Effects of prostaglandin E1 and indomethacin on fetal and neonatal lamb mesenteric artery responses to norepinephrine

The effects of prostaglandin E₁ (PGE₁) and indomethacin on isolated fetal and neonatal lamb mesenteric artery responses to norepinephrine were investigated. PGE₁ (1.5μM) significantly reduced vasoconstriction responses to 0.5 to 5μM norepinephrine. Indomethacin (1μM) markedly potentiated the constrictor effects of 0.5 to 10μM norepinephrine. PGE₁ prevented the potentiating effect of indomethacin. Neither PGE₁ nor indomethacin altered basal muscle tension. These results suggest that endogenous PGs modify adrenergic responses in the isolated mesenteric arteries of preterm and newborn lambs.     

Prostaglandins do not modulate the positive chronotropic and inotropic effects of sympathetic nerve stimulation and injected norepinephrine in the isolated blood perfused canine atrium

In isolated canine atrium, perfused with blood from a donor dog, the infusions of both prostaglandins (PG)I₂ and E₂ (0.1–1 μg/min) into the sinus node arterial cannula neither altered the sinus rate and developed tension nor the positive chronotropic and inotropic responses elicited by either electrical stimulation or by injected norepinephrine. Infusion of arachidonic acid (10–100 μg/min), a precursor of PGs, or indomethacin (15–20 μg/min), an inhibitor of PG synthesis, into the sinus node arterial cannula also failed to alter the increase in sinus rate or developed tension produced by either adrenergic stimulus in the isolated atria. When arachidonic acid, 100–300 μg/kg or PGI₂, 1 μg/kg, were injected into the jugular vein of the donor dog, they produced a fall in systemic blood pressure; this effect of arachidonic acid but not of PGI₂ was abolished by indomethacin, 1 mg/kg. During administration of either arachidonic acid or indomethacin to the donor dog, the positive chronotripic and inotropic responses to adrenergic stimuli in the isolated atria also remained unaltered. These data indicate that PGs do not modulate adrenergic transmission in the blood perfused canine atrium.     

Effects of prostaglandins E2, I2 and F2α, arachidonic acid and indomethacin on pressor responses to norepinephrine in conscious rats

The effects of prostaglandins E₂ (PGE₂), I₂ (PGI₂) and F₂α (PGF₂α), arachidonic acid and indomethacin on pressor responses to norepinephrine were examined in conscious rats. Intravenously infused PGE₂ (0.3, 1.25 μg/kg/min), PGI₂ (50, 100 ng/kg/min), PGF₂α (1.8, 5.4 μg/kg/min) and arachidonic acid (0.7, 1.4 mg/kg/min) did not change the basal blood pressure. Both PGE₂ and PGI₂ significantly attenuated pressor responses to norepinephrine, whereas PGF₂α significantly potentiated them. Arachidonic acid, a precursor of the prostaglandins (PGs), significantly attenuated pressor responses to norepinephrine. Since the attenuating effect of arachidonic acid was completely abolished by the pretreatment with indomethacin (5 mg/kg), arachidonic acid is thought to exert an effect through its conversion to PGs. On the contrary, intravenously injected indomethacin (0.2–5.0 mg/kg) facilitated pressor responses to norepinephrine in a dose-related manner without any direct effect on the basal blood pressure. These results suggest that endogenous PGs may participate in the regulation of blood pressure by modulating pressor responses to norepinephrine in conscious rats.     

Effects of prostaglandin E1 and indomethacin on fetal and neonatal lamb mesenteric artery responses to norepinephrine.

The effects of prostaglandin E1 (PGE1) and indomethacin on isolated fetal and neonatal lamb mesenteric artery responses to norepinephrine were investigated. PGE1 (1.5 micrometer) significantly reduced vasoconstriction responses to 0.5 to 5 micrometer norepinephrine. Indomethacin (1 micrometer) markedly potentiated the constrictor effects of 0.5 to 10 micrometer norepinephrine. PGE1 prevented the potentiating effect of indomethacin. Neither PGE1 nor indomethacin altered basal muscle tension. These results suggest that endogenous PGs modify adrenergic responses in the isolated mesenteric arteries of preterm and newborn lambs.     

Differential effects of prazosin and rauwolsin on the release of prostaglandins I2 and E2 from the perfused mesenteric arterial bed of the rabbit following nerve stimulation

Sympathetic nerve stimulation of the perfused mesenteric arterial bed of the rabbit, , increase the secretion of prostaglandin (PG)I₂ and PGE₂. Prazosin (4.8 × 10⁻⁶), and α₁ adrenergic receptor antagonist, inhibited this inrease in release of PGI₂ but not of PGE₂ whereas rauwolsin (10⁻⁷ M), an α₂ adrenergic receptor antagonist, inhibited the increase in release of PGE₂ but not of PGI₂. Prazosin (10⁻⁶ M) completely blocked the vasoconstrictor response to nerve stimulation, and to norepinephrine and phenylephrine administration, suggesting there to be little of an α₂ adrenergic receptor component in this response. It is concluded that the increase in PGI₂ release follows the activation of α₁ adrenergic receptors and is therefore post-junctional in origin, whereas the increase in PGE₂ release follows the activation of α₂ adrenergic receptors and may be pre- and/or post-junctional in origin.Indomethacin (2.8 × 10⁻⁷, 5.6 × 10⁻⁷ and 1.12 × 10^{−6 M} did not affect the vasoconstrictor responses to nerve stimulation at 10 Hz, whereas rauwolsin (10⁻⁷ M) in the presence of indomethacin substantially increased them. These results indicate that PGE₂ does not regulate norepinephrine release following nerve stimulation at 10 Hz to rabbit mesenteric arteries, and that the inhibition of norepinephrine release following stimulation of α₂ pre-junctional receptors is independent of PG involvement.     

Release of prostaglandins I2 and E2 from the perfused mesenteric arterial bed of normotensive and hypertensive rats. Effects of sympathetic nerve stimulation and norepinephrine administration

The spontaneous output of prostaglandin (PG) I₂ from the perfused mesenteric arterial bed in vitro was significantly higher in hypertensive rats than in normotensive rats. Sympathetic nerve stimulation (at 10Hz) of the mesenteric arterial bed from normotensive rats caused a rapid and short-lived (< 4 min) two-fold increase in PGI₂ output and a smaller increase in PGE₂ output. Sympathetic nerve stimulation (at 10Hz) of the mesenteric arterial bed from hypertensive rats failed to increase PGI₂ and PGE₂ output. It is not possible to conclude whether this lack of response is a cause or a result of hypertension. Surprisingly, norepinephrine administration stimulated PGI₂ and PGE₂ release from the mesenteric arterial bed of both normotensive and hypertensive rats. Obviously, differences exist in the responsiveness of rat mesenteric arteries to endogenous and exogenous norepinephrine concerning PG release between the normotensive and hypertensive states.     

A proposed role for prostaglandins in the modulation of the relaxation response to urotensin I in isolated rat arteries

Urotensin I (UI) elicits dose-dependent relaxation responses in isolated helical strips of rat tail and mesenteric arteries contracted by 10⁻⁵M norepinephrine (NE). The rat mesenteric artery demonstrated a 40 fold lower threshold sensitivity to UI (0.25 mU/M1 versus maximal relaxation at 0.25 mU/m1). Complete relaxation of the rat tail artery with UI could not be achieved, even at doses exceeding 10 mU/m1. Pretreatment of the arterial strips with cyclooxygenase inhibitors had no effect on the contractile response to NE in the tail artery, but reduced NE responsiveness in the mesenteric artery. Significant enhancement of UI relaxation responses in both types of arterial strips was achieved by pre-treatment with the cyclooxygenase inhibiters, suggesting a modulatory role for prostaglandins (PGs) in the expression of the UI relaxation response in NE contracted arterial strips. The major enzymatically formed PG (as assessed by [1-¹⁴C] PGH₂ metabolism in broken cell preparations) in both the rat tail and mesenteric arteries was 6-keto PGF_1α, the stable hydrolysis product of PGI₂. Using a specific RIA to quantify 6-keto PGF_1α release, it was found that UI elicited nearly a two-fold increase in the release of this PG compared to the NE control in both rat tail and mesenteric arteries. These data suggest that PGI₂ may modulate the relaxation response to UI either by direct physiological opposition (PGI₂ elicited contractile response in NE contracted tail and mesenteric arteries at doses exceeding 10−8M) and/or by some as yet undefined mechanism (eg. effects on Ca²⁺, cAMP).     

Modulation of prostaglandin of the renal vascular action of arginne vasopressin

To determine whether the renal vascular effect of arginine vasopressin (AVP) is modulated by renal prostaglandin E₂ (PGE₂) were determined during the infusion of AVP in dogs during control conditions and after the administration of the inhibitor of prostaglandin synthesis, indomethacin. During control conditions, intrarenal administration for 10 min of a dose of AVP calculated to increase arterial renal plasma AVP concentration by 75 pg/ml produced a slight renal vasodilation (p<0.01) and an increase in renal venous plasma concentration of PGE₂. Renal venous PGE₂ concentration during control and AVP infusion averaged 33 ± 7 and 52 ± 12 pg/ml (p<0.05), respectively. After administration of indomethacin, the same dose of AVP induced renal vasoconstriction (p<0.05) and failed to enhance renal venous PGE₂ concentration (9 ± 1 to 8 ± 1 pg/ml). Intrarenal administration of 20 ng/kg. min of AVP for 10 min induced a marked renal vasoconstriction (p<0.01) and increased renal venous plasma PGE₂. Renal venous PGE₂ during control and AVP infusion averaged 31 ± 10 and 121 ± 31 pg/ml (p<0.01), respectively. Administration of the same dose of AVP following indomethacin produced a significantly greater and longer lasting renal vasoconstriction (p<0.01) and failed to increase renal venous plasma PGE₂ (10 ± 1 to 9 ± 1 pg/ml). These results indicate that a concentration of AVP comparable to that observed in several pathophysiological conditions induces a slight renal vasodilation which is mediated by renal prostaglandins. The results also indicate that higher doses of AVP induce renal vasoconstriction and that prostaglandin synthesis induced by AVP attenautes the renal vasoconstriction produced by this peptide.     

Central cardiovascular and thermal effects of prostacyclin in rats

Prostacyclin (PGI₂) induced a dose-dependent decrease in blood pressure with slight increases in heart rate and body temperature, when administered at the doses of 0.1–100 μg into the lateral cerebral ventricle (i.c.v.) of the urethane-anaesthetised rat. When the same doses were administered intravenously, both the blood pressure and heart rate decreased. Central pretreatment with sodium meclofenamate (1 mg/rat i.c.v.) antagonised the central hypotensive effect of PGI₂ but i.c.v. pretreatment of the rats with indomethacin (1 mg/rat) failed to affect the PGO₂-induced hypotension. Central pretreatment with two histamine H₂-receptor antagonists, cimetidine (500 μg/rat i.c.v.) or metiamide (488 μg/rat i.c.v.), antagonised the blood pressure lowering effect of 0.1 μg dose of PGI₂ but failed to affect the hypotension induced by higher PGI₂ doses. Therefore the main central hypotensive effect of PGI₂ seems not to be associated with the stimulation of histamine H₂ -receptors in the brain.The hypotensive effect of i.c.v. administered PGI₂ appears to be due to an action upon the central nervous system rather than to a leakage into the peripheral circulation. This assumption is supported by the fact that sodium meclofenamate i.c.v. antagonished the effect of PGI₂. In addition, the chronotropic response to i.c.v. PGI₂ was opposite to that induced by intravenous administration. The results also suggest that there may be differences in the mode of action between sodium meclofenamate and indomethacin.     

The effect of prostaglandin I2 on the contractility of the term pregnant human myometrium

Small myometrial strips were dissected from the upper and lower segments of the term pregnant human uterus. The specimens were superfused in organ chambers and contractile activity was recorded isometrically.In strips from the upper segment, prostacyclin (PGI₂), induced an initial excitatory response followed in the majority of experiments by transient inhibition. In the lower segment the response was generally the same although direct inhibition without initial stimulation occurred in some cases.During the period of inhibition the specimens were refractory to iterated exposure to PGI₂. Furthermore, during this period of PGI₂-induced inhibition the muscle strip was also refractory to PGE₂ but responded to PGF_2α and oxytocin by stimulation.After inhibition of spontaneous contractile activity induced by indomethacin PGI₂ induced an excitatory response.The results do not indicate any critical change in the myometrial responsiveness of the upper uterine segment to PGI₂ during labor. In strips from the lower segment obtained before labor there tended to be a dominance of non-responders and inhibition only as compared to the results during labor. Nevertheless, whether or not PGI₂ under physiological or pharmacological conditions has any significant influence on the contractility of the term pregnant human uterus, still remains obscure.As judged from earlier reports from our laboratory and the present study it is evident that the uterine vessels are considerably more sensitive to the action of PGI₂ than the myometrium.     

Reversal of indomethacin-induced inhibition of tubuloglomerular feedback by prostaglandin infusion

Experiments were performed in rats to study the effect of infusion of PGI₂, PGE₂, and PGF_2α on tubuloglomerular feedback responses (i.e. the change of SNGFR in response to a change of loop of Henle flow rate) in the presence and absence of simultaneous inhibition of endogenous PG synthesis with indomethacin. Infusion of PGI₂ or PGE₂ at rates that did not alter arterial blood pressure did not significantly modify the magnitude of feedback responses (PGI₂) 8.5 μg/hr, PGE₂ 85 μg/hr). Some inhibition of feedback responses was seen when PGI₂ and PGE₂ were administered at higher rates were associated with a reduction of blood pressure (PGI₂ 20 μg/hr, PGE₂ 200 μg/hr). PGI₂ (8.5 μg/hr) and PGE₂ (85 μg/hr) largely prevented feedback inhibition induced by indomethacin. When given subsequent to indomethacin PGI₂ and PGE₂ restored feedback responsiveness almost to normal. In contrast, PGF_2α did not influence feedback inhibition caused by indomethacin. Infusion of PGI₂ induced partial restoration of feedback responses in DOCA-salt treated animals in which the feedback system is virtually completely inactive. Our results indicate that availability of PGI₂ or PGE₂ is necessary for the normal operation of the tubuloglomerular feedback mechanism for control of nephron filtration rate.     

Actions of prostacyclin (PGI2) on adrenergic neuroeffector transmission in the rabbit kidney

In the Tyrode's perfused rabbit kidney PGI₂ (1.3 × 10⁻⁸-3.3 × 10^−7M) dose-dependently inhibited vasoconstrictor responses to sympathetic nerve stimulation, as did PGE₂. The dose-effect curve of the two compounds differed, making PGI₂ the less potent in the low concentration and the more potent in the high. PGI₂ also inhibited the vasoconstrictor response to exogenous noradrenaline, but it had no effect on transmitter release. The main metabolite of PGI₂, 6-keto-PGF_1α, was ineffective both on noradrenaline release and on vascular responses to nerve stimulation or exogenous noradrenaline. It is suggested that PGI₂,if a significant renal prostaglandin, may modulate renal neuroeffector transmission post-junctionally, thereby forming a complement to the prejunctional action of PGE₂.     

Inhibition of vasoconstrictor responses by 6-keto-PGE1 in the feline mesenteric vascular bed

The effects of 6-keto-PGE₁ on vascular resistance and vascular responses to sympathetic nerve stimulation and vasoconstrictor hormones were investigated in the feline mesenteric vascular bed. Infusions of 6-keto-PGE₁ into the superior mesenteric artery dilated the mesenteric vascular bed and markedly inhibited vasoconstrictor responses to sympathetic nerve stimulation, norepinephrine and angiotensin II. The effects of 6-keto-PGE₁ and PGE₁ on vascular resistance and vasoconstrictor responses were quite similar and both substances inhibited responses to nerve stimulation and pressor hormones in a reversible manner. Responses to nerve stimulation, norepinephrine and angiotensin II were inhibited to a similar extent during infusion of 6-keto-PGE₁ and PGE₁. Results of these studies suggest that 6-keto-PGE₁, a newly identified prostaglandin metabolite, and PGE₁ possess the ability to inhibit the vasconstrictor effects of sympathetic nerve stimulation and pressor hormones by a nonspecific action on vascular smooth muscle in the feline small intestine.     

Prostacyclin and thromboxane formation in human umbilical arteries following stimulation with vasoactive autacoids

The formation of prostacyclin (PGI₂) and thromboxane A₂ (TXA₂) (measured as the stable metabolites 6-keto-PGF_1α and TXB₂) during stimulation with vasoactive autocoids was registered in human umbilical arteries perfused . Responses were registered within 3–4 minutes after addition of the subtances. Both angiostensin I and II were found to increase the formation of PGI₂ while depressing that of TXA₂. Serotonin increased the formation of TXA₂ but not that of PGI₂. Both PGE₂ and PGF_2α stimulated the PGI₂ formation. The TXA₂ mimetic U46619, increased PGI₂ production, whereas PGI₂ slighlty increased the formation of TXA₂. All responses were found to be completely inhibited by indomethacin.     

Differential effects of acute thermal injury on rat splanchnic and renal blood flow and prostanoid release

This study examines the hypothesis that acute thermal injury decreases renal and splanchnic blood flow which correlates with altered endogenous vasodilator eicosanoid release. Anesthetized male Wistar rats were subjected to sham or a non-resuscitated 30% total body surface area burn. At 1, 2, 4, 8, and 24 h post-burn mean arterial pressure as well as superior mesenteric and renal artery in vivo blood flow were measured. The superior mesenteric and renal arteries were cannulated and perfused in vitro with their end organs with Krebs buffer (pH 7.4, 37°C). Renal and splanchnic 6-keto-PGF_1α (PGI₂), PGE₂, and thromboxane B₂ (TXB₂) release were measured by EIA at 15 min of perfusion. Renal and superior mesenteric artery blood flow decreased by 40% or more at 1 and 2 h post-burn despite mean arterial pressure remaining unchanged. The major eicosanoids released were PGI₂ from the splanchnic bed and PGI₂ and PGE₂ from the kidney. Splanchnic PGI₂ and TXB₂ release and renal TXB₂ increased 2–3 fold at 1 h post-burn but returned to the sham level at 2 h post-burn. By 24 h post-burn the vasodilator eicosanoids were increased in both the splanchnic and renal vascular beds. These data show that decreased renal and splanchnic blood flow was associated with increased endogenous release of the potent vasoconstrictor TXB₂. By 2 h post-burn, renal and splanchnic blood flow began returning toward the sham level as endogenous release of TXB₂ from both organs fell to sham levels. These data suggest that increased endogenous release of TXB₂ may contribute to the short-term decrease in renal and splanchnic blood flow in the immediate post-burn period and thus may contribute to ischemia of both vascular beds.     

Contribution of lipoxygenase and cyclooxygenase metabolites in the modulation of cyclic nucleotides in the guinea pig mymotrium. Differential effects of carbachol and ionophore A23187

Accumulation of cyclic GMP in estradiol-treated immature guinea pig myometrium was enhanced by carbachol, ionophore A₂₃₁₈₆, unsaturated fatty acids and their hydroperoxides. Cyclic AMP content was elevated only by arachiodonic acid, A₂₃₁₈₇ and PGI₂. Eicosatetraynoic acid (TYA), but not indomethacin prevented all cyclic GMP responses. The effects of A₂₃₁₈₇ and arachidonate on cyclic AMP were accompanied by a parallel increase (2–3 fold) on the generation of PGI₂ by the myometrium. Both events were similarly reduced by indomethacin, TYA, 15-hydroperoxyarachidonic acid and tranylcypromine, suggesting that PGI₂ was involved. Omission of Ca²⁺ or addition of mepacrine of p-bromophenacylbromide abolished the stimulatory effects of A₂₃₁₈₇ and carbachol on cyclic GMP as well as the A₂₃₁₈₇-induced elevations in both PGI₂ and cyclic AMP generation. Thus, with both exogenous arachidonate as well as with endogenous fatty acid, released through an apparent phospholipase A₂-induced activation process, the lipoxygenase pathway was associated with an activation of the cyclic GMP system and the cyclooxygenase pathway, via PGI₂ generation, with an activation of the cyclic AMP system. Carbachol failed to alter both cyclic AMP content and the release of PGI₂ suggesting a cholinergic receptor-mediated fatty acid release process, selectively coupled to the lipoxygenase route.     

Evidence against prostaglandin modulation of cardioaccelerator nerve activity in the anesthetized dog

The hypothesis that prostaglandins have a modulatory role in adrenergic neurotransmitter release was tested in the anesthetized dog. Inhibition of prostaglandin synthesis with indomethacin (10 mg/kg, i.v.) did not alter positive chronotropic responses to cardioaccelerator nerve stimulation or blood pressure responses to exogenous norepinephrine. In the presence of indomethacin, infusions of PGE₂ (0.01 and 0.1 μg kg⁻¹ min⁻¹) also failed to influence the responses to cardioaccelerator nerve stimulation although the blood pressure responses to exogenous norepinephrine were reduced in a dose-related manner. It was concluded that endogenous prostaglandins and exogenous PGE₂, the purported physiological inhibitor of neurotransmitter release in cardiac tissue, do not play a role in modulating chronotropic responses during cardioaccelerator nerve stimulation in the anesthetized dog.     

Effect of angiotensin II and norepinephrine on release of prostaglandins E2 and I2 by the perfused rat mesenteric artery

Prostaglandin E₂ (PGE₂) and 6 keto-PGF_1α, the stable metabolite of prostacyclin (PGI₂), have been measured in the effluent of perfused rat mesenteric arteries by the use of a sensitive and specific radioimmunoadday (RIA) method. The PGE₂ and 6-keto-PGF_1α were continuousyl released by the unstimulated mesenteric artery over a period of 145 min. After 100 min of perfusion the release of PGE₂ and 6-keto-PGF_1α was 4.5 ± 8.4 pg/min and 254 ± 75 pg.min respectively, which is in accord with the general belief that PGI₂ is the major PG synthesized by arterial tissue. Angiotensin II (AII) 5 ng/ml) induced an increased of PGE₂ and 6-keto-PGF_1α release without changing the perfusion pressure. The effect of norepinephrine (NE) injections on release of PGs depended on the duration of the stabilization period. The changes of perfusion pressure induced by NE were not related to changes in release of PGs. Thus, it seems that the increase of PG release induced by AII and NE was due to a direct effect of the drugs on the vascular wall. This may represent an important modulating mechanism in the regulation of vascular tone.     

Circulatory and platelet actions of 6,9-thiaprostacyclin (PGI2-S) in the cat.

A new analog of prostacyclin, 6,9-Thiaprostacyclin was infused intravenously in pentobarbital anesthetized cats in order to determine its hemodynamic and anti-platelet aggregating properties. At an infusion rate of 0.01 μmoles/kg/min, PGI₂-S moderately decreased arterial blood pressure without altering heart rate of superior mesenteric artery flow or platelet aggregation responses to ADP. However, at 0.05 μmoles/kg/min, PGI₂-S significantly reduced arterial blood pressure and significantly increased heart rate, and superior mesenteric artery flow. Moreover, at 0.05 μmoles/kg/min, PGI₂-S inhibited ADP platelet aggregation by 80%. PGI₂-S may be a useful agent in circulatory shock.     

Effect of PGD2, PGE2, PGF2α and PGI2 on blood pressure,heart rate and plasma catecholamine responses to spinal cord stimulation in the rat

The following experiments were designed in order to examine the inter-relationships of various prostaglandins (PG's) and the adrenergic nervous system, in conjunction with blood pressure and heart rate responses, $\text{in vivo}$. Stimulation of the entire spinal cord (50v, 0.3–3 Hz, 1.0 msec) of the pithed rat increased blood pressure, heart rate and plasma epinephrine (EPI) and norepinephrine (NE) concentration (radioenzymatic-thin layer chromatographic assay). Infusion of PGE₂(10–30 μg/kg. min, i.v.) suppressed blood pressure and heart rate responses to spinal cord stimulation while plasma EPI (but not NE) was augmented over levels found in control animals. PGI₂ (0.03–3.0 μg/kg. min, i.v.) suppressed the blood pressure response to spinal cord stimulation without any effect on heart rate or the plasma catecholamine levels. PGE₂ and PGF_2α(10–30 μg/kg. min, i.v.) did not change the blood pressure, heart rate or plasma EPI and NE responses to the spinal cord stimulation although PGF_2α disclosed an overall vasopressor effect during the pre-stimulation period. At the pre-stimulation period it was also observed that PGE₂, PGF_2α and PGI₂, had a positive chronotropic effect on the heart rate, the cardiac accelerating effect of PGE₂ was not abolished by propanolol. These $\text{in vivo}$ studies suggest that in the rat, PGE₂ and PGI₂ modulate sympathetic responses, primarily by interaction with the post-synaptic elements — PGE₂ on both blood vessels and the heart and PGI₂ by acting principally on blood vessels.