receiving PGE1 and iloprost had a significant delay in the onset of proteinuria and reduction in mortality at 40 weeks. The TSI treatment had no apparent effect on proteinuria or mortality. The amelioration of the nephritis was not associated with an alteration in immune complex deposition in survivors at 40 weeks. Although PGE1 and iloprost lessened the age related increase in urinary TX B2, increased the urinary 6 keto PGF1 alpha levels and the ratio of 6 keto PGF1 alpha to TX B2; so did the TSI. The PGE1 treated mice did experience a marked and persistent reduction in blood pressure but this was not observed in the iloprost- or the TSI-treated mice. All drugs tested reduced the age-related increase in thromboxane B2 but only the PGE1 and iloprost had a significant effect on the evolution of the nephritis.

Topics: 6-Ketoprostaglandin F1 alpha; Age Factors; Alprostadil; Animals; Benzofurans; Blood Pressure; Disease Models, Animal; Epoprostenol; Female; Iloprost; Lupus Nephritis; Mice; Mice, Inbred NZB; Mice, Inbred Strains; Nephritis; Proteinuria; Thromboxane B2; Vasodilator Agents

This study examined the effect of selective thromboxane synthase inhibition and nonselective cyclooxygenase inhibition on vascular graft patency and indium 111-labeled platelet deposition in 35 mongrel dogs undergoing carotid artery replacement with 4 mm X 4 cm polytetrafluoroethylene (PTFE) (one side) and Dacron (opposite side) end-to-end grafts. Aspirin-dipyridamole therapy improved one-week graft patency, from 46% in untreated dogs to 93% in treated dogs. Thromboxane synthase inhibition (U-63557A) improved graft patency in these dogs to 81%. Both drug treatments reduced platelet deposition on Dacron and PTFE grafts by 48% to 68% compared with control dogs. Dacron grafts accumulated significantly more platelets than PTFE grafts but had comparable patency rates. Low-dose aspirin therapy had no significant effect on either graft patency or platelet deposition. All treatment groups showed a 60% to 76% reduction in serum thromboxane B2, but only thromboxane synthase inhibitor treatment increased plasma 6-keto-prostaglandin F1 alpha by 100%. Selective thromboxane synthase inhibition improved small-caliber prosthetic graft patency to the same extent as did conventional cyclooxygenase inhibition in this preliminary study.

Topics: 6-Ketoprostaglandin F1 alpha; Administration, Oral; Animals; Arteries; Aspirin; Benzofurans; Blood Platelets; Blood Vessel Prosthesis; Carotid Arteries; Dipyridamole; Dogs; Female; Indium; Polyethylene Terephthalates; Polytetrafluoroethylene; Radioisotopes; Random Allocation; Thromboxane B2; Thromboxane-A Synthase

Furosemide increases the synthesis of two major renal eicosanoids, prostacyclin (PGI2) and thromboxane A2 (TXA2), by stimulating the release of arachidonic acid which in turn is metabolized to PGG2/PGH2, then to PGI2 and TXA2. PGI2 may mediate, in part, the early increment in plasma renin activity (PRA) after furosemide. We hypothesized that thromboxane synthetase inhibition should direct prostaglandin endoperoxide metabolism toward PGI2, thereby enhancing the effects of furosemide on renin release. Furosemide (2.0 mg . kg-1 i.v.) was injected into Sprague-Dawley rats pretreated either with vehicle or with U-63,557A (a thromboxane synthetase inhibitor, 2 mg/kg-1 followed by 2 mg/kg-1 X hr-1). Urinary 6ketoPGF1 alpha and thromboxane B2 (TXB2), reflecting renal synthesis of PGI2 and TXA2, as well as PRA and serum TXB2, were measured. Serum TXB2 was reduced by 96% after U-63,557A. U-63,557A did not affect the basal PRA. Furosemide increased PRA in both vehicle and U63,557A treated rats. However, the PRA-increment at 10, 20 and 40 min following furosemide administration was greater in U-63,557A-treated rats than in vehicle-treated rats and urine 6ketoPGF1 alpha excretion rates were increased. These effects of thromboxane synthesis inhibition are consistent with a redirection of renal PG synthesis toward PGI2 and further suggest that such redirection can be physiologically relevant.

Topics: 6-Ketoprostaglandin F1 alpha; Animals; Benzofurans; Drug Interactions; Furosemide; Kidney; Male; Prostaglandins; Rats; Rats, Inbred Strains; Renin; Thromboxane B2; Thromboxane-A Synthase

Pregnancy-induced hypertension was induced in five ewes (gestational day 135; term 150 days) by 72 hours of food deprivation. Maternal arterial pressure, uterine blood flow, platelet function, renal function, and plasma levels of 6-ketoprostaglandin F1 alpha and thromboxane B2 were measured before and during hypertension and after three intravenous injections of U-63,557A; sodium 5-(3'-pyridinylmethyl) benzofuran-2-carboxylate, monohydrate (30 mg/kg every 8 hours). Blood pressure increased (p less than 0.03), and returned to normal after U-63,557A. Left uterine artery blood flow increased after U-63,557A (p less than 0.03). Creatinine clearance decreased during hypertension (p less than 0.03) and increased after U-63,557A. Urine protein increased during hypertension (p less than 0.03) and decreased after treatment. Platelet count dropped during hypertension (p less than 0.03) and was elevated after treatment. Collagen lag phase decreased during hypertension (p less than 0.03) and increased after treatment. After U-63,557A, 6-ketoprostaglandin F1 alpha levels were higher (p less than 0.04) than baseline or hypertensive values. Administration of a thromboxane synthetase inhibitor caused resolution of hemodynamic, renal, and coagulation dysfunctions that occurred in ovine pregnancy-induced hypertension.

Topics: 6-Ketoprostaglandin F1 alpha; Animals; Benzofurans; Blood Pressure; Female; Hypertension; Kidney Function Tests; Platelet Count; Pregnancy; Pregnancy Complications, Cardiovascular; Sheep; Thromboxane B2; Thromboxane-A Synthase; Uterus

Pretreatment with the thromboxane synthase inhibitor OKY-046 but not the cyclo-oxygenase inhibitor ibuprofen protects against ischemia-induced acute tubular necrosis. However, ibuprofen together with the vasodilating agent prostaglandin E1 is protective. This suggests that a high prostaglandin to thromboxane ratio is the major factor operative in preventing tubular necrosis, the subject of this study. Rats that had unilateral nephrectomy (n = 60) with the exception of rats that had sham operations (n = 8) underwent 45 minutes of left renal pedicle clamping. Thirty minutes before the operation, the rats received either a saline solution or a thromboxane synthase inhibitor that was given intravenously. The inhibitors OKY-046 (2 milligrams per kilogram, n = 10), UK38485 (1 milligram per kilogram, n = 9) and U63357A (10 milligrams per kilogram, n = 10) were given as a single bolus while the inhibitor CGS13080 (0.1 milligram per kilogram, n = 9, and 1.0 milligram per kilogram, n = 7) was given by constant infusion and continued for 60 minutes after reperfusion. With saline solution therapy, five minutes after reperfusion, thromboxane B2 increased from 154 to 2,537 picograms per milliliter (p less than 0.00001) and 6-keto-prostaglandin F1 alpha increased from 51 to 266 picograms per milliliter (p less than 0.004). At 24 hours, the creatinine level increased from 0.5 to 2.8 milligrams per deciliter (p less than 0.00001). Only OKY-046 yielded a creatinine level at 24 hours of 1.2 milligrams per deciliter, a value lower than that for those in the saline solution control group (p less than 0.002). Furthermore, OKY-046 led to the highest prostaglandin to thromboxane ratio (p less than 0.035). The five other ratios which occurred after drug therapy were inversely related to the decrease in the creatinine value (r = -0.93, p less than 0.02). Histologically, OKY-046 was the only thromboxane synthase inhibitor to prevent acute tubular necrosis (p less than 0.05). Results show that a high prostaglandin to thromboxane ratio protects against acute tubular necrosis.

Topics: 6-Ketoprostaglandin F1 alpha; Animals; Benzofurans; Creatinine; Evaluation Studies as Topic; Ibuprofen; Imidazoles; Ischemia; Kidney; Kidney Tubular Necrosis, Acute; Male; Methacrylates; Pyridines; Rats; Thromboxane B2; Thromboxane-A Synthase

Topics: 6-Ketoprostaglandin F1 alpha; Anti-Inflammatory Agents, Non-Steroidal; Benzofurans; Blood Vessel Prosthesis; Epoprostenol; Gas Chromatography-Mass Spectrometry; Humans; Myocardial Infarction; Thromboxane A2; Thromboxane B2