Prostaglandin F-2 alpha is transferred from the uterus to the ovary in the sheep by lymphatic and blood vascular pathways

[3H]Prostaglandin F-2 alpha (PGF-2 alpha) was infused into a uterine lymphatic vessel or a uterine vein for up to 1 h, or injected into the uterine lumen of anaesthetized non-pregnant sheep 7-15 days after oestrus. After an intraluminal injection, labelled PGF-2 alpha was recovered in uterine lymph and peak radioactivity was reached 50 min after injection. [3H]PGF-2 alpha infused at a constant rate into a uterine lymphatic vessel resulted in a maximum concentration of radioactivity in plasma which was 5.6- and 1.7-fold higher in the adjacent utero-ovarian and ovarian vein, respectively, than in carotid arterial plasma. Estimation of the amount of infusate transferred from a lymphatic into ovarian venous blood gave a value (0.4%) similar to that for transfer from a uterine vein (0.3%). Evidence for local transfer was substantiated by the presence of significantly higher concentrations of 3H-labelled compounds in the ovary and corpus luteum adjacent to the site of intra-lymphatic infusion compared with those in the opposite organs. The concentrations in the adjacent ovary and corpus luteum were significantly greater when an intra-lymphatic rather than intra-uterine vein infusion was adopted. The results show that [3H]PGF-2 alpha is transferred locally from uterine lymphatic vessels into the adjacent ovary, corpus luteum and ovarian vein.     

Urogenital vasculature and local steroid concentrations in the uterine branch of the ovarian vein of the female tammar wallaby (Macropus eugenii)

The urogenital vasculature of the tammar comprises 4 major paired arteries and veins: the ovarian, the cranial urogenital, the caudal urogenital and the internal pudendal artery and vein. The ovarian artery and vein and their uterine branches which supply the ovary, oviduct and uterus, ramify extensively. Each anterior urogenital artery and vein supplies the caudal regions of the ipsilateral uterus, lateral and median vagina and cranial parts of the urogenital sinus. The caudal urogenital arteries and veins supply the urogenital sinus and caudal regions of the bladder. The internal pudendal artery and vein vascularize the cloacal region, with some anastomoses with branches of the external pudendal vessels. Anastomoses connect the uterine branch of the ovarian artery with the uterine branch of the cranial urogenital and cranial branches of the caudal urogenital arteries, and connect the caudal urogenital and the internal pudendal arteries. Anastomotic connections between the left and right arterial supply also occur across the midline of the cervical regions of the uteri and the anterior lateral vaginae. Similar connections are seen in the venous system. The uterine branch of the ovarian artery ramifies extensively very close to the ovary, giving a plexiform arrangement with the ovarian veins, and also with the uterine venous system on the lateral side of each uterus. This plexiform structure provides an anatomical arrangement which could allow a local transfer of ovarian hormones from ovarian vein into the uterine arterial supply, and thence to the ipsilateral uterus. Progesterone concentrations in plasma from the mesometrial side of the uterine branch of the ovarian vein are markedly higher than in tail vein plasma, especially during the 'Day 5 peak' early in pregnancy, and also at full term. There is also a marked decrease in progesterone concentration from all sites immediately before birth as previously reported for peripheral plasma. These results support the suggestion of a countercurrent transfer mechanism, at least for progesterone, and possibly other hormones, between the ovarian vein and uterine artery. Such a local transfer could explain the different morphological responses of the endometria of the two adjacent uteri during pregnancy in macropodid marsupial species.     

3H-oestradiol-17β counter current transfer from the ovarian vein into the ovarian artery in cows

During laparatomy the ovary in the luteal phase with the ovarian pedicle was isolated and transferred under stereomicroscope. The ovary was supplied with blood flowing out of the facial artery through a cannula. ³H-oestradiol-17β or ⁵¹Cr-labelled red blood cells (⁵¹Cr-RBC) were infused for 30 min through the cannula inserted into the ovarian vein 3 cm below the ovary. During and 30 min after the ³H-oestradiol-17β infusion, radioactivity was found both in the ovarian arterial blood near the ovary and in ovarian tissue. When ⁵¹Cr-RBC were infused in the same way as ³H-oestradiol, there was no radioactivity in the arterial blood or ovarian tissue. These experiments indicate the existence of a counter current transfer of ³H-oestradiol-17β from the ovarian vein into the ovarian artery in a cow's ovarian pedicle.     

Direct venous-arterial transfer of 125I-radiolabelled relaxin and tyrosine in the ovarian pedicle in sheep

125I-labelled relaxin and tyrosine were infused into the ovarian vein to investigate transfer to branches of the ovarian artery at the ovarian pedicle in sheep. The ovarian arteries supply the ovary, the oviduct, and the tip of the uterine horn. An exchange of relaxin (n = 24) and tyrosine (n = 18) was observed in blood samples collected from all branches of ovarian arteries. This is expressed as a ratio of radioactivity greater than 1 between jugular venous blood plasma and arterial blood plasma. The average ratio (+/- s.d.) over the total infusion period of 1 h was 1.42 (+/- 0.35) for relaxin and 1.69 (+/- 0.38) for tyrosine with maximal values up to 4.9 and 2.9, respectively. Of the total amount of substance infused (348 pmol/h), 0.22% of the relaxin and 1.19% of the tyrosine reached the adjacent arteries directly. From these investigations it is concluded that molecules with a molecular weight of approximately 6000 can be transferred directly from veins to arteries at the ovarian pedicle, and the efficiency of this exchange does not only depend on molecular size.     

Counter current transfer in the female adnex

The utero-ovarian veins and lymph vessels are intimately connected with the ovarian artery in the human female and in domestic animals, with the exception of the horse and the human female. A direct, local exchange of molecules from veins and lymph vessels to arteries (counter current transfer) has been documented for this anatomic structure. Countercurrent transfer of certain inert gases (133xenon, 85krypton), of prostaglandins (PGF2 alpha), of steroid hormones (e.g. progesterone, estradiol, testosterone), and of small peptide hormones (oxytocin, relaxin) has been shown to occur in laboratory and domestic animals as well as in the human female. The transfer of the inert gases takes place within seconds. The transfer of steroid hormones and peptides is detectable within minutes while the transfer of PGF2 alpha is delayed for 20 minutes. Red blood cells or albumin are not transferred. The existence of the local transfer is postulated to be of importance for: 1) the pregnancy/non-pregnancy signal from the uterus and tube to the ovary. The signal may be a combination of a luteotrophic signal from the embryo and lack of a "non-pregnant" luteolytic signal from the endometrium, the latter probably being PGF2 alpha in some species; 2) the unilateral influence of the ovarian hormones on the function of the ovarian, tubal, and possibly uterine tissues. An active corpus luteum may create in a mono-ovulatory animal a higher progesterone level in arterial blood supplying the ipsilateral tube and ovarian interstitial tissue than on equivalent contralateral organs.     

Retrograde and local destination transfer of uterine prostaglandin E2 in early pregnant sow and its physiological consequences

The local destination transfer of prostaglandin E2 (PGE2) from the uterine lymph to arterial blood supplying the ovary and its retrograde transfer to arterial blood supplying the uterine horn and the effect of additional delivery of PGE2 into the ovary on the secretion of steroid hormones was studied in early pregnant gilts. The injection of PGE2 under the perimetrium caused an increase (P<0.001) in PGE2 concentration in both uterine venous effluent and ovarian and uterine arterial blood. The infusion of PGE2 into the ovarian artery increased the concentration of progesterone in ovarian venous blood on day 13 of pregnancy during (P<0.05) and after (P<0.001) infusion, and on day 14 of pregnancy after infusion (P<0.01). In conclusion, local destination transfer of PGE2 from uterine lymph and venous blood to the ovary may affect luteal function, and retrograde transfer of PGE2 to the arterial blood supplying the uterus may contribute to the prevention of regressive changes of the endometrium in early pregnant gilts.     

High performance liquid chromatography of steroid metabolites in the pregnenolone and progesterone pathways

Rapid separation of gonadal steroids in the progesterone(Δ⁴) and pregnenolone pathway (Δ⁵) has been accomplished by the use of high performance liquid chromatography (HPLC). Two HPLC systems are utilized. The first requires the use of two separate radial compression columns (C-18 and C-8), with steroids being eluted with a methanol-water gradient. The second employs a stainless steel C-18 (reversed phase) column with a 12% octadecylsilane coating. The latter system separates seven of the eight steroids in the Δ⁴ and Δ⁵ pathways in thirty-five minutes. For the quantitation of steroids directly, integration of the peak areas, using 254 nm absorption for the Δ⁴ pathway steroids (5 ng minimum limit), and 210 nm absorption for the Δ ⁵ pathway steroids (25 ng minimum limit) is used. For the quantitation of radiolabeled metabolites resulting from incubation of gonadal tissue with radiolabeled steroid precursors, either one of two methods is used: (1) the eluent can be recovered from the HPLC using a fraction collector, and counted in liquid scintillation counter or (2) the entire eluent (or a portion of it) can be counted immediately by directing the flow through a radioactivity detector.     

Local exchange of oxytocin from the ovarian vein to ovarian arteries in sheep

Local transfer of 125I-labeled oxytocin from the ovarian vein to arteries supplying the ovary, the oviduct, and the tip of the uterine born has been investigated. In five sheep, 10 infusions of 125I-oxytocin over a period of 1 h were performed, and the concentration of labeled polypeptide in the peripheral plasma was compared to ovarian arterial plasma. During 2 consecutive infusions into each animal's ovarian vein, blood was collected simultaneously from the following sites: ovarian branch of the ovarian artery (OBOA), tubal branch of the ovarian artery (TBOA), uterine branch of the ovarian artery (UBOA), and from the jugular vein. In all experiments the concentration of 125I-oxytocin in ovarian arterial plasma was higher than in peripheral plasma. The ratio of ovarian artery/jugular vein for 125I-oxytocin was: OBOA 2.8, TBOA 1.8, UBOA 1.6. Based on a 4 ml/min blood flow through ovarian arteries supplying ovary, oviduct, and the tip of the uterine horn, the local transfer of the total amount of oxytocin infused was estimated to be about 1% (range: 0.1-4.4%). Analysis of variance did not reveal significant differences in the exchange ratios between OBOA, TBOA, and OBOA. However, the variances within these groups are significant, presumably because of anatomical variation in the degree of surface contact area between arteries and veins at the ovarian pedicle. It is concluded that polypeptides are locally recirculated to ovaries, oviduct, and the tip of the uterine horn in a higher concentration than is supplied by peripheral blood. This could provide a mechanism for local distribution and concentration of the ovarian peptides that regulate reproductive function.     

Ovarian and uterine lymphatic drainage in Australian flying-foxes (genus Pteropus,suborder Megachiroptera)

Ovarian lymphatics of flying-foxes were traced to determine if they could transport hormones directly from ovary to ipsilateral uterine horn, thereby stimulating the localised endometrial growth which is characteristic of these animals. Intra-ovarian injections of ink and serial histological sections did not reveal any such connection. All major ovarian lymphatics and those from the cranial tip of each uterine horn drain cranially, terminating in 1 or 2 lymph nodes lying caudal to the ipsilateral kidney. For much of their course, the major ovarian lymphatics run in the adventitia of the ovarian venous sinus. This sinus encloses the coiled ovarian artery, which provides the major blood supply to the cranial end of the ipsilateral uterine horn. Some fine ovarian lymphatics run in the adventitia of the coiled ovarian artery. The enclosure of the coiled ovarian artery by the ovarian venous drainage is thought to provide the main route for transfer of steroids from ovarian vein to ovarian artery and thence to ipsilateral uterine horn. The ovarian lymphatics described here do not bypass the vascular pathway but provide an additional route for counter-or cross-current transfer of ovarian steroids to the ovarian arterial supply to the uterus.     

Ovarian and adrenal function during the estrous cycle of the sow.

The concentrations of plasma estrogens, progesterone, and corticosteroids and of urinary pregnanediol, pregnanetriol, ketogenic steroids, and corticosteroids were determined as indicators of ovarian and adrenal function throughout a normal sow's estrous cycle. Two broad peaks of plasma estrogen, one lasting 11–12 days during estrus and another 6-day peak period during the early part of the luteal phase were detected. Plasma progesterone was elevated during the late follicular and luteal phase. Two broad peaks of plasma corticoids appeared, one following the decrease of plasma progesterone and the second 7–14 days later. Those elevations in plasma corticoids occurred when estrogen titres were elevated. Urinary determinations generally reflected plasma findings. Estrogen levels began to rise during the follicular phase while a reasonably high progesterone level was evident. Estrogen titres never decreased to non-detectable levels. An interrelationship between adrenal function and ovarian estrogen production is suggested.     

Flow and composition of lymph from the ovary and uterus of cows during pregnancy

Ovarian or uterine lymph was collected continuously for periods of up to 25 days from 16 cows cannulated at stages of pregnancy ranging from 96 to 278 days post coitum. Blood samples were taken acutely from the ovarian and uterine veins during surgery and periodically from the jugular vein during the course of lymph collection. The flow rate and cell content of lymph was measured and blood and lymph plasma samples were analysed for progesterone, pregnenolone, pregnenolone sulphate, androstenedione, testosterone, oestrone, oestrone sulphate, oestradiol-17 beta, prostaglandin (PG) F-2 alpha, total protein and albumin. There was a high flow rate of protein-rich lymph from luteal ovaries with rates up to 101.7 ml/h occurring in individual lymphatics over short periods. Peripheral ovarian and uterine lymph contained a low concentration of cells (mean less than 10(5) cells/ml) comprising about 82-87% lymphocytes, 11-14% macrophages and monocytes and 2-4% other cells. At all stages of pregnancy, the concentration of progestagens and androgens was higher in ovarian lymph than in uterine lymph or blood plasma. The differences were greatest for progesterone and androstenedione which occurred at 200-fold and 60-fold greater concentration respectively in ovarian lymph than in jugular plasma. When serial 10 min samples were collected over a 12-h period, the concentration and output of progesterone in ovarian lymph varied in a phasic manner, ranging from 3.5 to 7.6 microM and from 31.7 to 293.1 nmol/h respectively. There was a positive correlation between the output of progesterone in lymph and the progesterone concentration in jugular blood samples taken every 20 min. During most of pregnancy there was little difference between the concentration of oestrogens in ovarian lymph, ovarian venous plasma and jugular plasma but, during the 3-5 days before calving, these hormones occurred at slightly higher concentration in ovarian lymph. Apart from pregnenolone and androstenedione, all steroids occurred at lower concentrations in uterine lymph than in jugular plasma. Shortly before parturition there was an abrupt increase in the concentration of PGF-2 alpha in uterine lymph. Lymph reflects more accurately the milieu of tissue cells than efferent blood and further analysis of differences in the concentration of substances in lymph relative to the output in the ovarian and uterine arterial and venous blood may lead to the identification of factors important in local regulatory mechanisms in the reproductive tract.     

Determination of infused (13C)progesterone in ovarian arterial blood by selected ion monitoring

Gas chromatography mass spectrometry (GC/MS) with selected ion monitoring (SIM) is employed to detect and approximate the levels of (13C)progesterone is small blood samples obtained at intervals from ipsilateral and contralateral ovarian arteries and a peripheral vein before, during and after infusion into the utero-ovarian vein (five women during hysterectomy). The internal standard was 16 alpha-methylprogesterone. The method is rapid and allows the time course of the infused hormone to be plotted in spite of large and rapidly fluctuating concentrations of endogenous progesterone. The results show for the first time the local in vivo transfer of a steroid hormone from the uterine vein to the adjacent ovary in humans.     

Estradiol induces and progesterone inhibits the preovulatory surges of luteinizing hormone and follicle-stimulating hormone in heifers

Objectives were to determine: 1) whether estradiol, given via implants in amounts to stimulate a proestrus increase, induces preovulatory-like luteinizing hormone (LH) and follicle-stimulating hormone (FSH) surges; and 2) whether progesterone, given via infusion in amounts to simulate concentrations found in blood during the luteal phase of the estrous cycle, inhibits gonadotropin surges. All heifers were in the luteal phase of an estrous cycle when ovariectomized. Replacement therapy with estradiol and progesterone was started immediately after ovariectomy to mimic luteal phase concentrations of these steroids. Average estradiol (pg/ml) and progesterone (ng/ml) resulting from this replacement were 2.5 and 6.2 respectively; these values were similar (P greater than 0.05) to those on the day before ovariectomy (2.3 and 7.2, respectively). Nevertheless, basal concentrations of LH and FSH increased from 0.7 and 43 ng/ml before ovariectomy to 2.6 and 96 ng/ml, respectively, 24 h after ovariectomy. This may indicate that other ovarian factors are required to maintain low baselines of LH and FSH. Beginning 24 h after ovariectomy, replacement of steroids were adjusted as follows: 1) progesterone infusion was terminated and 2 additional estradiol implants were given every 12 h for 36 h (n = 5); 2) progesterone infusion was maintained and 2 additional estradiol implants were given every 12 h for 36 h (n = 3); or 3) progesterone infusion was terminated and 2 additional empty implants were given every 12 h for 36 h (n = 6). When estradiol implants were given every 12 h for 36 h, estradiol levels increased in plasma to 5 to 7 pg/ml, which resembles the increase in estradiol that occurs at proestrus. After ending progesterone infusion, levels of progesterone in plasma decreased to less than 1 ng/ml by 8 h. Preovulatory-like LH and FSH surges were induced only when progesterone infusion was stopped and additional estradiol implants were given. These surges were synchronous, occurring 61.8 +/- 0.4 h (mean +/- SE) after ending infusion of progesterone. We conclude that estradiol, at concentrations which simulate those found during proestrus, induces preovulatory-like LH and FSH surges in heifers and that progesterone, at concentrations found during the luteal phase of the estrous cycle, inhibits estradiol-induced gonadotropin surges. Furthermore, ovarian factors other than estradiol and progesterone may be required to maintain basal concentrations of LH and FSH in heifers.     

Competitive protein binding assay of progesterone without chromatography

A competitive protein binding assay for the measurement of progesterone in human plasma without chromatographic separation of steroids and recovery evaluation in individual samples is described. It is based on the specificity of the progesterone binding plasma protein (PBP) of the pregnant guinea pig. A dried petroleum ether extract of plasma was incubated with ³H-progesterone and 1600 fold diluted pregnant guinea pig plasma. Bound radioactivity was measured with a dextran coated charcoal suspension technique. Plasma progesterone concentration was obtained by comparison with a standard curve and correction for extraction separately measured for each batch of petroleum ether. The sensitivity was 100 pg. Recovery experiments for progesterone and competing steroids added to plasma respectively showed the accuracy and the specificity of the method. However comparison of the results from assays with and without chromatographic separation of steroids, showed that in the latter-case the specificity was good only for plasmas containing more than 1ng/ml of progesterone. Concentration of progesterone in plasma from men was 0.46±0.14 ng/ml (mean ± S.D) and from post menopausal women 0.30± 0.13 ng/ml.Between days 1 and 13 and days 16 and 22 of the normal menstrualcycle the concentrations were respectively 0.81 ± 0.38 and 12.50 ± 2.96 ng/ml. The variations of the progesterone concentration during pregnancy are also shown.     

Induced ovulation and changes in pituitary responsiveness to continuous infusion of gonadotropin-releasing hormone during the ovarian cycle in the bullfrog, Rana catesbeiana

Chronic (2-4 days) constant-rate infusions of mammalian gonadotropin releasing hormone (GnRH) were performed in female bullfrogs, Rana catesbeiana. The magnitude and temporal relationship of profiles of plasma follicle-stimulating hormone (FSH), luteinizing hormone (LH) and sex steroids [testosterone (T), estradiol-17 beta (E2) and progesterone (P)] during GnRH infusion were dependent on ovarian stage. However, in all females, the same biphasic increase in plasma gonadotropins was apparent and initial elevations in gonadotropins were accompanied by correlated increments in plasma T and E2. Complete pituitary "desensitization" to chronic GnRH infusion was not observed. Females in early follicular stages were relatively unresponsive to infusions of 1.0-10.0 micrograms/h GnRH; elevations in plasma LH were marginal and FSH was unchanged. Females with fully developed (preovulatory) ovaries were more responsive: infusion of 1.0 micrograms/h GnRH produced significant elevations in plasma LH by 2 h followed by even larger increases ("surges") after 12 h. This LH "surge" was preceded by a decline in plasma T and E2 and was accompanied by abrupt elevations in plasma P and by ovulation. Postovulatory females showed a more gradual and smaller increase in plasma LH. Infusion of GnRH in the female bullfrog establishes a clear relationship between pituitary responsiveness and the ovarian cycle not evident from acute GnRH injection; GnRH was most effective immediately before ovulation. These data are also the first to detail periovulatory changes in plasma gonadotropins and ovarian steroids in an amphibian.     

Effects of arterial infusions of adrenalin and acetylcholine on luteal secretion of progesterone and oxytocin in goats

The effects of close intra-arterial infusion of acetylcholine and adrenalin on ovarian secretion of progesterone and oxytocin were examined on Day 10 of the estrous cycle in goats (estrus = Day 0). Acetylcholine (15 micrograms/min) was without effect, but adrenalin (10 micrograms/min) significantly (P < 0.001) raised both progesterone and oxytocin concentrations in ovarian vein plasma. These results show that luteal hormone secretion is enhanced in the goat by beta-adrenergic stimulation and suggest that, as in the sheep and cow, there may be neuroendocrine involvement in the regulation of caprine luteal function.     

Metabolism of oestradiol-17 beta and progesterone in the white rhinoceros (Ceratotherium simum simum)

14C-Labelled oestradiol-17 beta and progesterone (50 mu Ci each) were injected i.v. into an adult female white rhinoceros and all urine and faeces collected separately over the next 4 days. The total recovery of injected label was 61%, 25% being present in the urine and 36% in the faeces. Of the radioactivity recovered, 69% was excreted on Day 2 of the collection period. Repeated extraction of samples obtained on Day 2 showed that, of the radioactivity in faeces, 92.4% was associated with unconjugated steroids whereas in the urine the proportion of conjugated and unconjugated steroids were similar (41.2% and 51.4% respectively). After phenolic separation of urinary steroids, HPLC followed by derivatization and recrystallization techniques identified progesterone as the major component of the unconjugated portion with 4-pregnen-20 alpha-ol-3-one as the principal metabolite in the conjugated fraction. Pregnanediol was not present. Oestrone appeared to be the most abundant oestrogen metabolite with smaller but significant amounts of oestradiol-17 beta and oestradiol-17 alpha in the unconjugated and conjugated fractions respectively. Small amounts of progesterone were found in the faecal extract in which the radioactivity consisted mainly of oestradiol-17 alpha and oestradiol-17 beta. The results have established the major excreted metabolites of oestradiol-17 beta and progesterone in the white rhinoceros and the development of more appropriate assay methods for monitoring ovarian function in African rhinoceroses should now be possible.     

Effect of steroids in combination with LH-RH on the release of LH and FSH in LH-RH-primed immature male rat.

LH and FSH release of immature male rats was remarkedably enhanced by LH-RH if primed with LH-RH one hour before. The effect of exogenous steroids on the action of the second LH-RH was investigated. C-18, C-19 and C-21 steroids in different doses were tested. Blood samples were collected from the jugular vein immediately before and 30 min after the second LH-RH injection. Serum LH and FSH were determined by respective radioimmunoassays. The concomitant increase of LH and FSH was not induced by all the steroids administered iv. Estrone or 17alpha-hydroxyprogesterone suppressed LH and FSH release. Estradiol-17beta preferentially suppressed LH release. Cortisone, progesterone or dehydroepiandrosterone significantly facilitated FSH release, whiel 20alpha-dihydroprogesterone or 20beta-dihydroprogesterone selectively promoted LH release. The sc injection of most steroids dissolved in oil tended to augment the acute release of LH but not FSH. 20alpha-Dihydroprogesterone was particularly potent in this concern. Dehydroepiandrosterone or androstenedione was effective in maintaining FSH release for a longer period. These data revealed that potentiated LH and FSH release induced by the second LH-RH was readily modified by steroids administered simultaneously.     

Acute effects of unilateral ovariectomy in the baboonPapio cynocephalus

The purpose of this study was to determine if steroids secreted by one ovary affected the steroid secretion of the other ovary by direct transportation of the steroids via uterine blood vessels. Either two or three baboons were scheduled for ovariectomy on the day of ovulation and on alternate days from 1–15 days before the expected day of ovulation. Two days before the scheduled ovariectomy, utero-ovarian vein blood from both sides was collected by the use of a laparoscope. Measurement of estradiol (E₂) was carried out in these samples. The ovary with a higher concentration of E₂ was designated the dominant side. At the time of ovariectomy utero-ovarian vein and uterine vein blood from the two sides was again collected. After removal of the dominant side ovary another sample of utero-ovarian and uterine vein blood was collected. The interval between removal of one ovary and blood collection from the contralateral side ranged from 2–15 min. Steroids E₂, progesterone (P), testosterone (T), and androstenedione (A) were measured in the blood plasma. Of the 21 baboons 12, 12, 11, and 10 baboons showed an increase in E₂, P, T, and A values, respectively, on the contralateral side after unilateral ovariectomy. The time elapsed between pre-ovariectomy blood collection and post-ovariectomy blood collection as well as the day of the follicular phase, when these samples were collected had no effect on the increases and decreases on the contralateral side. Statistical analysis, however, showed that the change in utero-ovarian vein or uterine vein hormone levels on the contralateral side after removal of one ovary was not significant for any of the four hormones E₂, P, T, and A. Thus there is no evidence to demonstrate cross circulation of steroids from one ovary to the other via direct vascular channels. This research was supported by NIH grant HD15300 toA. A. Shaikh.     

Progesterone values in monkeys near term

The serum progesterone of peripheral, ovarian, uterine and umbilical blood from six Macaca mulatta and two M. fascicularis was determined by radioimmunoassay in late pregnancy. Peripheral progesterone values fell to lower levels the day after delivery, a decrease indicating placental progesterone secretion. The concentration of progesterone in the ovarian vein associated with the presence of a corpus luteum was greater than that in the contralateral vein, a difference denoting active progesterone secretion by the corpus luteum. In most cases the uterine vein on the side associated with the placement of the primary and secondary placentae contained more progesterone than its opposite counterpart, a condition that suggests some synthesis of progesterone by the placenta. The umbilical vein/artery progesterone ratio showed fetal metabolism of this steroid and also greater metabolism of progesterone by the female fetus. The progesterone concentration in the ovarian vein associated with the corpus luteum in mothers who bore female fetuses was greater than that of the same vein in those mothers who bore male fetuses. Peripheral progesterone levels were high the day before cesarean section and fell to lower levels the day after delivery. The decline was more rapid in mothers who bore male fetuses.