Cortisol and cortisone levels in umbilical cord plasma and maternal plasma of normal pregnancies

A method for assaying cortisol and cortisone using chromatography on either paper or Sephadex LH-20 columns for isolation, followed by competitive protein binding, has been applied to umbilical cord and maternal plasma samples. In mixed cord plasma the mean cortisol concentration was 6.0 ± 0.8 μg/100 ml (n = 9) and the mean cortisone concentration was 13.5 ± 2.9 μg/100 ml (n = 9). In cord arterial plasma the mean cortisol concentration was 6.3 ± 2.9 μg/100 ml (n = 6) and the mean cortisone level was 10.1 ± 2.5 μg/100 ml (n = 6). For cord venous plasma, the mean level of cortisol was 5.6 ± 1.5 μg/100 ml (n = 6) and of cortisone was 13.5 ± 2.4 μg/100 ml (n = 6). Maternal plasma gave a mean value of cortisol of 42.3 ± 4.5 μg/100 ml (n = 6) and of cortisone of 6.2 ± 0.9 μg/100 ml. The results of this study suggest that the fetus at term-gestation produces cortisol. The significance of this production compared with placental transfer of maternal cortisol into the fetal circulation however is uncertain.     

The influence of prolactin (PRL) on progesterone secretion by porcine luteal cells in vitro

Porcine luteal cells were obtained from corpora lutea on the 5th, 13th and 17th days of the estrous cycle. The cells were suspended at a concentration of 5 × 10⁴ cells/ml in Eagle's medium with 2% human serum albumin. These cells were incubated with or without 0.01, 0.1, 1 or 10 μg/ml porcine prolactin. The amount of progesterone in cultures was estimated by a radio-immunological method after 30 min, 3 h and 6 h of culturing.Luteal cells obtained on the 5th day of the estrous cycle and incubated without prolactin secreted 71.24 ± 21.91 ng progesterone/ml of medium, whereas under the influence of prolactin at 0.01, 0.1, 1 and 10 μg/ml, 39.06 ± 13.33, 44.31 ± 12.69, 44.88 ± 16.85 and 51.62 ± 15.01 ng progesterone/ml (P<0.01) were secreted. Luteal cells from the 13th day of the estrous cycle incubated without prolactin secreted on average 70.72 ± 9.21 ng progesterone/ml of medium, whereas under the influence of different prolactin doses 50.75 ± 8.52, 46.54 ± 7.13, 43.30 ± 6.78 and 41.68 ± 7.21 ng progesterone/ml (P<0.01) were secreted.Prolactin did not change progesterone secretion by luteal cells obtained on the 17th day of the estrous cycle. An influence of the incubation time on progesterone secretion by these cells was observed: after 30 min of incubation the cells secreted 8.83 ± 2.95 ng/ml, after 3 h 8.12 ± 2.57 ng/ml and after 6 h 6.86 ± 1.91 ng/ml, irrespective of the amount of PRL added.The results suggest that prolactin plays a role in the luteolysis of the corpus luteum.     

Dietary-induced suppression of pre-ovulatory progesterone concentrations in superovulated ewes impairs the subsequent in vivo and in vitro development of their ova

In the first of three experiments, eight ovariectomised Greyface ewes primed with exogenous progesterone were used to provide quantitative data on the effects of two contrasting feeding levels (0.3 vs. 1.4 × maintenance) on plasma progesterone concentrations. Over the 9 day study period, mean (± SEM) daily progesterone concentrations were 4.3 ± 0.13 and 3.3 ± 0.17 μg l⁻¹ for the low and high feeding regimens, respectively (P = 0.06), indicating that high feed intake suppressed circulating progesterone levels. The second experiment examined the effect in superovulated Finn-Dorset ewes of a diet supplying either 0.6 (Group L, n = 8) or 2.3 (Group H, n = 8) times their daily energy needs for maintenance, from 1 day before introduction of exogenous progesterone to the time of insemination, on plasma progesterone concentrations and the viability of ova recovered 4 days after insemination. Mean (± SEM) plasma progesterone concentrations were 4.5 ± 0.17 μg l⁻¹ and 2.8 ± 0.16 μg l⁻¹ for L and H ewes, respectively, during the 12 day priming period (P < 0.001). Eight hours after progesterone withdrawal, levels had fallen to 0.9 ± 0.06 μg l⁻¹ and 0.8 ± 0.07 μg l⁻¹, respectively, then rose to 17.8 ± 3.01 μg l⁻¹ and 12.9 ± 2.50 μg l⁻¹ (P > 0.10) at ovum collection. Intervals (mean ± SEM) to oestrous onset (14.5 ± 0.38 h) and the luteinising hormone (LH) surge (27.1 ± 0.98 h) were unaffected by feed intake. Mean (± SEM) ovulation rates (8.1 ± 1.57 vs. 7.8 ± 1.10) and numbers of ova recovered (5.0 ± 1.39 vs. 4.8 ± 1.11) were also similar for each group. However, the proportions of ova considered viable (over 32 cells) at recovery were 0.53 and 0.22 for L and H groups, respectively (P < 0.005). Following 72 h culture (Tissue Culture Medium-199 (M199) + 10% foetal calf serum (FCS)), 0.55 and 0.27, respectively, had developed to blastocysts (P < 0.025). Of ova assessed as viable at recovery, similar proportions (0.86 vs. 0.75) from L and H treatments developed to blastocysts, with corresponding nuclei counts (mean ± SEM) of 55 ± 5.2 and 55 ± 13.2. The third experiment used 12 superovulated Greyface ewes, each offered a different feed level within the range 0.6–2.5 × maintenance, to determine the nature of the relationship between feeding level, pre-ovulatory progesterone concentrations and ovum development at Day 2 following insemination and subsequently during 7 day co-culture (M199 + FCS). Increases in feeding level were accompanied by linear decreases in plasma progesterone (r² = 0.79, P < 0.001), the interval to oestrous onset (r² = 0.52, P < 0.01) and timing of the LH surge (r² = 0.32, P < 0.06). Although undetectable at ovum collection, and somewhat equivocal after 4 day culture, high feeding levels prior to ovulation reduced the proportion of ova (0.16 vs. 0.58) developing to or beyond the expanding blastocyst stage after 7 day culture. Quantitative indices of cell division and protein synthesis confirmed this. In conclusion, excessive feeding during follicular recruitment and oocyte maturation in superovulated ewes imparts a legacy of embryonic loss and developmental retardation.     

Chromium status of full-term and preterm newborns

In order to obtain reference values from normal babies, Cr status of full-term newborns has been studied. Plasma and urine values were (mean±SEM) 0.7±0.1 μg/L and 0.9±0.3 μg/L, respectively, for the first month of life (n=19), and 0.6±0.1 μg/L and 0.8±0.2 μg/L for the second-to-third-month period (n=31). Premature newborns (gestational age 28–36 wk) were compared to these control values; concentrations were 0.9±0.1 μg/L and 1.1±0.2 μg/L for the first month (n=47), and 1.0±0.2 μg/L and 1.5±0.3 μg/L for the second to third months (n=27). For the whole group, there was a positive correlation between plasma and urine concentrations (p=0.0001); multiple regression analysis was performed between plasma levels and gestational age at birth (p=?0.002) and postnatal age (NS). Plasma levels of prematures and full terms were statistically different (p=0.03) only for the second- to third-month period. It is suggested that these high Cr levels result from high dietary intakes and/or high absorption rates.     

Normal or induced secretory patterns of luteinising hormone and follicle-stimulating hormone in anoestrous gonadotrophin-releasing hormone-immunised and cyclic control heifers

The objective was to determine the effect of gonadotrophin-releasing hormone (GnRH), GnRH analogue (GnRH-A) or oestradiol administration on luteinising hormone (LH) and follicle-stimulating hormone (FSH) release in GnRH-immunised anoestrous and control cyclic heifers. Thirty-two heifers (477 ± 7.1 kg) were immunised against either human serum albumin (HSA; controls; n = 8), or a HSAGnRH conjugate. On day 70 after primary immunisation, control heifers (n = 4 per treatment; day 3 of cycle) received either (a) 2.5 μg GnRH or (b) 2.5 μg of GnRH-A (Buserelin®) and GnRH-immunised heifers (blocked by GnRH antibody titre; n = 6 per treatment) received either (c) saline, (d) 2.5 μg GnRH, (e) 25 μg GnRH or (f) 2.5 μg GnRH-A, intravenously. On day 105, 1 mg oestradiol was injected (intramuscularly) into control (n = 6) and GnRH-immunised anoestrous heifers with either low (13.4 ± 1.9% binding at 1:640; n = 6) or high GnRH antibody titres (33.4 ± 4.8% binding; n = 6). Data were analysed by ANOVA. Mean plasma LH and FSH concentrations on day 69 were higher (P < 0.05) in control than in GnRH-immunised heifers (3.1 ± 0.16 vs. 2.5 ± 0.12 ng LH ml⁻¹ and 22.5 ± 0.73 vs. 17.1 ± 0.64 ng FSH ml⁻¹, respectively). The number of LH pulses was higher (P < 0.05) in control than in GnRH-immunised heifers on day 69 (3.4 ± 0.45 and 1.0 ± 0.26 pulses per 6 h, respectively). On day 70, 2.5 μg GnRH increased (P < 0.05) LH concentrations in control but not in GnRH-immunised heifers, while both 25 μg GnRH and 2.5 μg GnRH-A increased (P < 0.05) LH concentrations in GnRH-immunised heifers, and 2.5 μg GnRH-A increased LH in controls. FSH was increased (P < 0.05) in GnRH-immunised heifers following 25 μg GnRH and 2.5 μg GnRH-A. Oestradiol challenge increased (P < 0.05) LH concentrations during the 13–24 h period after challenge with a greater (P < 0.05) increase in control than in GnRH-immunised heifers. FSH concentrations were decreased (P < 0.05) for at least 30 h after oestradiol challenge. In conclusion, GnRH immunisation decreased LH pulsatility and mean LH and FSH concentrations. GnRH antibodies neutralised low doses of GnRH (2.5 μg), but not high doses of GnRH (25 μg) and GnRH-A (2.5 μg). GnRH immunisation decreased the rise in LH concentrations following oestradiol challenge.     

The effect of prenatal photoperiodic history on the postnatal endocrine status of female lambs

Postnatal photoperiodic experience plays a pivotal role in determining the timing of ovarian activity in female lambs. This study examines whether a photoperiodic history gained while in utero is able to influence this timing.Pregnant Soay ewes were maintained in either long days (n = 7, 18 h light : 6 h dark; group PLD) or short days (n = 12, y h light : 18 h dark; group PSD) from 25 days of gestation. At birth, female lambs (n = 8 per group) were transferred to long days for 10 weeks, and then placed under short days until the end of the experiment at 38 weeks of age. Blood samples were collected from lambs on the day of birth and three times weekly for the duration of the study and the resulting plasma assayed for progesterone and prolactin.Although both gestational photoperiods produced, at best, abbreviated periods of ovarian activity, lambs born to ewes which experienced long days during gestation (group PLD) exhibited elevated plasma progesterone concentrations significantly earlier (P < 0.05) than lambs born to ewes exposed to short days during gestation (group PSD) (mean ± SEM, 193 ± 17 versus 244 ± 14 days for PLD and PSD groups, respectively. Plasma prolactin concentrations in newborn lambs born between late December and early April were not affected by the ambient photoperiod, but reflected the artificial daylength experienced by their mothers during gestation. Lambs born to ewes maintained under long days during gestation (group PLD) had significantly higher prolactin concentrations on the day of birth than lambs born to ewes maintained under short days during gestation (group PSD) (45 ± 5.4 ng/ml versus 7 ± 3.7 ng/ml respectively, P < 0.001). The mean birth weight, rate of live weight gain and live body weight of lambs at the end of the experiment did not vary significantly between treatment groups. These results suggest that the ovine foetus is sensitive to photoperiodic information prior to birth, and develops a photoperiodic history which, under the present experimental conditions, modulates the subsequent endocrine status of the neonatal lamb.     

Temporal relationship of the prolactin-dependent LH-induced LH receptor to the LH stimulus

The time course for LH induction of luteinizing hormone (LH) receptors as reflected in binding of ¹²⁵l-labeled hCG was investigated in hypophysecto-mized adult male rats. A low dose of oLH (10 μg) was administered to hypophysectomized adult male rats following pretreatments with prolactin, follicle-stimulating hormone (FSH), growth hormone (GH), or saline. Testicular binding of hCG was determined at different times following the LH injection using Leydig cell membrane preparations from a testicular homogenate. Seven days after hypophysectomy, hCG binding was at a nadir of 19 ± 7% (mean ± SD) of control values. Pretreatment with prolactin (100 μg/day) for 7 days was associated with a nonsignificantly different hCG binding that was 30 ± 5% of control values. Prolactin pretreatment plus a single 10 μg LH i.p. injection increased ¹²⁵l hCG binding up to 56 ± 10% of control values within 30 minutes of the LH injection. Luteinizing hormone-induced hCG binding persisted at a high level (51 ± 4% of control values) for 2 hours but returned to hypophysectomized control levels 6 hours after the i.p. LH injection. Seven days pretreatment with FSH or GH at 100 μg/day plus 10-μg LH injections was also tested. Neither FSH nor GH had a statistically significant effect on hCG binding nor could they mimic the ability of prolactin to allow for LH induction of hCG binding in the hypophysectomized adult male rats. These studies suggest that the induction or “up-regulation” of Leydig cell hCG binding by ovine LH is rapid and specifically dependent upon pre-exposure to prolactin.     

High-performance liquid chromatographic determination of spectinomycin in swine,calf and chicken plasma using post-column derivatization

An HPLC method for the determination of spectinomycin in swine, calf and chicken plasma at 0.1 μg/ml or higher is described. The clean-up is based upon ion-pair solid-phase extraction on a High Hydrophobic C₁₈ column treated with sodium dioctyl suflosuccinate. After elution with methanol, spectinomycin is chromatographed on a Spherisorb SCX column using 0.1 M sodium sulphate solution (pH 2.6)-acetonitrile (80:20, v/v) as mobile phase. Fluorescence detection is at an excitation wavelength of 340 nm and an emission wavelength of 460 nm after post-column oxidation with sodium hypochlorite followed by derivatization with o-phthaldialdehyde. Mean recoveries were 99 ± 2% (n = 6), 99 ± 2% (n = 7) and 104 ± 2% (n = 6) for swine, calf and chicken plasma, respectively, at the 0.1 μg/ml level.     

Reproductive endocrine responses to photoperiod and exogenous gonadotropins in the pallas' cat (Otocolobus manul)

Fecal samples were collected for 14–26 months from three male and six female Pallas' cats (Otocolobus manul) to examine gonadal steroidogenic activity in response to changes in photoperiod and treatment with exogenous gonadotropins. Females exhibited a seasonal anestrus from May–December, excreting consistently low concentrations of fecal estrogens (overall mean, 50.2±8.5 ng/g). During the breeding season (January–April), baseline fecal estrogen concentrations were higher, averaging 128.4±18.9 ng/g, with peak concentrations ranging from 455.8–909.6 ng/g. Interpeak intervals in estrogen excretion ranged between 7 and 21 days, with an average estrous cycle length of 14.3±1.7 days. Two females became pregnant after natural mating, with overall luteal progestogen concentrations averaging ～40 μg/g throughout gestation. Fecal estrogens increased in mid‐gestation, peaking just before birth. Induction of follicular development with eCG (100–300 IU, i.m.) resulted in an increase in fecal estrogens (peak range, 263.1–1198.1 ng/g), followed by a postovulatory increase in fecal progestogens (overall mean, 41.1±11.9 μg/g) after hCG (75–150 IU, i.m.). Despite apparently normal ovarian responses, none of the females conceived after artificial insemination (AI). The gonadotropin‐induced nonpregnant luteal phase lasted 49.8±5.3 days (range, 30–60 days), whereas gestation lasted ～70 days. In the male Pallas' cat, fecal androgens were elevated from November–April (overall mean, 352.3±30.3 ng/g) compared with nadir concentrations during the rest of the year (82.1±3.3 ng/g). Entrainment of seasonality to photoperiod was demonstrated by stimulation of gonadal steroidogenic activity in cats exposed to increasing artificial light during natural (nonbreeding season) and artificially induced short‐day photoperiods. In summary, reproduction in Pallas' cats is highly seasonal and photoperiod‐dependent. Females exhibit elevated baseline and peak fecal estrogen concentrations for 3–4 months during late winter/early spring. Testicular steroidogenic activity precedes the rise in female estrogen excretion by about 2 months, presumably to ensure maximal sperm production during the breeding season. Zoo Biol 21:347–364, 2002. Published 2002 Wiley‐Liss, Inc.     

Ultrafiltration-light absorption spectrophotometric determination of silicon in blood

An ultrafiltration-light absorption spectrometric method for soluble molybdate-reactive silicon was assessed and applied to bovine and ovine blood plasma and sera, giving precise analytical results. Interfering protein above molecular weight 10,000–25,000 was removed by ultrafiltration, and silicon in ultrafiltrates was quantitated by measuring light absorption at 810 nm of the 1,2,4-aminonaphthol sulfonic acid/ascorbic acid-reduced silicomolybdate. Chemical interferences on the color-forming reaction of remaining blood components were tested by measuring recoveries of silicon added to real blood plasma samples and to synthetic blood plasma solutions, the latter containing typical levels of the major ions Na⁺, K⁺, Ca²⁺, HCO₃^?, and Cl^?, together with varying quantities of the potential interferants (amount per analytical reaction): phosphate (0–0.5 mg P), ferric ion (0–3 mg), fluoride (0–1.25 mg), vanadate (0–0.5 mg V), arsenate (0–10 μg As), and germanate (0–0.5 μg Ge). The mean recovery of added 0.8–9 μg silicon/g of bovine and ovine plasma was 97.7% (SE = 1.0, n = 17); the mean recovery of 1 and 5 μg silicon from synthetic blood plasma solutions with interferant levels up to 50-fold that in normal plasma was 99.2% (SE = 0.3, n = 47). Silicon concentrations found in bovine and ovine blood plasma and sera were typically around 7 μg/ml with procedural reagent blanks consistently low at a mean of 0.12 μg/test (SD = 0.011, n = 20). The silicon level in Center for Disease Control bovine serum (reference specimen Lot R-2274) was found to be (mean ± SE, n = 10) 1.147 ± 0.013 μg/g or 1.172 ± 0.013 μg/ml (25°C). The method detectivity (detection limit) was estimated at 0.03 μg.     

Does dietary arsenic and mercury affect cutaneous bleeding time and blood lipids in humans?

Fish species may contain considerable amounts of trace elements, such as selenium (Se), arsenic (As), and mercury (Hg). The present study investigated the relationships between dietary intake of these elements and cutaneous bleeding time and blood lipids in 32 healthy volunteers. For 6 wk, one group (n=11) consumed approx 250 g Se-rich fish daily, providing them with an average Se intake of 115±31 μg Se/d, Hg intake of 18±8 μg/d, and As intake of 806±405 μg/d, all values analyzed in 4-d duplicate food collections. To study the effect of Se alone, one group (n=11) included Se-rich bread in their normal diet, giving them a Se intake (135±25 μg/d) that was comparable to the fish group. A control group (n=10) ate their normal diet, providing 77±25 gmg Se/d, 3.1±2.5 μg Hg/d, and 101±33 μg As/d. The dietary As load strongly correlated both with bleeding times and changes in bleeding times (r=0.48,p<0.01 andr=0.54,p<0.002, respectively). Dietary Hg showed a positive correlation with LDL-cholesterol (r=0.55,p<0.01), whereas dietary Hg in the fish group showed a strong negative relationship with HDL-cholesterol (r=?0.76,p<0.01). Selenium seemed to have only a modest effect on bleeding time. Our results suggest that mercury and arsenic from fish may be factors contributing to or modifying some of the known effects of fish ingestion.     

Low selenium status in alcoholic cirrhosis is correlated with aminopyrine breath test

The relationship among impaired selenium status, lipid peroxidation, and liver function was examined in 19 hospitalized patients with severe alcoholic cirrhosis. Plasma selenium was found to be significantly lower (mean±SD: 54±13 μg/L) than in healthy controls (83±11 μg/L) and plasma malondialdehyde, assessed as thiobarbituric acid reactants, which reflects lipid peroxidation, was increased (2.0±1.2 μmol/L vs <1.2 μmol/L in controls). The mean¹⁴C aminopyrine breath test, an indicator of liver function, was lower than normal (2.7±1.9 vs 6.3±0.9% in controls) and found to be significantly correlated with plasma selenium (r=0.59,p<0.05). A prospective, randomized selenium supplementation trial was conducted in a group of 16 patients who received either daily 100 μg selenium as enriched yeast during 4 mo or a placebo. Among the 10 patients who completed the study, plasma selenium significantly increased in the supplemented group (n=4; before: 58±10 μg/L, and after 101±12 μg/L,p<0.01) contrary to the placebo group (n=6, before: 47±10 μg/L, after: 57±9 μg/L, n.s.),¹⁴C aminopyrine breath test improved in three out of four selenium-supplemented patients and in three out of six placebo patients, but the small number of patients did not allow statistical evaluation. These results demonstrate that low selenium status in alcoholic cirrhosis is correlated to liver function and could be improved by supplementation.     

Induction of atresia of the dominant follicle in rhesus monkeys (Macaca mulatta) by the local application of estradiol-17β

Estradiol-17β (E₂), administered systemically to rhesus monkeys during the follicular phase of the menstrual cycle, induces atretic changes in the microenvironment of the dominant follicle (DF), which results in its demise. It has been proposed that this effect of E₂ represents a direct action at the ovarian level. The present study was designed to test this hypothesis, using local treatment with E₂. After identification of the DF during laparoscopy on day 6 of the cycle, female monkeys were laparotomized and their ovaries exposed. Either corn oil (20 μl, controls) or E2 (100 μg ) in oil vehicle (experimentals) was injected into the ovary near the DF. In control animals, preovulatory release of gonadotropins and ovulation were normal in five of six animals, with cycle and luteal phase lengths of 27.8 ± 2.2 days and 14.6 ± 2.5 days, respectively (x? ± S.D.). Conversely, in only one of six animals in the experimental group did ovulation occur at the expected time (P < 0.05). In the other five treated animals, E₂ induced atresia of the DF and significantly extended cycles (35.4 ± 5.4 days) without affecting luteal phase lengths (12.0 ± 1.4 days). Concentrations of estrogen in peripheral sera of some animals were increased transiently at 6 h after injection of E₂ but returned to normal by 12 h; this duration of estrogen exposure is far less than the 24 h required to induce atresia of the DF in previous studies. At 6 h after injection of E₂, there was a statistical difference between controls and experimentals in concentrations of circulating estrogen; however, these changes were apparently not enough to alter pituitary secretion of follicle-stimulating hormone or luteinizing hormone. These data support the hypothesis that E₂ can induce atresia of the DF in rhesus monkeys by acting locally at the ovary.     

Salivary progesterone for the assessment of the ovarian function in the capuchin monkey (Cebus apella)

Salivary and plasma progesterone were measured in normally cycling (n=10) and castrated (n=4) femaleCebus monkeys (Cebus apella). During the follicular phase, progesterone levels in saliva ranged between 0.05 and 1.40 ng/ml and in the luteal phase they increased to between 0.22 and 4.70 ng/ml. These values represented on average 6.5 and 3.2% of those values measured in plasma, for the follicular and luteal phases, respectively. The regression analysis of the steroid concentrations in both fluids showed a highly significant correlation (r=0.8985,n=180,P<0.0001). Ovariectomized monkeys had consistently low salivary (0.37±0.02 ng/ml) and plasma (4.70±0.25 ng/ml) progesterone, showing a low, but significnat, correlation coefficient (r=0.2592,n=58,P=0.047). The ratio of plasma/salivary progesterone was significantly higher in the luteal phase (31.09±1.65) than in the follicular phase (23.06±2.26) and in castrated monkeys (16.00±1.38). The free fraction of progesterone constituted 5.3±0.2% of the total plasma progesterone during the follicular phase and 3.3±0.1% during the luteal phase. Ovariectomized monkeys showed a significantly higher percentage of free progesterone in plasma (7.7±0.1%). In contrast, free progesterone made up 64.4 and 70.9% of the total salivary progesterone for the follicular and luteal phases, respectively. The proportion of free progesterone in castrated animals was within the range observed in cycling animals. We suggest that the levels of progesterone in the saliva of capuchin monkey follow a pattern similar to that for plasma progesterone, reflecting the free steroid fraction. Thus, the measurement of such steroid in saliva may offer a valuable alternative to plasma determinations for the assessment of the ovarian function inCebus and probably other New World monkey species.     

The Antiepileptic Effect of Ghrelin During Different Phases of the Estrous Cycle in PTZ-Induced Seizures in Rat

Catamenial epilepsy is a special form of epilepsy in women whom seizure aggravation is arranged with menstrual cycle that may affect up to 70 % of epileptic women. Antiepileptic effect of Ghrelin hormone has been proved recently. Due to effects of Ghrelin on GABA and LH concentration and periodic variation in the level of estrogen (E₂) and progesterone (P₄) during menstrual cycle, it seems that antiepileptic effect of Ghrelin can be different during various phases of estrous cycle. So this study was conducted to survey antiepileptic effect of Ghrelin during various phases of estrous cycle in rats. 72 adult female Wistar rats in three groups (control, 40 and 80 μg/kg of Ghrelin), each with four subgroups (proestrus, estrus, metestrus and diestrus) were used (n = 6). Then, intracerebroventricular (ICV) injection of Ghrelin (40 and 80 μg/kg) followed by intraperitoneal injection of 80 μg/kg pentylenetetrazole in control and treatment groups were done. Initiation time of myoclonic seizures (ITMS), initiation time of tonic–clonic seizures (ITTS), seizures duration and mortality rate were monitored and recorded for 30 min. Results showed that, ICV injection of Ghrelin significantly increased ITMS and ITTS during luteal phase than follicular phase compared to control group (P < 0.05). Also, seizure duration significantly decreased after ICV injection of Ghrelin during luteal phase and follicular phase compared to control group (P < 0.05). Furthermore, there was no mortality after ICV injection of Ghrelin (40 and 80 μg/kg) during luteal and follicular phases compared to control group (P < 0.05). These results suggest that Ghrelin has antiepileptic effects which are more prominent during luteal phase than follicular phase.     

Opioid regulation of luteinising hormone and prolactin release in the horse—identical or independent endocrine pathways?

In order to determine if endogenous opioids regulate luteinising hormone (LH) and prolactin secretion via a common, gonadotropin-releasing hormone (GnRH) dependent pathway in the horse, effects of the opioid antagonist naloxone (300 mg) and the GnRH agonist buserelin (20 μg) on prolactin and LH secretion were investigated in stallions (n = 22), long-term castrated geldings (n = 15) and non-lactating mares during the luteal phase of the oestrous cycle (n = 16). Blood samples for determination of LH and prolactin concentrations were withdrawn at 15 min intervals for 120 min. After 60 min of sampling, animals were treated with either naloxone, buserelin or saline. In stallions, naloxone significantly increased LH as well as prolactin release (P < 0.05), indicating an opioid inhibition of both hormones, whereas in mares, naloxone stimulated only LH secretion (P < 0.05). No changes in plasma LH or prolactin concentrations after injection of naloxone were found in geldings. In all animal groups, buserelin induced a significant release of LH (P < 0.05) without affecting prolactin. We conclude that endogenous opioids inhibit LH and prolactin release in the horse but the regulation of these two hormones involves independent opioid pathways. These are activated differentially in stallions, geldings and mares. The opioid regulation of prolactin secretion is not mediated via GnRH.     

Cadmium effects on dopamine turnover and plasma levels of prolactin, GH and ACTH

This paper analyzes possible dopamine (DA) mediated cadmium effects on plasma levels of prolactin, growing hormone (GH) and adrenocorticotropic hormone (ACTH), and if these changes are related to metal accumulation. For that purpose, adult male rats were treated with 50 mg/L of CdCl₂ in the drinking water for one month. Plasma levels of prolactin, ACTH and GH were measured by specific double antibody radioimmunoassays. DA was measured by high performance liquid chromatography using electrochemical detection. Cadmium content in the tissues was measured by atomic absorption spectometry with graphite furnace. Analysis was performed by using a T-Student test. Metal exposure increased DA content (34.79±3.06vs. 18.2±2.88 pg/mg protein) and decreased its turnover (0.40±0.07vs. 0.75±0.06) in posterior hypothalamus. Cadmium also decreased DA turnover in median eminence (0.48±0.15vs. 1.50±0.63). Plasma levels of prolactin and GH decreased (2.4±0.11vs. 3.1±0.15 ng/mL and 5.37±0.05vs. 9.87±1.8 ng/mL respectively), while those of ACTH increased (2.73±0.14vs. 1.7±0.16 ng/mL). Cadmium concentration increased in both hypothalamus (4.88±0.34vs. 0.72±0.2 μg/g) and pituitary (22.82±4.57vs. 5.02±1.25 μg/g) after the metal exposure. These results suggest that cadmium effects on the secretion of these hormones are not mediated by dopamine and might be correlated to the metal accumulation at pituitary level.     

Differential effects of placental lactogen,growth hormone and prolactin on rat liver ornithine decarboxylase activity in the perinatal period

Ovine placental lactogen, (oPL), ovine growth hormone, (oGH), and ovine prolactin, (oPRL) are present in high concentrations in the fetal circulation late in gestation. To determine if these hormones stimulate the activity of ornithine decarboxylase (ODC), an enzyme widely implicated in the control of cellular growth, rat fetuses were injected $\text{in utero}$ with 100 μg of oPL, oGH, oPRL, rat growth hormone (rGH) or rat prolactin (rPRL) and ODC activity in the livers, hearts, and brains of the fetuses was measured 2, 4, and 6 hours after injection. OPL stimulated fetal liver ODC activity by 282 ± 45% (mean ± SEM) as compared to litter mates injected with buffer alone but oGH, oPRL, rGH and rPRL had no effect on fetal liver ODC activity. However, in neonatal rats 24–48 hours old all five hormones significantly increased liver ODC activity. ODC activities in the hearts and brains of the fetuses and neonates were unaffected by any of the five hormones. In other experiments 50 μg of oPL significantly stimulated fetal liver ODC activity while 250 μg of oGH were without effect. However 25 μg of oGH significantly stimulated liver ODC activity in rat pups 1–2 days after birth. These results suggest that oPL, by its stimulation of ODC activity, has somatotropic effects in the fetus and that rat liver ODC activity becomes responsive to growth hormone and prolactin in the perinatal period.     

The Effect of oestradiol benzoate on the duration of oestrus and release of LH in ovariectomized Galway ewe lambs and adult ewes

The oestrous and LH responses by ovariectomized adult ewes (N=23) and 8-month-old ewe lambs (N=24) to i.m. injection of 10, 25, 62.5 or 156.25 μg oestradiol benzoate (ODB) were compared. The animals were primed by six daily injections of progesterone and ODB was administered 48 h after the last progesterone injection. The interval between ODB injection and onset of oestrus declined linearly (P<0.01) as the dose of ODB increased and was similar for the two age groups. The mean (±SEM) intervals to oestrus for levels of 10, 25, 62.5 and 156.25 μg ODB were 22.9±1.90, 18.0±1.33, 14.5±1.26 and 13.5±1.32 h, respectively. The duration of oestrus, determined by checking with Finnish Landrace rams at 3-h intervals, increased linearly (P<0.01) as the dose of ODB was raised and was significantly longer for ewe lambs (63.1±2.95 h) than for adult ewes (50.4±3.52 h). The overall mean (±SEM) durations of oestrus for levels of 10,25, 62.5 and 156.25 μg ODB were 16.9±5.91, 37.0±4.13, 75.2±3.94 and 97.8±4.13 h, respectively. A “pre-ovulatory” -type LH surge was observed in 32 of the 47 animals studied. The interval between injection of ODB and the beginning of the LH release declined as the dose of ODB increased (P<0.01) and was shorter (P<0.01) for ewe lambs (19.8±0.74 h) than for adult ewes (23.2±0.90 h). There was no evidence for an effect of either ewe age or dose of ODB on the maximum LH concentration observed, duration of LH discharge or total quantity of LH released. The sensitivity of the two age groups to the negative feedback effects of ODB on LH secretion was similar.     

Plasma FSH,LH, prolactin and progesterone profiles of Cheviot ewes with different levels of intake before and after mating,and associated effects on reproductive performance

Patterns of secretion of FSH, LH and prolactin were investigated in the luteal and follicular phases of the cycle prior to mating in Cheviot ewes on high and low intakes (approximately 3.0 and 0.8 kg DM per head per day) during the weeks before mating. Ewes on the high intake had a higher mean ovulation rate (1.95 vs 1.40; P < 0.01) and higher mean potential litter size (1.75 vs 1.00; P < 0.001) as determined at slaughter 3 weeks after mating.No significant differences associated with intake were observed in the endocrine profiles during the luteal phase of the cycle before mating, indicating that differences in reproductive performance were not mediated by changes in endocrine profiles in this period. However, during periods of the subsequent follicular phase, ewes on a high intake had a higher LH pulse frequency, higher mean prolactin levels and non-significantly higher FSH levels. The preovulatory peaks of these hormones were not altered by the level of intake but the mean peak values for prolactin and LH were significantly higher in ewes with multiple ovulations than in those with single ovulations. Differences in endocrine status prior to mating were not associated with differences in luteal function after mating, as measured by circulating progesterone levels. However, mean progesterone levels were higher in ewes on a low intake after mating compared with those on a high intake.