Inhibition of ovulation in the gonadotropin-primed immature rat by exogenous prostaglandin E2

In the past two decades there have been innumerable reports that prostaglandins (PGs) are essential for mammalian ovulation. However, we have recently found that a relatively low dose of 0.03 mg indomethacin (INDO) sc to PMSG/hCG-primed immature Wistar rats can significantly reduce ovarian PG levels without inhibiting the control ovulation rate of 60+ ova/rat (1–3). In view of this information, the present study was an effort to duplicate the earlier reports that PGs can reverse the “inhibitory” effect of INDO on ovulation. In control animals, which received PMSG and hCG only, the ovulation rate was 63.8 ± 4.5 ova/rat. This rate was reduced to 4.1 ± 1.1 ova/rat when the animals were injected with 1.0 mg INDO at 3 h after hCG. In no instance was this inhibition reversed when the animals were treated with 1.0 mg of PGE₂ or PGF_2α, or a combination of both prostanoids in either a single dose at 3 h after hCG, or in 4× doses at 2-h intervals beginning at 3 h after hCG. Furthermore, in animals that did not receive INDO, the ovulation rate in PGE₂-treated animals was reduced to 20.0 ± 6.7 ova/rat, and in animals treated with PGE₂ and PGF_2α (combined) it was reduced to 19.4 ± 6.5 ova/rat. In summary, not only did the PGs fail to reverse the anti-ovulatory effect of INDO, PGE₂ actually suppressed the ovulation rate.     

Effectiveness of prostaglandin F2α in restoration of HMG-HCG induced ovulation in indomethacin-treated rhesus monkeys

Six mature female rhesus monkeys were treated with HMG-HCG in control cycles at doses adjusted to induce ovulation while avoiding superovulation. Occurrence of ovulation was determined by observation of fresh ovulation points at laparotomy 48 to 120 hours following HCG. In subsequent cycles animals were treated with indomethacin (treatment days 4 through 10) together with the established dose of HMG_HCG. In 8 cycles indomethacin 5 mg/kg was given i.m. once daily; in 9 cycles 10 mg/kg i.m. was administered in 2 divided doses. Following this, PGF_2^α (3 mg t.i.d. s.c.) was administered for 3 days together with indomethacin 10 mg/kg and HMG-HCG, beginning on the day prior to HCG. Determinations of progesterone were performed by RIA on treatment days 4, 7, 10, and 11. Eleven of the 13 control cycles were ovulatory. With indomethacin 5 mg/kg/day, 5 of 8 cycles were ovulatory but ovulation was delayed in 2 instances. Of 9 cycles using indomethacin 10 mg/kg/day only 1 was ovulatory. When PGF_2^α was administered in subsequent cycles along with indomethacin (10 mg/kg) and HMG-HCG, ovulation occurred in 13 of 19 cycles. These data suggest that local ovarian PGF_2^α may be essential in the mechanics of follicle rupture in gonadotropin-treated rhesus monkeys.     

Ovulation rate and serum LH levels in rats treated with indomethacin or prostaglandin E2

Serum LH levels were determined by radioimmunoassay at the normal time of the proestrous LH peak (17.30 – 18.00) and ovulatory performance was examined on the morning of estrus in rats treated with indomethacin, an inhibitor of prostaglandin synthesis. When the drug was administered at 14.30 on the day of proestrus, only 21% of the rats ovulated and the total number of ova shed was reduced to 4% of that found in the untreated control group, but there was no significant change in peak serum LH level (1122 ± 184 vs. 975 ± 240 ng/ml ± S.E., treated vs. control). Prostaglandin E₂ (PGE₂) given late on the day of proestrus (25 to 750 μ g/rat at 24.00) was effective in overcoming this antiovulatory action of indomethacin: 71–90% of the rats ovulated, though the number of eggs shed was low (24–55% of control value). Indomethacin was still effective in blocking ovulation when given at 20.00, that is after completion of the proestrous LH surge, but not at 24.00. Administration of PGE₂ (2 × 750 μ g/rat) in the early afternoon of proestrus elicited a rise in serum LH levels in rats in which the cyclic LH surge had been blocked with Nembutal (470 ± 87 vs. 106 ± 17 ng/ml ± S.E.) and induced ovulation in two-thirds of these animals.The results confirm, by direct measurement, that indomethacin does not block LH release but interferes with a late phase of the ovulatory process. PGE₂ reverses this action of indomethacin on the ovary. In addition, PGE₂ has a central effect causing LH release.     

Influence of the position of the side chain hydroxy group on the gastric antisecretory and antiulcer actions of E1 prostaglandin analogs

The influence of transposing the C-15 hydroxy group of prostaglandin E₁ methyl ester (PGE₁ME) on gastric antisecretory and antiulcer actions was investigated. The compound (±)15-deoxy- 16α,β-hydroxy PGE₁ME (SC-28904) was equipotent to the reference standard PGE₁ME in suppressing histamine-stimulated gastric secretion in the Heidenhain pouch (HP) dog. In contrast to PGE₁ME, SC-28904 was longer acting when administered intravenously and also showed significant oral activity in the histamine-stimulated gastric fistula dog. SC-28904 was also equipotent to PGE₁ME (range of active doses of 0.5 to 5.0 mg/kg, s.c.) in inhibiting forced-exertion gastric ulceration in rats.The compound (±)15-deoxy-17α,β-hydroxy PGE₁ME (SC-30693) was an inactive antisecretory agent in the dog at the 1.0 mg/kg i.v. bolus dose. This dose was 100 times greater than the active antisecretory dose of PGE₁ME. Likewise, SC-30693, when administered subcutaneously at a 5.0 mg/kg dose, was also totally inactive in preventing gastric ulcers induced by forced exertion in rats.The important implications of this work are that some of the receptor sites for the PGE₁ molecule could easily accommodate the side chain hydroxy group either in the C-15 or C-16 position. Moreover, the hydroxy group in the latter position significantly improved the biological activity of PGE₁ME.     

Effectiveness of prostagland in F2α in restoration of HMG-HCG induced ovulation in indomethacin-treated rhesus monkeys

Six mature female rhesus monkeys were treated with HMG-HCG in control cycles at doses adjusted to induce ovulation while avoiding superovulation. Occurrence of ovulation was determined by observation of fresh ovulation points at laparotomy 48 to 120 hours following HCG. In subsequent cycles animals were treated with indomethacin (treatment days 4 through 10) together with the established dose of HMG-HCG. In 8 cycles indomethacin 5 mg/kg was given i.m. once daily; in 9 cycles 10 mg/kg i.m. was administered in 2 divided doses. Following this, PGF₂α (3 mg t.i.d. s.c.) was administered for 3 days together with indomethacin 10 mg/kg and HMG-HCG, beginning on the day prior to HCG. Determinations of progesterone were performed by RIA on treatment days 4, 7, 10, and 11. Eleven of the 13 control cycles were ovulatory. With indomethacin 5 mg/kg/day, 5 of 8 cycles were ovulatory but ovulation was delayed in 2 instances. Of 9 cycles using indomethacin 10 mg/kg/day only 1 was ovulatory. When PGF₂α was administered in subsequent cycles along with indomethacin (10 mg/kg) and HMG-HCG, ovulation occurred in 13 of 19 cycles. These data suggest that local ovarian PGF₂α may be essential in the mechanics of follicle rupture in gonadotropin-treated rhesus monkeys.     

The effect of intravenously administered prostaglandin E2 on rat uterine 3′, 5′-adenosine monophosphate

PGE₂ administered intravenously increased levels of cyclic AMP in uterine tissue of rats ovariectomized 12 days before treatment. This action of PGE₂ on uterine tissue was dose-dependent, with a dose response curve from 50 to 600 μ/Kg and the maximum effect was seen 10 minutes after PGE₂ administration. Delay of prostaglandin treatment until 25 days post-ovariectomy prevented this response. Administration of estradiol benzoate to such animals however, allowed the rat uterus to respond with elevated cyclic AMP levels at 3 minutes but not at 10 or 45 minutes after PGE₂ treatment.     

Inhibition of ovulation in the gonadotropin-primed immature rat by exogenous prostaglandin E2.

In the past two decades there have been innumerable reports that prostaglandins (PGs) are essential for mammalian ovulation. However, we have recently found that a relatively low dose of 0.03 mg indomethacin (INDO) sc to PMSG/hCG-primed immature Wistar rats can significantly reduce ovarian PG levels without inhibiting the control ovulation rate of 60+ ova/rat (1-3). In view of this information, the present study was an effort to duplicate the earlier reports that PGs can reverse the "inhibitory" effect of INDO on ovulation. In control animals, which received PMSG and hCG only, the ovulation rate was 63.8 +/- 4.5 ova/rat. This rate was reduced to 4.1 +/- 1.1 ova/rat when the animals were injected with 1.0 mg INDO at 3 h after hCG. In no instance was this inhibition reversed when the animals were treated with 1.0 mg of PGE2 or PGF2 alpha, or a combination of both prostanoids in either a single dose at 3 h after hCG, or in 4x doses at 2-h intervals beginning at 3 h after hCG. Furthermore, in animals that did not receive INDO, the ovulation rate in PGE2-treated animals was reduced to 20.0 +/- 6.7 ova/rat, and in animals treated with PGE2 and PGF2 alpha (combined) it was reduced to 19.4 +/- 6.5 ova/rat. In summary, not only did the PGs fail to reverse the anti-ovulatory effect of INDO, PGE2 actually suppressed the ovulation rate.     

Gastric antisecretory actions of (15S)-15-methyl prostaglandin E2 methyl ester and natural prostaglandin E2 in rhesus monkeys

The gastric antisecretory actions of (15S)-15-methyl prostaglandin E₂ methyl ester (Me-PGE₂) and Prostaglandin E₂ (PGE₂) were evaluated in the unanesthetized gastric fistula rhesus monkey. Secretion was submaximally stimulated by multiple subcutaneous injections of histamine acid phosphate given every hour for four consecutive hours. When a steady-state plateau of gastric secretion was reached, the PG's were administered as a single bolus dose either intravenously (i.v.) or intragastrically (i.g.). Both PG's inhibited histamine-stimulated gastric secretion. The PG's showed greater sensitivity in inhibiting acid concentration while not affecting volume output. Active i.v. and i.g. antisecretory doses of Me-PGE₂ ranged from 3 to 10 μg/kg, while PGE₂ showed significant antisecretory activity at i.v. bolus doses of 30–100 μg/kg and i.g. bolus dose of 1.0 mg/kg. Thus, Me-PGE₂ is estimated to be at least 10 and 300 times more potent than PGE₂ by the i.v. and i.g. administration routes, respectively. These findings indicate that the rhesus monkey shows some similarities to man in responsiveness to gastric secretory inhibition by E-prostaglandins.     

Effectiveness of prostaglandin f 2 alpha in restoration of HMG-HCG induced ovulation in indomethacin-treated rhesus monkeys.

Six mature female rhesus monkeys were treated with HMG-HCG in control cycles at doses adjusted to induce ovulation while avoiding superovulation. Occurrence of ovulation was determined by observation of fresh ovulation points at laparotomy 48 to 120 hours following HCG. In subsequent cycles animals were treated with indomethacin (treatment days 4 through 10) together with the established dose of HMG-HCG. In 8 cycles indomethacin 5 mg/kg was given i.m. once daily; in 9 cycles 10 mg/kg i.m. was administered in 2 divided doses. Following this, PGF2alpha (3 mg t.i.d. s.c.) was administered for 3 days together with indomethacin 10 mg/kg and HMG-HCG, beginning on the day prior to HCG. Determinations of progesterone were performed by RIA on treatment days 4, 7, 10, and 11. Eleven of the 13 control cycles were ovulatory. With indomethacin 5 mg/kg/day, 5 of 8 cycles were ovulatory but ovulation was delayed in 2 instances. Of 9 cycles using indomethacin 10 mg/kg/day only 1 was ovulatory. When PGF2alpha was administered in susequent cycles along with indomethacin (10 mg/kg) and HMG-HCG, ovulation occurred in 13 of 19 cycles. These data suggest that local ovarian PGF2alpha may be essential in the mechanics of follicle rupture in gonadotropin-treated rhesus monkeys.     

Effect of indomethacin, tiaprofenic acid and dicrofenac on rat gastric mucosal damage and content of prostacyclin and prostaglandin E2

Gastric ulcerogenicity and depletion of endogenous prostaglandins (PGs) content induced by tiaprofenic acid, dicrofenac and indomethacin were examined using the same antiinflammatory effective doses. Male Wistar rats were given each of these drugs intragasrically 24, 18, and 3 hrs before sacrifice in the following doses (mg/kg): indomethacin (0.8, 4 and 20); tiaprofenic acid (1.2, 6 and 30); dicrofenac (0.8, 4 and 20). Endogenous prostacyclin (PGI₂) and PGE₂ in fundic mucosa were determined by radioimmunoassay. The three compounds produced fundic mucosal lesions in a dose-dependent manner. However, tiaprofenic acid and dicrofenac were both less potent than indomethacin in producing gastric mucosal lesions at similar antiinflammatory doses. Mucosal PGE₂ content was abolished by the three compounds in the following doses (mg/kg): indomethacin (4 and 20); tiaprofenic acid (6 and 30); dicrofenac (20). Mucosal PGI₂ was maintained around 50% of the control value in rats given tiaprofenic acid in a dose of 6 mg/kg or dicrofenac in a dose of 4 mg/kg, while indomethacin in a dose of 4 mg/kg markedly reduced mucosal PGI₂ to 17% of the control value. In larger doses, tiaprofenic acid and dicrofenac were also significantly less potent in reducing mucosal PGI₂ than idomethacin. These results suggest that the difference in ulcerogenicity between idomethacin and the other two compounds was closely related to their potency in decreasing PGI₂ in the gastric (fundic) mucosa.     

Effect of prostaglandin F2α on ovulation and fertilization in rabbit

The effect of prostaglandin F_2α on ovulation and fertilization was studied in rabbits. The number of ovulation was not affected by subcutaneous injection of PGF_2α but the recovery of ova was significantly decreased when PGF_2α was given either at 12 or 16 h after HCG injection and autopsied 24 h latter. The results suggest that exogenous PGF_2α accelerates ovum transport and expels the eggs prematurely from the female tract and does not impair ovulation or the fertilization processes when given to rabbit at 1 mg/kg B.W.     

Effect of mifepristone and antiestrogens on uterine PGF2α and PGE2 concentrations in ovariectomized and pregnant rats

Four antiestrogens (anordiol, tamoxifen, RU 39411, ICI 182780) and the antiprogestin, mifepristone (RU 486), were administered to the following three animal models: (1) ovariectomized rats, (2) mated rats treated post-coitally; and (3) pregnant rats treated post-implantation. The antiestrogens were administered alone or in combination with mifepristone at doses effective in preventing and/or terminating pregnancy in rats. The objective of the study was to determine whether these drugs influenced uterine concentrations of prostaglandins (PGF_2α and PGE₂).Antiestrogens administered alone to ovariectomized rats did not effect uterine PGE₂ or PGF_2α concentrations; whereas the combination of anordiol/mifepristone increased uterine PGF_2α concentration, resulting in an increase in the PGF_2α/PGE₂ ratio.Mated rats were treated post-coitally for three consecutive days with anordiol, tamoxifen, estradiol and mifepristone alone and with the combination of anordiol/mifepristone and tamoxifen/mifepristone. An increase in uterine PGF_2α concentrations and in the PGF_2α/PGE₂ ratio occurred only in anordiol/mifepristone treated group. A decrease in uterine PGE₂ concentrations occurred in animals treated with anordiol, tamoxifen and estradiol, resulting in an increase in the PGF_2α/PGE₂ ratio.Anordiol (5.0 mg/kg/day) and mifepristone (4.0 mg/kg/day) alone and the combination of anordiol/mifepristone (2.5/1.0 mg/kg/day) administered to pregnant rats on days 7, 8 and 9 of pregnancy induced an increase in PGF_2α levels without affecting uterine PGE₂ concentration. The changes in uterine PGF_2α concentrations induced by anordiol and the combination of anordiol/mifepristone resulted in an increase in the PGF_2α/PGE₂ ratio.The antiestrogens tested except for ICI 182780 possessed agonist activity when assayed by measuring their capacity to increase the uterine weights in ovariectomized rats. Also, ICI 182789 was the only antiestrogen that did not influence uterine PG concentrations. It can be concluded that ICI 182780 is the only “pure” antiestrogen among those tested.The present results show that antiestrogens and the combination of mifepristone plus anordiol at doses preventing implantation and terminating pregnancy increase uterine PGF_2α and/or decrease PGE₂ concentrations, resulting in an alteration of PGF_2α/PGE₂ ratio. These findings suggest that there exists a critical balance of PGF_2α to PGE₂ concentrations in the uterus required for the normal passage of fertilized ova through the oviduct, initiating implantation of the blastocysts, development of embryos, and maintenance of pregnancy.     

Effects of intracerebroventricular administration of PGE1, E2 and F2α on electrically induced convulsions in mice

Intracerebroventricular administration of prostaglandins E₁ or E₂ was shown to block, while PGF_2α increased the incidence of tonic convulsion due to electroshock in mice. The Prostaglandins were administered intracerebroventricularly (i.c.v.) to conscious mice by a modification of Haley and McCormick's method (1) prior to a transcorneal maximal electroshock (MES) or a transcorneal supra-maximal electroshock (SMES). PGE₁ and PGE₂ i.c.v. blocked the tonic hindlimb extension (THE) and protected the animals from death induced by MES with ED₅₀'s for PGE₁ and PGE₂ for inhibition of the THE of 6.6 (4.3–12.0) μg/mouse i.c.v. and 13.3 (8.9–22.4) μg/mouse i.c.v. respectively. When PGE₂ was administered intraperitoneally (i.p.) in doses as high as 4.0 mg/kg it did not block the THE. However, the duration of the THE as well as the mortality were reduced by doses of 0.5–4.0 mg/kg PGE₂ i.p.. Both PGE₁ and PGE₂ were shown to cause a dose related significant (p<.001) decrease in the duration of the THE with SMES in doses of 1–10 μg/mouse i.c.v. for PGE₁ and 2–40 μg/mouse i.c.v. for PGE₂. PGF_2α, administered i.c.v. prior to a transcorneal electroshock equivalent to a current at the ED₁ level, increased the incidence of the THE as well as the mortality in doses of 20–50 μg/mouse.     

Chronobiological Studies on the Hypotensive Effect of Prostaglandin E2 and Arachidonic Acid in the Rat

The present study was designed to determine whether biological rhythm variations could be detected in the hypotensive action of prostaglandin E₂ (PGE₂) and arachidonic acid (AA) in normal rats. Doses of 1.0 μg kg^?1 of PGE₂ or 0.5 mg kg^?1 of AA were administered to pentobarbital-anesthetized rats at 6 times of the day. Maximal reduction of systolic and diastolic blood pressures was obtained when PGE₂ or AA were administered to rats between 0930 and 1200. The lowest falls in blood pressure were found when the same doses of the two substances were injected between 0300 and 0500. Mechanisms to explain these circadian variations are suggested.     

Comparative behavioral effects of dibutyryl cyclic AMP and prostaglandin E1 in mice

Three behavioral tests, spontaneous locomotor activity (SLMA), exploratory behavior (EB) and rotarod performance (RP), a measure of neuromuscular coordination, were used to study the interaction of PGE₁ (1 mg/kg i.p., 10 min. pretreatment) with DBcAMP (25 mg/kg i.p., 25 min. pretreatment) in mice. A dose-response relationship of PGE₁ (0.01–5.0 mg/kg) to SLMA was determined, with a significant decrease in SLMA produced by a dose of 0.1 mg/kg. Decreases in SLMA were produced by PGE₁ (79%), DBcAMP (41%) and DBcAMP-PGE₁ combination (71%). Similar decreases in EB were observed. Although no significant difference between controls and DBcAMP was observed in RP, 52% of mice tested were RP failures following PGE₁ and a 100% failure rate was induced by the combination. Mice were treated with a second injection of DBcAMP or PGE₁ or the combination 24 hr following the first injection. Behavioral activity of these mice was observed 25 min (DBcAMP) or 10 min (PGE₁) after the second dose was administered. A second injection of DBcAMP failed to decrease SLMA and EB from controls; moreover, SLMA began to return towards control levels as early as 2 hr between injections. The second injection of PGE₁ or DBcAMP+PGE₁ produced the same behavior as that produced by the first injection. On the basis of these results, the relationship of cyclic nucleotides and PGs to behavioral activity is discussed.     

Changes in morphine self-administration in rats induced by prostaglandin E1 and naloxone

Interactions of prostaglandin E₁ (PGE₁) with morphine have been reported in several test systems and an hypothesis has been advanced for a role of prostaglandins in morphine analgesia and physical dependence. In rats self-administering morphine intravenously, a simultaneous and continuous infusion of naloxone hydrochloride at 56 to 560 μg/kg/day caused the expected increase in injection rate for morphine. Infusion of PGE₁ by itself at 56 or 180 μg/kg/day had no effect on the rate of morphine intake. Likewise the addition of PGE₁ at 180 μg/kg/day did not potentiate the increase caused by naloxone (56 or 180 μg/kg/day) when it was added to the naloxone infusion. These results do not support a role for prostaglandins in the behavioral aspects of morphine addiction. However, larger doses of PGE₁ (1 and 1.8 mg/kg/day), which were without overt effects in normal rats, caused severe and incapacitating prostration in morphinized rats.     

Marked inhibition of gastric secretion by two prostaglandin analogs given orally to man

Two prostaglandin analogs, 15(S)-15-methyl PGE₂, methyl ester, and 16, 16-dimethyl PGE₂ were administered to human volunteers for their possible effect in inhibiting gastric secretion. Both analogs, given orally, inhibited gastric secretion stimulated by pentagastrin, and the effect was dose dependent. The inhibition lasted for more than 4 hours, and no side-effects were noted at the doses used. When given intraduodenally, through a thin tube swallowed the night before, 15($\text{S}$)-15-methyl PGE₂, methyl ester was more active than 16, 16-dimethyl PGE₂. In view of their oral and prolonged activity, these analogs may have clinical potential in the treatment of peptic ulcer.     

Effect of super-ovulatory doses of pregnant mare serum gonadotropin and human chorionic gonadotropin in blastocyst implantation in golden hamsters

The effect of super-ovulatory dose of pregnant mare serum gonadotropin and human chorionic gonadotropin on ovulation, advancement of ovulation, subsequent embryo development and implantation were studied in the hamster. Groups of hamsters received pregnant mare serum gonadotropin injection on day 1 of the estrous cycle followed by human chorionic gonadotropin injection either at 56 or 76 h later, pregnant mare serum gonadotropin alone on day 1 or human chorionic gonadotropin alone on day 3.The combination therapy (pregnant mare serum gonadotropin and human chorionic gonadotropin) resulted in super-ovulation (an average of 40 mature ova/animal) while human chorionic gonadotropin alone yielded an average of 10 mature ova/animal. Ovulation was advanced by 24 h by giving human chorionic gonadotropin at 56 h instead of 76 h after pregnant mare serum gonadotropin. Subsequent embryo development and implantation occurring under different hormonal regimens were studied. The ova obtained by giving human chorionic gonadotropin injection at 56 h were poorly fertilizablein vivo and hence the pregnancy rate was low (6 %). These ova however, were fertilizablein vitro, suggesting that the low fertilization rate and developmental failure may be due to inhibition of sperm capacitation/transport because of premature human chorionic gonadotropin administration. In the group receiving human chorionic gonadotropin alone on day 3 there was fertilization and cleavage, but no implantation occurred due to failure of functional corpora lutea. However, administration of progesterone and estrone from day 2 of gestation resulted in 80% implantation and sustenance of pregnancy. On the other hand, the pregnant mare serum gonadotropin and human chorionic gonadotropin combination therapy resulted in super-pregnancy. The number of fetuses present at term was higher in the group receiving pregnant mare serum gonadotropin alone than in the group receiving the combination therapy. Embryo resorption however was higher (37%) in the latter group compared with the former (9.5%). However, preimplantation embryos were found to be viable as evidenced by fluorescein diacetate staining.     

Effects of prostaglandin E2, 16,16-dimethyl prostaglandin E2 and a prostaglandin endoperoxide analogue (U-46619) on gastric secretory volume, [H] and mucus synthesis and secretion in the rat

The effects of orally administered prostaglandin E₂, 16,16-dimethyl prostaglandin E₂ and U-46619, an analogue of the prostaglandin endoperoxide PGH₂, on gastric secretory volume, acid and mucus were studied in the rat. All of the compounds significantly increased the volume of gastric secretion, mucus secretion, measured as N-acetylneuraminic acid and mucus synthesis measured as the incorporation of [³H]-glucosamine into mucosal glycoprotein; however, only PGE₂ and 16,16-dimethyl PGE₂ inhibited acid secretion. U-46619, 1.5 mg/kg provided significant protection against ethanol-induced gastric ulcers, an effect that has been previously shown for the other two compounds. These studies provide additional evidence that prostaglandin induced mucosal protection may by related to an effect on mucus and on stimulation of nonparietal cell gastric secretion. Further study of these parameters may be important in the development of antiulcer drugs for long term clinical use.     

The possible mode of action of prostaglandins: VII - evidence of an antifertility effect of prostaglandin E1 in rats

Prostaglandin E₁ (PGE₁) of 5 mg/kg body weight was found to be ineffective to induce luteolysis in 100% of the test animals when injected either, on day 3, day 5 or day 7 of pregnancy. While, conversely the same dose schedule was absolutely potent in the induction of luteolysis and resorption of fetuses, placentae when tested on day 10 or day 13 of pregnancy. Progesterone alongwith PGE₁ consistently prevented the abortifacient efficacy of PGE₁. Moreover, it was observed that PGE₁ could also successfully terminate pseudopregnant state in the bilaterally hysterectomized rats between fortyeight and ninetysix hours after the injection. It was suggested that the luteolytic or abortifacient efficacy of PGE₁ is not the exclusive reflection of an augmented activity of uterine musculature.