Superovulation in immature and mature Chinese hamsters

Mature female Chinese hamsters ovulate an average of 8.8 ± 1.0 (mean ± SD) eggs per female in each estrous cycle. Superovulation can be induced in both immature and mature females by subcutaneous or intraperitoneal injections of pregnant mare serum gonadotropin (PMSG) and either human chorionic gonadotropin (hCG) or pituitary luteinizing hormone (PLH). The best superovulation in immature females was induced by the administration of 15 IU of PMSG followed 72 hr later by injection of 15 IU of hCG (about 25 eggs per female) or 0.2 mg (200 IU) PLH (about 46 eggs per female). Ovulation started about 13–15 hr after administration of hCG (or PLH) and was completed during the next 5–6 hr. Superovulation in mature females could be induced by injecting PMSG any day of the estrous cycle, but the best superovulation (about 39 eggs per female) was induced by injecting 15 IU of PMSG on day 1 (day of ovulation) followed by the injection of 0.4 mg of PLH 72 hr later. When immature females treated with the best superovulatory protocol were mated on the evening of PLH injection, only 5% of the eggs were found fertilized 50 hr after PLH administration. On the other hand, about 60% of the eggs were found fertilized in mature females mated following treatment with the best superovulatory protocol. The majority (83–85%) of superovulated eggs obtained from both immature and mature females were normally fertilized in vitro.     

Preimplantation embryo development and serum steroid levels in immature rats induced to ovulate or superovulate with pregnant mares' serum gonadotropin injection or follicle-stimulating hormone infusions

Follicular stimulation protocols using pregnant mares' serum gonadotropin (PMSG) or a follicle-stimulating hormone (FSH) preparation were compared to evaluate the yield and quality of embryos obtained from immature rats. Rats received a superovulatory dose of PMSG (401U), a nonsuperovulatory dose of the same gonadotrophin (4 IU), or a continu ous s.c. infusion over a 72-h period with a purified FSH preparation containing an opti mum ratio of luteinizing hormone (LH): FSH (FSH-hCG). The females were caged with fertile males on the evening of the 3rd day of gonadotropin treatment and scored for the occurrence of mating on the next morning; subgroups were killed on days 1–4 of preg-nancy. High fertilization rates were observed in rats treated with 4 IU PMSG (84.1%) and in rats infused with FSH-hCG (91.0%); however, a much lower fertilization rate was observed following treatment with 40 IU PMSG (41.5%). From median ovulation rates of 9 and 79 in rats treated with 4 IU PMSG and in rats infused with FSH-hCG, medians of 8 and 69 embryos, respectively, were recovered from reproductive tracts flushed on day 4 of pregnancy, from which 75% were morulae or blastocysts; in contrast, from a median ovu lation rate of 42.5, a median of only 12 embryos was recovered on day 3 of pregnancy following superovulation with 40 IU PMSG of which 80% were degenerate ova. Serum steroid profiles during the first 4 days of pregnancy differed significantly among treatment groups, the major differences being in substantially elevated levels of estradiol and andro-gens on days 1–3 in rats receiving the high (40 IU) dose of PMSG. Levels of these steroids in rats superovulated with the FSH-hCG infusion regimen were only marginally elevated above levels observed in rats treated with the low (4 IU) nonsuperovulatory dose of PMSG. Consistent with high ovulation rates, serum progesterone levels rose to considera bly higher levels during the period in both superovulated groups than in animals receiving the low, nonsuperovulatory dose of PMSG. This work describes a novel method to superovulate rate (FSH-hCG) leading to high yields of normally developing embryos at all preimplantation stages and illustrates the close association between high yield of emyryos and low levels of circulating andorgens and estradiol-17β during the preimplantation period.     

C57BL/6J小鼠超数排卵的研究

目的　确定C57BL 6J小鼠超排的最佳激素剂量和最合适的注射间隔时间 ,提高超排率。方法　 40只C57BL 6J雌鼠随机分为四组 ,分别用 5IU或 10IU的PMSG和HCG ,间隔 48h或 72h注射 ,比较排出卵母细胞的数量。结果　 5IU +5IU剂量的PMSG和HCG、间隔 48h注射组超排效果最好 ;8～ 10周龄雌鼠较 6～ 8周龄雌鼠超排效果好。结论　C57BL 6J小鼠超排的最佳激素剂量为 5IUPMSG +5IUHCG ,最合适的注射间隔时间为 48h ,处于繁殖期的雌鼠超排效果好。     

Adverse effects of gonadotrophin treatment on pre- and postimplantation development in mice.

The effect of gonadotrophins on pre- and postimplantation development in mice was investigated by superovulating C57BL/6J/Bom females with pregnant mares' serum gonadotrophin (PMSG) and human chorionic gonadotrophin (hCG) or by inducing ovulation with hCG. In both hormone treated groups, the proportion of abnormal preimplantation embryos increased compared with naturally ovulating animals. Postimplantation mortality increased and the mean number of live fetuses per pregnant mouse decreased in superovulated and hCG-treated mice compared with controls. Embryonic growth was highly retarded. Mean weight of live fetuses in superovulated and hCG-treated mice was reduced and skeletal examination revealed developmental retardation. In conclusion, superovulation as well as induction of ovulation adversely affected embryonic and fetal development.     

Biochemical status of ovaries after induction of superovulation on different days of estrus cycle in mice

To investigate the role of ovarian status and to find out a suitable hormonal dose for induction of superovulation and its effect on biochemical status of the ovaries, the mice were injected with PMSG in doses of 5, 7.5, and 10 IU on different days of the estrous cycle i.e. proestrus, estrus, metestrus and diestrus followed by hCG injection 48 hr later. All these treatments increased the mean ovarian weight and ovulation rate when compared with that of control animals. Maximum response was observed by treatment with 7.5 IU PMSG on the day of estrus. This treatment resulted in a non-significant decrease in total proteins but a significant increase in the lipid concentrations while no change in cholesterol content of the ovaries of superovulated mice. The activity of acid phosphatase and lactate dehydrogenase significantly increased and alanine aminotranseferase significantly decreased in the ovaries of mice after superovulatory treatment when compared with that of control animals. This reveals that treatment with PMSG and hCG results in metabolic alterations in the ovaries which may perhaps be inducing biosynthetic deficiencies in oocytes as indicated by increased prenatal mortality in superovulated pregnant mice when compared with that of controls in the present studies.     

Time of ovulation in goats (Capra hircus) induced to superovulate with PMSG

The timing of ovulation in feral goats treated with 1200 i.u. PMSG +/- 50 micrograms GnRH was studied by repeated laparoscopy. Experiment 1 established that superovulation began as early as 30 h after withdrawal of progestagen-impregnated sponges and was not completed at 54 h if goats received PMSG alone. GnRH synchronized ovulation, leading to 91% of ovulations appearing between 36 and 48 h after sponges were withdrawn. Experiment 2 established that superovulation continued until up to 77 h in goats treated only with PMSG. The stress of repeated laparoscopy appeared to delay or abolish ovulation in some females. The mean (+/- s.e.) ovulation rate was greater in goats treated with GnRH (12.7 +/- 1.3) than in those that received PMSG only (9.7 +/- 1.1; P less than 0.05). Out of 47 of the females in Exp. 1, 43 had one or more corpora lutea at laparoscopy 24 h after withdrawal of progestagen. These early corpora lutea were associated with an increased concentration of plasma progesterone during the periovulatory period. Experiment 3 provided evidence that these corpora lutea arose before the withdrawal of progestagen-impregnated sponges.     

Use of PMSG antiserum in superovulated cattle?

Two Pregnant Mare Serum Gonadotrophin (PMSG) antisera were tested in 174 dairy cows that were superovulated with PMSG and were then given prostaglandin at 60 hours after PMSG. At 48 hours after injection of prostaglandin, the cows were given either PMSG antiserum (monoclonal (n=56) or polyclonal (n=57)), or saline as control (n=61). Ova (n=1,206) were recovered either nonsurgically or after slaughter. Of these, 757 were evaluated morphologically to be transferable embryos. A proportion of these embryos (n=295 from 52 flushed donors) were transferred to synchronized recipients and the pregnancy results were recorded. The reproductive function of 37 flushed donors was followed for 6 months after superovulation. No significant effect of the PMSG antisera could be demonstrated in any of the parameters studied (i.e., ovulation rate, number of follicles at collection, total yield of ova, fertilization rate, number of transferable embryos, pregnancy results after transfer of embryos, or period required by the donor cows for restitution of reproductive function after superovulation and recovery). It is concluded that use of PMSG antiserum did not improve the embryo yield in terms of the number and quality of transferable embryos or enhance normalization of reproductive function of the donor in the 6-month period after superovulation. Therefore, in an embryo transfer operation, the routine use of PMSG antiserum in a PMSG superovulation regimen in cattle is not recommended.     

Evaluation of systems for collection of porcine zygotes for DNA microinjection and transfer

Crossbred gilts and sows (n=116) were used for the collection of 1-cell zygotes for DNA microinjection and transfer. Retrospectively, estrus synchronization and superovulation schemes were evaluated to assess practicality for zygote collection. Four synchronization and superovulation procedures were used: 1) sows were observed for natural estrous behavior; 1000 IU human chorionic gonadotrophin (hCG) was administered at the onset of estrus (NAT); 2) cyclic gilts were synchronized with 17.6 mg altrenogest (ALT)/day for 15 to 19 days followed by superovulation with 1500 IU pregnant mares serum gonadotropin (PMSG) and 500 IU hCG (LALT); 3) gilts between 11 and 16 days of the estrous cycle received 17.6 mg ALT for 5 to 9 days and PMSG and hCG were used to induce superovulation (SALT); and 4) precocious ovulation was induced in prepubertal gilts with PMSG and hCG (PRE). A total of 505 DNA microinjected embryos transferred into 17 recipients produced 7 litters and 50 piglets, of which 8 were transgenic. The NAT sows had less (P < 0.05) ovarian activity than gilts synchronized and superovulated by all the other procedures. Synchronization treatments with PMSG did not differ (P > 0.05) in the number of corpora hemorrhagica or unovulated follicles, but SALT and PRE treaments had higher ovulation rates than LALT (24.7 +/- 2.9, 24.3 +/- 1.8 vs 11.6 +/- 2.7 ovulations; X +/- SEM). The SALT and PRE treatments yielded 12.3 +/- 2.6 and 17.7 +/- 1.7 zygotes. Successful transgenesis was accomplished with SALT and PRE procedures for estrus synchronization and superovulation.     

Plasma levels of oestradiol-17 beta in the pre-puberal heifer treated to induce superovulation

The plasma concentrations of oestradiol-17β have been measured by radioimmunoassay in pre-puberal calves following treatments used to induce superovulation (PMSG/HCG and PMSG/FGA/HCG). Before treatment, in almost all animals, the concentrations of oestradiol-17β were different from zero (2 to 8 pg/ml). The highest concentrations were measured around 130 h. after the beginning of treatment, before ovulation (150 to 2050 pg/ml). The curves showing the changes in hormonal levels have the same form as those of follicular growth measured using morphological criteria. The two hormonal treatments resulted in similar oestradiol-17β concentrations.     

Plasma concentrations of luteinizing hormone and progesterone during superovulation of dairy cows using follicle stimulating hormone or pregnant mare serum gonadotrophin

Eighteen lactating Holstein cows were randomly divided into three groups of equal size. Six cows were not superovulated; the remaining cows were superovulated using either FSH-P or PMSG beginning on Day 12 of the estrous cycle (day of ovulation = Day 0). Animals treated with FSH-P were injected intramuscularly (i.m.) with 4 mg FSH-P every 12 h for 5 d. PMSG was administered i.m. as a single injection of 2350 IU. Cloprostenol (PG, 500 ug) was injected i.m. 56 and 72 h after commencement of treatment and at the same time in the cycle of controls. All cows were inseminated 56, 68 and 80 h after the first PG injection. Blood samples (5 ml) were collected daily and every 15 min for a period of 9 h on Days -1, 0, 2, 8 and 10, with continuous blood sampling at 15-min intervals during Days 3 to 6. Ovulation rate was 27.7 +/- 8.22 in animals treated with PMSG, and 8.0 +/- 3.2 embryos per donor were recovered. In the FSH group, ovulation rate was 8.3 +/- 1.48 and 3.0 +/- 1.1 embryos per donor were recovered. Progesterone concentrations were similar in all three groups until the onset of the LH surge, when progesterone concentrations were greater (P<0.05) in animals of the PMSG group. After the preovulatory LH surge, concentrations of progesterone started increasing earlier (44 h) in cows treated with PMSG, followed by FSH-treated cows (76 h) and controls (99 h). The LH surge occurred earlier (P<0.05) in PMSG-treated cows (37 h after first PG treatment), than in animals treated with FSH-P (52 h) or controls (82 h). In animals treated with FSH-P, the magnitude of the preovulatory LH surge (24.2 +/- 1.02 ng/ml) was higher (P<0.05) than in the other two groups (PMSG = 17.1 +/- 2.04 ng/ml; control, 16.7 +/- 1.24 ng/ml). Superovulation with FSH-P or PMSG did not affect either mean basal LH concentration, frequency or amplitude of LH pulses during Days -1, 0, 2, 3, presurge periods, or Days 8 and 10 post-treatment. At ovariectomy, 8 d post-estrus, more follicles > 10 mm diam. were observed in the ovaries after treatment with PMSG (8.5 +/- 5.66) than after treatment with FSH-P (0.7 +/- 0.42) (P<0.05). Maximum concentrations of PMSG were measured 24 h after administration. Following this peak, PMSG levels declined with two slopes, with half-lives of 36 h and 370 h.     

Superovulation of immature rats by continuous infusion of follicle-stimulating hormone

Immature female rats were infused s.c. continuously over a 60-h period with partially purified porcine pituitary follicle-stimulating hormone (FSH) preparations differing in degree of purity and having widely divergent luteinizing hormone (LH):FSH potency ratios as defined by radioreceptor assays. Rats infused with the more purified FSH preparation (FSH-A) ovulated a mean of 60-85 oocytes per rat on the morning of the third day (Day 1) after FSH infusion was begun (on Day -2). The same total dose of FSH administered as a single s.c. injection or as twice daily injections over the same 60-h period resulted in ovulation in only a minority of treated rats (3/16), with none achieving ovulation rates approaching those of rats infused continuously. High fertilization rates (80% of ovulated oocytes) were observed in superovulated rats joined with fertile males on the evening of the second day of infusion (Day 0). Of the 67 +/- 7 fertilized ova per rat retrieved from oviducts flushed on Day 1, 52 +/- 8, or 80%, were accounted for as morulae or blastocysts recovered when oviducts and uteri were flushed on the morning of Day 5, demonstrating essentially normal developmental rates and high survival rates in reproductive tracts of superovulated females during the preimplantation period. Infusion of rats with the same dose of a less well-purified FSH preparation (FSH-E) containing 20 times as much LH activity, or injection of rats with a superovulatory dose of pregnant mare's serum gonadotropin (PMSG) (40 IU), were much less effective in causing superovulation, with ovulation rates of 17 +/- 6 and 34 +/- 8 oocytes/rat, respectively, compared to 79 +/- 9 oocytes/rat infused with the FSH preparation (FSH-A) containing lower LH activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

A histological study of corpora lutea from superovulated beef heifers

There is great variability between animals in the number of viable embryos produced following different superovulation regimens. It is not clear if all the follicles that ovulate produce healthy oocytes and form normal corpora lutea (CL) following superovulation. The objective of this study was to assess and compare CL from heifers undergoing three superovulatory regimes with CL from unstimulated heifers on the basis of morphology and morphometric analysis of luteal cells.Beef heifers were superovulated using either: (a) 24 mg porcine follicle stimulating hormone (pFSH) given twice daily over a 4 day period in decreasing doses commencing on day 10 of the oestrous cycle; (b) a single injection of 2000 IU pregnant mare serum gonadotrophin (PMSG) given on day 10 of the cycle; (c) as in (b) but followed by 2000 IU anti-PMSG (IgG to neutralise endogenous PMSG) at the time of the first insemination which was 12–18 h after the onset of oestrus (n = 33 per treatment). Luteolysis was induced 48 h after initial gonadotrophin administration and CL were collected on day 7 of the subsequent cycle and from ten unstimulated heifers (controls) at the same stage of the oestrous cycle. CL morphology was studied at light and electron microscopy levels. Morphometric analysis was performed on luteal cells. Subcellular morphology was similar in heifers from all groups. However, CL from superovulated heifers had more connective tissue than CL from control heifers; the connective tissue content of CL in the anti-PMSG-treated group was particularly marked. Both large and small luteal cells in the heifers receiving anti-PMSG had significantly smaller (P < 0.001) area and sphere volume than similar cells from CL of heifers in the other groups.     

孕马血清促性腺激素和氯地酚对猕猴超数排卵效果的观察

用孕马血清促性腺激素,总剂量为1550—2000单位,分4—7天处理猕猴,可促使其每侧卵巢出现滤泡超数发育,随后静脉注射入绒毛膜促性腺激素2500单位,在24小时内,猕猴即可出现超数排卵。     

Luteinizing hormone,progesterone and the morphological development of normal and superovulated corpora lutea in sheep

The development of granulosa-lutein cells was studied in 27 normal and 32 superovulated ewes between days 0-4(day 0 began with the preovulatory LH peak in normal animals and the HCG injection in superovulated ewes). The pattern of differentiation was similar in both groups. Following initial hormonal stimulation (0-12 hours after LH or HCG), granulosa cells were approximately 100 mu2 and contained small, pleomorphic nuclei with large amounts of clumped chromatin. Elongate cells lining the basement membrane possessed large, heterogeneous dense bodies, and a well-developed Golgi apparatus. Mitotic figures were observed up to 6 hours prior to ovulation. Sixteen to 20 hours following the LH surge or HCG injection, hypertrophy of granulosa cells was evident. Nuclei contained definitive nucleoli. Blood vessels in the theca interna were abundant and highly dilated. Ovulation occurred approximately 24 hours after the LH peak or HCG injection. Visible signs of luteinization were evident 6-12 hours after ovulation. A slight increase in serum progesterone levels was detected. The second post-ovulatory day was characterized by continuing hypertrophy of granulosa cells and extensive proliferation of smooth endoplasmic reticulum and mitochondria. Nuclei of granulosa cells were larger and possessed extremely large nucleoli. Numerous mitotic figures were apparent within the corpus luteum. Serum progesterone concentrations began increasing at 60-72 hours after hormone stimulation. By the end of the third post-ovulatory day, the corpus luteum consisted of large, pleomorphic, parenchymal cells, interspersed between capillaries and connective tissue elements. Only an occasional mitotic figure was apparent within the corpus luteum at 100 hours. Light microscopic autoradiography of 5, 10, and 15 day corpora lutea taken from ewes pulsed with 3H thymidine at specific times before and after ovulation revealed that granulosa cells did not undergo secondary mitoses following ovulation. In contrast, thecal, mesenchymal and endothelial cells did mitose on day 3.     

Rat embryo quality and production efficiency are dependent on gonadotrophin dose in superovulatory treatments

The present study was performed to optimize a superovulation protocol in rats in order to produce a large number of good-quality embryos suitable to develop rat embryonic stem (rES) cells. We first evaluated the ovulation kinetics of three rat strains: Wistar, Fisher and ACI/N. Animals (n=30 per strain) were treated with 50 IU of pregnant mare serum gonadotrophin (PMSG), and ovulation was induced with 50 IU of human chorionic gonadotrophin (hCG) 50 h apart. Next, we evaluated the dose-response curves of PMSG and hCG in Wistar rats in order to obtain the highest number of embryos. The parameters evaluated for superovulation efficiency were: percentage of mated females, percentage of pregnant females and the average number of embryos collected per female. The results of these experiments suggested that the best dose combination was 50 IU for each hormone. Subsequent experiments, again with Wistar rats, were designed to test which of four hormonal combination treatments (30/30, 30/50, 50/30, and 50/50 IU of PMSG/hCG) will produce the largest numbers of good-quality embryos. Embryo quality was evaluated by embryo development uniformity, embryo morphology, embryo survival in an in vitro culture and embryo ability to generate rES-like cells. Results from these experiments showed that 30/50 IU of PMSG/hCG was the treatment that induced the best embryo quality. In conclusion, our results indicated that, in Wistar rats, the most appropriate hormonal combination dose for superovulation protocols with high number of good-quality embryos was 30 IU of PMSG and 50 IU of hCG given 50 h apart. We are performing further studies with rES-like cells produced with the present methodology to evaluate if they are able to participate in the production of germ-line chimeras.     

Superovulatory responses of cattle

Non-histological examination of superovulated ovaries of cows does not allow one to distinguish between corpora lutea and luteinized follicles. A better estimation of ovulation rate could, therefore, be made from the number of embryos recovered or from the levels of E₂-17β in the plasma 60 hours after PMSG.For comparison of different treatments, it is necessary to characterize activities of the stimulatory agents used. Administration of an FSH - LH preparation twice a day at decreasing doses gives the best mean responses, but no treatment has been found which can clearly decrease the large variation between individuals in their responses.Numerical, kinetic and endocrine ovarian factors can partly explain the variability of ovarian responses to PMSG in the heifer. Individual differences in follicular populations at the time of treatment, or in E₂-17β levels after stimulation, could be related to differences in responses in ovulation rate. Normal follicles >1.7 mm diameter before treatment would usually ovulate following PMSG injection, whereas early atretic follicles of the same size mostly luteinize.     

Effect of rumen degradable bolus containing melatonin or progestagen pessary plus pregnant mare serum gonadotropin on estrus response and lambing rate in ewes

Two practical regimens designed to induce estrus and ovulation in ewes in late anestrus were compared. Forty ewes were given a soluble glass rumen bolus containing 150 mg melatonin on July 9 and were joined with two vasectomized rams on July 23 and with three fertile rams on August 6. A second group of 40 ewes was treated with an intravaginal progestagen pessary (60mg medroxy-progesterone acetate) on July 23. Following pessary removal after 12 d, ewes were given 750 IU of pregnant mare serum gonadotropin (PMSG). Five fertile rams were joined with these ewes 48 h after progestagen removal. Melatonin concentrations were determined in single blood samples collected in early afternoon of July 21. Mating dates, lambing dates and litter sizes were recorded. Date of mating was significantly later in ewes treated with melatonin compared with those treated with progestagen plus PMSG (P<0.0001). All ewes given melatonin were mated within 4 wk, and those on progestagen plus PMSG treatment within one day of fertile ram introduction. Thirty-four ewes (85%) allocated to melatonin treatment and 36 (90%) allocated to progestagen plus PMSG treatment lambed (P>0.05). Mean (+/-SEM) lambing date was later in melatonin-treated ewes (January 17+/-1.2 d) compared to those given progestagen plus PMSG (December 30+/-0.6 d; P<0.0001). Mean litter size was lower in melatonin-treated ewes (1.5+/-0.1) compared with those given progestagen plus PMSG (2.0+/-0.1; P<0.001). Plasma melatonin concentrations indicated that 9 of 40 ewes treated with melatonin had circulating melatonin concentrations of less than 16 pg/ml. It is concluded that under conditions that existed in this experiment, treatment with progestagen plus PMSG in late anestrus resulted in more synchronous mating and lambing and a higher litter size than that following administration of a soluble glass rumen-degradable bolus containing melatonin.     

Effect of pregnant mare's serum gonadotropin on increased ovulation in guinea pigs with synchronized estrous cycle

An ability of Pregnant Mare's Serum Gonadotropin (PMSG) to induce superovulation was investigated in guinea pigs with synchronized estrous cycle caused by the treatment for 21 days of progesterone tubing. On day 6 later following the removal of progesterone treatment, every animal given saline injection had synchronously ovulated. When compared with saline control, a significant increase of ova ovulated was induced by an injection of PMSG 8 hours before the removal of progesterone tubing, but not by the other PMSG treatment schedule. Present study indicates that PMSG injection given at a fixed stage of synchronized estrous cycle induced superovulation in guinea pigs treated with long-term implantation of progesterone tubing.     

Follicular activity and ovulation regulated by exogenous progestagen and PMSG in anestrous ewes

Follicular dynamics and ovulation were compared in 3 groups of anestrous ewes: those treated with medroxyprogesterone acetate (MAP) sponges for 12 d, then with 750 IU PMSG at the time of sponge removal (P4 + PMSG, n = 6), or PMSG alone (n = 6) and untreated controls (n = 6). Waves of follicular activity were observed in all the animals. In the P4 + PMSG treatment group, MAP priming permitted more ovulatory follicles (P < 0.001) to be recruited without changing follicle growth rate; MAP priming also delayed the time of ovulation (P < 0.001) and the time of the LH surge (P < 0.01), which allowed for an increase in the size of ovulatory follicles (P < 0.05). Ovulation also resulted in normal luteal function after P4 + PMSG (P < 0.01) but not after PMSG alone, since premature luteal regression occurred in 80% of the cases and was related to the presence of follicles > 4 mm when P4 levels were < 1 ng/mL on the day following ovulation. The results showed that MAP priming increased the ovulation rate by increasing the number of follicles that responded to PMSG.     

The effect of two different levels of progesterone priming on the response of ewes to superovulation

The use of either 1 or 3 controlled internal drug release (CIDR) devices for progesterone priming in ewes (n=11) superovulated with 1500 IU pregnant mare serum gonadotrophin (PMSG) at 28 hours prior to CIDR device withdrawal was investigated in relation to the stages of development and viability of the ova produced. Progesterone levels in the ewes (n=6) treated with 3 CIDR devices were significantly higher (P<0.01) during the 11 days of insertion than in those (n=5) treated with 1 CIDR device (7.3 vs 3.3 ng/ml) over the same period. However, following superovulation, the mean (+/-SEM) ovulation rates were similar for both groups (8.2 +/- 1.7 vs 10.2 +/- 1.5). The number of ova (M+/-SEM) recovered by laparoscopy 5 days after insemination was 4.2 +/- 1.0 for ewes treated with 3 CIDR devices and 7.0 +/- 1.1 for those treated with 1 CIDR device (P<0.10). The respective ovum recovery rates (M+/-SEM) were 55+/-9.8 and 74+/-13.2%. There was no effect of progesterone concentration in the priming phase on either the stages of development of the recovered ova or on their ability to develop during in vitro culture. It was concluded, therefore, that progesterone concentrations within the range 3.3 +/- 0.1 to 7.3 +/- 0.3 ng/ml during the priming phase and 2.4 +/- 0.3 to 6.5 +/- 0.2 ng/ml at the time of PMSG administration did not affect the ovulation rate or the viability of ova recovered from superovulated ewes.