Physiological concentrations of ADP stimulate the release of prostacyclin from bovine aortic endothelial cells

ADP (0.2−200 μN) stimulated the synthesis of prostacyclin (PGI₂), as reflected by the release of 6-keto-prostaglandin F_1α (6-K-PGF_1α), in endothelial cells cultured from bovine orta. This effect of ADP was mimicked by ATP, whereas AMP and adenosine were completely inactive. The release of 6-K-PGF_1α triggered by ADP was rapid in onset (within 5 min), transient (10 min) and followed by a period of refractoriness to a new ADP challenge. Growing and confluent cells were equally responsive to ADP. ADP stimulated the release of free arachidonic acid from the endothelial cells. ADP could be thus exert two opposite actions on platelet aggregation in vivo: a direct stimulation and an inhibition mediated by PGI₂. This last action might contribute to limit thrombus formation to areas of endothelial cell damage.     

Metabolism of PGI2 by 15-hydroxyprostaglandin-dehydrogenase and Δ-reductase in different vascular beds of the cat in vivo

The metabolism of endogenous PGI₂ (released by angiotensin II or bradykinin) and exogenous PGI₂ by 15-hydroxy-PG-dehydrogenase and Δ¹³-reductase was studied in five different vascular beds of the anaesthetized cat. Plasma concentrations of 6-keto-PGF_1α (the product of spontaneous hydrolysis of PGI₂) and 6,15-diketo-13,14-dihydro-PGF_1α (the metabolite formed from PGI₂ by 15-hydroxy-PG-dehydrogenase and Δ¹³-reductase) were determined in the efferent vessels of the respective vascular beds by specific radioimmunoassays.No major metabolism of PGI₂ by 15-hydroxy-PG-dehydrogenase and Δ¹³-reductase was detected in the head and the hindlimbs of the cat. In the lung exogenous (circulating) PGI₂ was not metabolized, whereas PGI₂ synthetized in the lung itself was converted to 6,15-diketo-13,14-dihydor-PGF_1α. No significant amounts of 6,15-diketo-13,14-dihydro-PGF_1α-immunoreactivity were detected in hepatic venous blood after infusion of PGI₂ into the portal vein. However as also no 6-keto-PGF_1α was found, the liver seems to efficiently extract PGI₂ from the circulation. The cat kidney had the highest capacity of all vascular beds investigated to release endogenous and exogenous PGI₂ as 6-15-diketo-13,14-dihydro-PGF_1α. In other organs (vascular beds) investigated PGI₂ is either metabolized less efficiently by the 15-hydroxy-PG-dehydrogenase or further transformed to other metabolites.     

Cholinergic stimulation of vascular prostacyclin synthesis

The production of prostacyclin by rings of rabbit aorta was assessed by the radioimmunoassay of 6-K-PGF_1α. In steady-state conditions, the rings released 11 ng 6-K-PGF_1α per 100 mg tissue in 30 min. Acetylcholine increased this output: a significant effect was detected at 1 μM and at 10 μM the amplitude of stimulation was 10-fold. The production of PGE₂ and PGF_2α was also increased, but to a lesser extent. The stimulatory action of acetylcholine was mimicked by carbamylcholine and inhibited by atropine; it was abolished in a calcium-free medium. Dog and rat aorta also produced more 6-K-PGF_1α in response to cholinergic agonists. A short rubbing of the intimal surface of the aorta removed the layer of endothelial cells and completely abolished the cholinergic effect. It is concluded that in the aorta, cholinergic agonists, acting on a muscarinic receptor, stimulate the production of prostacyclin by endothelial cells.     

Metabolism of prostacyclin. III. Urinary metabolite profile of 6-keto PGF1α in rat

The in vivo metabolism of 6-keto PGF_1α was investigated in rats. Following continuous intravenous infusion for 14 days the urinary metabolites were isolated and identified. A substantial amount of unchanged 6-keto PGF_1α was recovered in the urine. The metabolic pattern very closely resembles that of PGI₂ in rats. Metabolites were found which represented 15-dehydrogenation, β-oxidation, ω and ω-1-hydroxylation and oxidation.Previous work showed that 6-keto PGF_1α is very poorly oxidized by 15-PGDH. We administered 15-[H³]-PGI₂ and 15-[H³]-6-keto PGF_1α to rats and measured urinary tritiated water as an index for in vivo 15-PGDH activity. The results showed that PGI₂ and 6-keto PGF_1α were both oxidized to the 15-keto product, although the rate of oxidation of PGI₂ was greater than that of 6-keto PGF_1α. We concluded that the administered PGI₂ was oxidized by 15-PGDH before hydrolysis to 6-keto PGF_1α. A portion of the dose is probably hydrolyzed before 15-dehydrogenation.     

Prostacyclin contributes to inhibition of hypoxic pulmonary vasoconstriction by alkalosis

The mechanism by which extracellular alkalosis inhibits hypoxic pulmonary vasoconstriction is unknown. We investigated whether the inhibition was due to intrapulmonary production of a vasodilator prostaglandin such as prostacyclin (PGI₂). Hypoxic vasoconstriction in isolated salt-solution-perfused rat lungs was blunted by both hypocapnic and NaHCO₃_induced alkalosis (perfusate pH increased from 7.3 to 7.7). The NaHCO₃-induced alkalosis was accompanied by a significant increase in the perfusate level of 6-keto-prostaglandin F_1α (6-keto-PGF_1α), an hydrolysis product of PGI₁. Meclofenamate, an inhibitor of cyclooxygenase, counteracted both the blunting of hypoxic vasoconstriction and the increased level of 6-keto-PGF_1α. In intact anesthetized dogs, hypocapnic alkalosis (blood pH increased from 7.4 to 7.5) blunted hypoxic pulmonary vasoconstriction before but not after administration of meclofenamate. In separate cultures of bovine pulmonary artery endothelial and smooth muscle cells stimulated by bradykinin, the incubation medium levels of 6-keto-PGF_1α were increased by both hypocapnia and NaHCO₃-induced alkalosis (medium pH increased from 7.4 to 7.7). These results suggest that inhibition of hypoxic pulmonary vasoconstriction by alkalosis is mediated at least partly by PGI_2.     

The effects of itnravenous ZK36-374, a stsable prostacyclin analogue, on normal volunteers

Prostacyclin (PGI₂) therapy has been evaluated in many vascular diseases. However, it is unstable and a potent vasodilator, able to lower blood pressure. Although such effects may be desirable in some situations, they are unwanted in others. ZK36-374 (Schering AG) is a carbacyclin derivatives with a similar action to PGI₂; however, it is chemically stable and has less of a hypotensive action.We evaluated the effects of a 4-hour I.V. infusion of ZK36-374 at a maximum dose of 2ng/Kg/min. in ten normal volunteers. Prior to the infusion and at 2 and 4 hours, blood was sampled for estimation of platelet aggregation in both platelet rich plasma and whole blood. β-thromboglobulin, 6-keto-PGF_1α and TXB₂ were measuerd by radioimmunoassay, as were other coagulation and rheological tests. The infusion was well tolerated with facial flushing, jaw trismus and some nausea at max dose. Blood pressure and pulse rate were not significantly altered. During infusion of ZK36-374, the rates of platelet aggregation to 2μm AdP and 2μg collagen in PRP were significantly decreased when compared to baseline, as was whole blood aggregation to 2μm ADP and 0.5 μg collagen. βTG also fell significantly, as did the levels of 6-keto-PGF_1α and TXB₂. Fibrinolysis, blood viscosity, and red cell deformability were unchanged.ZK36-374 is an effective anti-platelet agent without major toxic or hypotensive effects.     

Effect of PGI2, PGE2 and 6-keto PGF1α on canine gastric blood flow and acid secretion

Prostaglandins (PG)I₂, PGE₂ and 6-keto PGF₁α were infused directly into the gastric arterial supply at 10⁻⁹, 10⁻⁸ and 10⁻⁷ g/kg/min during an intra-gastric artery pentagastrin infusion in anesthetized dogs. 6-keto PGF₁α was also infused at 10⁻⁶ g/kg/min. Gastric arterial blood flow was measured continuously with a non-cannulating electromagnetic flow probe and gastric acid collected directly from the stomach. PGI₂ and PGE₂ produced similar dose-dependent increases in blood flow with an increase of more than four-fold at the highest dose. Both PGs inhibited acid output over this dose range with PGE₂ having 10 times the potency of PGI₂. 6-keto PGF₁α was at least 1000 times less active than PGI₂ or PGE₂ at increasing blood flow and failed to inhibit acid output even at 10⁻⁶ g/kg/min.     

Enhanced formation of PGI2, a potent hypotensive substance, by aortic rings and homogenates of the spontaneously hypertensive rat

Intact rings and homogenates of aorta from spontaneously hypertensive rats (SHR) contain enhanced capacity over normal rats (NR) to convert arachidonic acid into PGI₂. The PGI₂ synthetic system in SHR is stimulated to a greater extent than NR by norepinephrine. Indomethacin blocks this stimulation. PGE₂ and PGF_2α were detected in much smaller amounts in homogenates (undetected in rings) but their formation was not enhanced by the hypertensive tissue. The identity of PGI₂ was based on 1) direct pharmacological assay on the rat blood pressure. In this system identical vasodepressor responses to PGI₂ are observed after intracarotid and intrajugular administration 2) indirectly as 6-keto PGF_1α isolated after incubation of aortic homogenates with tritiated arachidonic acid and 3) indirectly by GC-MS assay of PGE₂, PGF_2α and 6-keto PGF_1α formed during incubation of aortic homogenates with excess unlabeled arachidonic acid. These results provide additional support to our recent hypothesis that PGI₂, of aortic origin, might actively participate in the regulation of systemic blood pressure. Its enhanced formation by intact hypertensive vascular tissue reflects an increase in the number of enzyme molecules immediately available to the substrate. This could probably be an adaptive response to the elevated levels of catecholamines in the circulation.     

The effects of prostacyclin (PGI2) on tissues which detect prostaglandins (PG'S)

The effects of prostacyclin (PGI₂) and its stable metabolite 6-oxo-PGF_1α on various bioassay tissues are compared with those of PGE₂ and PGF_2α, using the cascade superfusion method. On vascular smooth muscle, PGI₂ caused relaxation of all tissues tested except the rabbit aorta. PGE₂ relaxed rabbit coeliac and mesenteric artery but contracted bovine coronary artery and had no effect on rabbit aorta. 6-oxo-PGF_1α was ineffective at the concentrations tested.On gastro-intestinal smooth muscle, PGI₂ contracted strips of rat and hamster stomach and the chick rectum. It was less potent than PGE₂ or PGF_2α. None of these substances contracted that cat terminal ileum. 6-oxo-PGF_1α was inactive on these tissues at the doses tested.PGI₂ was less active than PGE₂ or PGF_2α in contracting guinea-pig trachea and rat uterus; 6-oxo-PGF_1α was active only on the rat uterus. Thus, PGI₂ can be distinguished from the other stable prostaglandins using the cascade method of superfusion.     

Comparison of umbilical vein models for measurement of relative prostacyclin and thromboxane production

There is growing evidence that blood vessels generate TXA₂ in addition to PGI₂. We examined effluents from continously perfused human umbilical vein and supernatants from umbilical vein rings for TXB₂ and 6-keto-PGF_1α measurements (stable metabolites of TXA₂ and PGI₂, respectively). TXB₂ and 6-keto-PGF_1α were identified in all samples. 6-keto-PGF_1α to TXB₂ ratio was higher in intact vein effluents than in the venous ring supernatants (112:1 and 28:1, respectively, P<0.01). Arachidonate stimulation increased 6-keto-PGF_1α and TXB₂ levels similarly in the intact vein effluent. In contrast, stimulation of the venous rings resulted in a relatively larger increase in TXB₂ than in 6-keto-PGF_1α. This caused 6-keto-PGF_1α to TXB₂ ratio to decline (p<0.01). The identity of TXB₂ was confirmed in several different ways. These data suggest that 1) human umbilical veins produce TXA₂ in addition to PGI₂, 2) TXA₂ release is more by venous rings than by the intact vein probably reflecting contribution from non-endothelial layers, and 3) arachidonate stimulation causes relatively greater release of TXA₂ than of PGI₂ from the venous rings, whereas release of PGI₂ and TXA₂ is similar from the intact vein.     

Prostacyclin induces a surprising long-lasting motility in quiescent uterine strips (indomethacin-treated) isolated from ovariectomized rats

Dose-response curves for several prostaglandins (PGI₂; PGD₂; PGF₂ and PGE₂); BaCl₂ or prostaglandin metabolites (15-keto-PGF_2α; 13, 14-diOH-15-keto-PGF_2α; 6-keto-PGF_1α and 6-keto-PGE₁ in quiescent (indomethacin-treated) uterine strips from ovariectomized rats, were constructed. All PGs tested as well as BaCl₂, triggered at different concentrations, evident phasic contractions. Within the range of concentrations tested the portion of the curves for the metabolites of PGF_2α was shifted to the right of that for PGF_2α itself; the curve for 6-keto-PGF_1α was displaced to the right of the curve for PGI₂ and that for 6-keto-PGE₁ to the left.It was also demonstrated that the uterine motility elicited by 10⁻⁵ M PGF_2α and its metabolites was long lasting (more than 3 hours) and so it was the activity evoked by PGI₂; 6-keto-PGF_1α and BaCl₂, but not the contractions following 6-keto-PGE₁, which disappeared much earlier. The contractile tension after PGF_2α; 15-keto-PGF_2α; 13, 14-diOH-15-keto-PGF_2α and PGI₂, increased as time progressed whilst that evoked by 6-keto-PGF_2α or BaCl₂ fluctuated during the same period around more constant levels.The surprising sustained and gradually increasing contractile activity after a single dose of an unstable prostaglandin such as PGI₂, on the isolated rat uterus rendered quiescent by indomethacin, is discussed in terms of an effect associated to its transformation into more stable metabolites (6-keto-PGF_1α, or another not tested) or as a consequence of a factor which might protects prostacyclin from inactivation.     

The use of stable prostaglandins to investigate prostacyclin (PGI2)-binding sites and PGI2-sensitive adenylate cyclase in human platelet membranes

Prostacyclin, (PGI₂) is a potent but unstable inhibitor of platelet aggregation, probably acting through stimulation of adenylate cyclase.A stable analogue of prostacyclin with antiaggregatory properties, 5,6-dihydro-PGI₂ (6β-PGI), and PGE₁ can compete for the binding sites labelled by ³H-PGI₂ in human platelet membranes (the affinity being PGI₂ > PGE₁ > 6β -PGI₁). Both 6β-PGI₁ and PGE₁, as well as PGI₂, bind to two classes of binding sites. 6β -PGI₁ and PGE₁ activate adenylate cyclase to the same extent as PGI₂,with a rank order of potency which parallels that observed in binding experiments. The stimulation of this enzyme is brought about by interaction of each these prostanoids with two different classes of components. The comparison of binding and adenylate cyclase data suggests that the sites to which PGI₂, 6β -PGI₁ and PGE₁ bind might be coupled to the activation of adenylate cyclase. Since 6β-PGI₁ seems to act through the same molecular mechanisms as PGI₂, because of its stability it is an useful tool to investigate the mode of action of prostacyclin in platelets.     

Role of prostacyclin on steroidogenesis by frog interrenal gland

The role of prostacyclin (PGI₂) on amphibian adrenal steroidogenesis was studied in perifused interrenal fragments from adult male frogs. Exogenous PGI₂ (3×10⁻⁸ M to 3×10⁻⁵ M) and, in a lesser extent, 6-keto-PGF_1α increased both corticosterone and aldosterone production in a dose-related manner. Short pulses (20 min) of 0.88 μM PGI₂ administered at 90 min intervals within the same experiment did not induce any desensitization phenomenon. A prolonged administration (6 h) of PGI₂ gave rise to an important increase in steroid production followed by a decline of corticosteroidogenesis. Indomethacin (IDM, 5 μM) induced a marked reduction of the spontaneous secretion of corticosteroid which confirmed the involvement of endogenous PGs in the process of corticosteroid biosynthesis. The IDM-induced blockade of corticosterone and aldosterone secretion was totally reversed by administration of exogenous PGI₂ in our model. Angiotensin II (AII) induced a massive release of 6-keto-PGF_1α, the stable metabolite of PGI₂. The increase of 6-keto-PGF_1α preceded the stimulation of corticosterone and aldosterone secretions. In contrast, the administration of ACTH did not modify the release of 6-keto-PGF_1α. These results indicate that PGI₂ might be an important mediator of adrenal steroidogenesis in frog. They confirm that the corticosteroidogenic actions of ACTH and AII are mediated by different mechanisms.     

A radioimmunoassay for 6-keto-prostaglandin F1α utilizing an antiserum against 6-methoxime-prostaglandin F1α: Application to study renal synthesis of prostacyclin

PGI₂ and 6-keto-PGF_1α were converted to 6-methoxime-PGF_1α (6-MeON-PGF_1α) by treatment with methoxyamine HCl in acetate buffer. The formed 6-MeON-PGF_1α was measured by radioimmunoassay. Antisera were raised in rabbits after immunization against 6-MeON-PGF_1α-BSA conjugate. Diluted 1:20.000 to bind 50% of the tracer (³H-6-MeON-PGF_1α, 100 Ci/mmol), the antiserum cross reacted 0.8% with PGE₂, 1% with PGF_2α and less than 0.2% with PGD₂, PGF_1α, PGF_2β and TXB₂. The radioimmunoassay was used to estimate release of PGI₂ and 6-keto-PGF_1α from chopped rabbit renal medulla and cortex incubated in Krebs-Ringer bicarbonate buffer (37°C, 30 min). The 6-keto-PGf_1α radioimmunoassay was validated in biological samples by mass fragmentography. The chopped medulla (n=5) released 38±9 ng/g/min and the cortex (n=5) 4.7±2.0 ng/g/min, while the release of immunoreactive PGE₂ (iPGE₂) and iPGF_2α was 171±26 and 74±13 ng/g/min from the medulla and 4.3±1.3 and 2.7±0.3 ng/g/min from the cortex, respectively. The results confirm previous findings, which indicate that in the renal medulla prostaglandin endoperoxides are mainly transformed to prostaglandins, while in the cortex transformation to PGI₂ seems to be of greater importance.     

The renal haemodynamic and excretory actions of prostacyclin and 6-oxo-PGF1α in anaesthetized dogs

Intrarenal arterial (i.a.) infusions of prostacyclin (PGI₂) at 30–300 ng/min to anaesthetized dogs reduced renal vascular resistance (RVR) and filtration fraction (FF), increased mean renal blood flow (MRBF) but did not alter mean arterial pressure (MAP) or glomerular filtration rate (GFR). The urinary excretion of sodium (U_NaV), potassium (U_KV) and chloride ions (U_ClV) were increased through inhibition of net tubular ion reabsorption. PGI₂ (3000 ng/min, i.a.) reduced MAP and increased heart rate. Intravenous (i.v.) infusions of PGI₂ (3000 ng/min) reduced MAP, GFR, FF, urine volume and ion excretion, with elevation of heart rate. The measured variables were unaltered by 6-oxo-PGF_1α (10,000 ng/min i.a.). Treatment of the dogs witht he PG synthetase inhibitor meclofenamic acid (2.5 mg/kg i.v.), did not antagonise the elevation of MRBF to PGI₂ (300 ng/min i.a.). Thus the renal effects of PGI₂ were due to a direct action rather than through conversion to 6-oxo-PGF_1α or through stimulation of endogenous renal PG biosynthesis and release.     

Prostacyclin as neuromodulator in the sympathetically stimulated rabbit heart

Prostaglandin E₂ (PGE₂) has previously been shown to inhibit sympathetic neurotransmission in different organs and species. Based on this inhibitory effect and on its reversal by cyclo-oxygenase inhibitors, PGE₂ has been claimed to be a physiological modulator of in vivo release of norepinephrine (NE) from sympathetic nerves. It is now recognized that prostacyclin (PGI₂) is the main cyclo-oxygenase product in the heart. We therefore addressed the question whether PGI₂, within the same preparation, is formed in increased amounts during sympathetic nerve stimulation and has neuromodulatory activity.The effluent from isolated rabbit hearts subjected to sympathetic nerve stimulation or to infusion of NE or adenosine (ADO) was collected, and its content of PGE₂ and 6-keto-PGF_1α (dehydration product of PGI₂) was analyzed using gas chromatography/mass spectrometry, operated in the negative ion/chemical ionization mode. Other hearts were infused with PGI₂ and nerve stimulation induced outflow of endogenous NE into the effluent was analyzed using HPLC with electrochemical detection. Nerve stimulation at 5 or 10 Hz (before but not after adrenergic receptor blockade), as well as infusion of NE (10⁻⁶–10⁻⁵M) or ADO (10⁻⁴M) increased the cardiac outflow of 6-keto-PGF_1α. Basal and nerve stimulation induced efflux of 6-keto-PGF_1α was approximately 5 times higher than the corresponding efflux of PGE₂. PGI₂ dose-dependently inhibited the outflow of NE from sympathetically stimulated hearts, the inhibition at 10⁻⁶M being approximately 40%.On the basis of these observations we propose that PGI₂ is a more likely candidate than PGE₂ as a potential modulator of neurotransmission in cardiac tissue in vivo.     

Chemical stability of prostacyclin (PGI2) in aqueous solutions

The rate constant for the hydrolysis of prostacyclin (PGI₂) to 6-keto-PGF_1α was measured by monitoring the UV spectral change, over a pH range 6 to 10 at 25°C and the total ionic strength of 0.5 M. The first-order rate constant (k_obs) extrapolated to zero buffer concentration follows an expression, k_obs = k_H+ (H+), where k_H+ is a second-order rate constant for the specific acid catalyzed hydrolysis. The value of k_H+ obtained (3.71 × 10⁴ sec⁻¹ M⁻¹) is estimated approximately 700-fold greater than a k_H+ value expected from the hydrolysis of other vinyl ethers. Such an unusually high reactivity of PGI₂ even for a vinyl ether is attributed to a possible ring strain release that would occur upon the rate controlling protonation of C₅. A Brønsted slope (α) of 0.71 was obtained for the acid (including H₃O+) catalytic constants, from which a pH independent first-order rate constant for the spontaneous hydrolysis (catalyzed by H₂O as a general acid) was estimated to be 1.3 × 10⁻⁶ sec⁻¹. An apparent activation energy (E_a) of 11.85 Kcal/mole was obtained for the hydrolysis at pH 7.48, from which a half-life of PGI₂ at 4°C was estimated to be approximately 14.5 min. when the total phosphate concentration is 0.165 M (cf. 3.5 min. at 25°C).     

PGI2 production by rat blood vessels: Diminished prostacyclin formation in veins compared to arteries

Homogenates of eleven different blood vessels from normal Sprague-Dawley rats varied in their ability to produce PGI₂ (i.e., 6-keto-PGF_1α) from [1−¹⁴C]PGH₂. The most notable difference was seen between arteries and veins. Arterial tissues produced more 6-keto-PGF_1α from exogenous PGH₂ than veins at all enzyme (i.e., protein) concentrations tested. Similar results were obtained utilizing different homogenization techniques or arterial and venous rings, indicating this difference was real and not due to homogenization artifacts. In addition, the thoracic segment of the inferior vena cava was more active in converting added [1−¹⁴C]PGH₂ to 6-keto-PGF_1α than the abdominal segment of added inferior vena cava suggestive of a possible segmental distribution of the enzyme activity in blood vessels. These results may be interpreted as indicating that PGI₂ may have a vasomotor function for blood vessels in addition to its proposed antithrombotic role.     

Prostanoid synthesis by human umbilical artery

A discrepancy between published values of PGI₂ production by human umbilical artery measured by platelet bioassay, compared with values of 6-oxo-PGF_1α by radioimmunoassay, raised the possibility that another anti-aggregatory prostanoid was produced by this tissue. To test this hypothesis, umbilical artery rings were incubated in buffer and PGI₂ determined by platelet bioassay and by a more specific radioimmunoassay based on comparison of 6-oxo-PGF_1α in hydrolysed and non-hydrolysed samples. 6-oxo-PGF_1a, PGF_2α and TXB₂ were also measured by gas chromatography negative ion chemical ionisation mass spectrometry. PGI₂ concentrations by radioimmunoassay and bioassay were significantly correlated (r = 0.92, p < 0.01). There was no difference between them, disproving the presence of an additional antiaggregatory substance. PGI₂ production determined by bioassay (mean 1.21 ng/mg wet weight/h, range 0.59–1.53 ng/mg/h) differed from previously reported values (range 70–325 ng/mg/h). 6-oxo-PGF_1α concentrations were confirmed by gas chromatography negative ion chemical ionisation mass spectrometry. Previous determinations of PGI₂ production by this tissue overestimated it by approximately 100 times.     

Assay of prostacyclin synthesis in intact aorta by aqueous sampling

Conversion of 1-¹⁴C-arachidonic acid (AA) to 6-keto-PGF_1α, the stable metabolite of prostacyclin (PGI₂) was assayed kinetically by employing an aqueous sampling technique. In this way, one can arrive at a kinetic view of PGI₂ synthesis from AA in intact tissue. The assay appears to be particularly suitable to tissues such as the aorta where PGI₂ constitutes the major metabolite of AA. The assay avoids the need for organic solvent extraction and relies on the essential absence of tissue binding of 6-keto-PGF_1α. The disappearance of AA can also be followed in this system but quantitation is complicated by avid tissue binding of the fatty acid. The assay, as described should be applicable to other vascular tissues and should greatly simplify kinetic analyses of prostacyclin synthesis.