The effect of estradiol valerate on follicular dynamics and superovulatory response in cows with Syncro-Mate-B implants

Two experiments were designed to evaluate the effect of estradiol valerate on follicular dynamics and superovulatory response in cows with Syncro-Mate-B (SMB)implants. In Experiment 1, 5 mg estradiol valerate (E(2)), injected at the same time as superstimulation treatments were initiated, resulted in fewer corpora lutea (CL), ova/embryos collected and fertilized ova (P<0.05) than if E(2) was administered with the SMB implant 7 days earlier. In Experiment 2, 31 beef cows and 26 Holstein cows were placed in one of four treatment groups. Group I (control) cows were superstimulated on Day 9 (estrus=Day 0). On Day 2, cows in Groups II, III, and IV received SMB and cows in Group III received E(2). On Day 9, cows in Group IV received E(2), and all cows were superstimulated with Folltropin. The number of CL did not differ (P>0.19) among groups. However, there were more follicles < 10 mm and fewer fertilized ova and transferable embryos (P<0.02) in Group IV cows. Ovarian ultrasonography revealed that the diameter of the largest follicle in Group III cows declined from Day 2 to Day 7 and subsequently increased until Day 13. In contrast, Groups I, II and IV were characterized by apparently linear growth between Days 2 and 13. Differences (P<0.05) were detected between Days 5 and 9. Mean diameter of the largest follicle was smaller for cows in Group III than for the remaining groups on Day 9. It was concluded that SMB did not adversely affect superovulatory response and that E(2) administration resulted in atresia of the antral follicles in the cows with SMB implants.     

Effect of frequency of follicle aspiration on oocyte yield and subsequent superovulatory response in cattle

The effect of frequency of transvaginal follicular aspiration on oocyte yield and subsequent superovulatory response was studied in 2 experiments. In Experiment 1, 32 primiparous Hereford x Friesian cows were assigned to 4 treatments (n = 8 per treatment). Oocyte recovery was carried out once a week for 12, 8, 4 or 0 (control) wk. Embryo recovery for all animals was 7 wk after the completion of the aspiration schedules. In Experiment 2, the effects of oocyte recovery once or twice a week (n = 8 per treatment; control n = 18) for 12 wk and response to superovulation 4 wk after the last aspiration were compared using nulliparous purebred Simmental heifers. Increasing the period of once weekly aspirations from 4 to 12 wk (Experiment 1) did not affect the number of follicles observed per session (mean +/- SEM; 10.0 +/- 0.82) or aspirated (7.8 +/- 0.71), but the recovery rate of oocytes from follicles aspirated was greater for donors aspirated for either 4 or 8 wk than for 12 wk (32.3 +/- 3.73 vs 28.4 +/- 2.61 vs 20.1 +/- 2.13 %; P < 0.05). Following the last aspiration and prior to commencing superovulatory procedures, estrus or estrous activity was observed in 7 8 , 8 8 , 7 8 and 6 8 of the animals aspirated over 12, 8, 4 or 0 wk, respectively. Subsequent superovulatory responses and in vivo embryo recoveries were similar for all aspiration treatments and for control animals. Changing the frequency of oocyte recovery from once to twice weekly (Experiment 2) did not affect the numbers of follicles observed (9.1 +/- 0.63 vs 8.3 +/- 0.85), follicles aspirated (5.9 +/- 0.56 vs 6.2 +/- 0.69), oocytes recovered (1.7 +/- 0.27 vs 1.9 +/- 2.0) per session or the oocyte recovery rate (29.4 +/- 2.4 vs 30.4 +/- 2.4 %); nor was there any effect of frequency of aspiration on subsequent superovulatory response and embryo recovery. In conclusion, increasing the period of aspiration from 4 to 12 wk and the frequency from once to twice a week over 12 wk did not reduce the number of follicles observed or aspirated, or number of oocytes recovered per donor per session. Subsequent estrous cyclicity and responses to superovulation were unaffected by the periods or frequencies of oocyte recovery examined here.     

Effect of treatment with estradiol valerate on endocrine changes and ovarian follicle populations in dairy cows

A linear-array ultrasound instrument was used to monitor the dynamics of follicular cyst formation following estradiol valerate (EV) administration in postpartum dairy cattle. Twelve cyclic cows were given two intramuscular (i.m.) injections of prostaglandin and F(2alpha) (PGF(2alpha)) 12 d apart to synchronize estrus. On Day 16 (Day 0 = day of estrus) six cows received 10 mg of EV in 1 ml sesame oil; the remaining six cows were treated with 1 ml sesame oil. The ovaries of all cows were scanned rectally each morning from Day 9 until 14 or 30 d post treatment. Plasma concentrations of luteinizing hormone (LH) and progesterone (P(4)) were also determined as objective indices of treatment effects. Day 0 to 16 ultrasound pictures of the ovaries of both control and treated cows were characterized by the presence of a corpus luteum (CL; 19 to 38 mm), several small follicles (<5 mm) and a medium-sized follicle (6 to 28 mm). Following treatment in control cows, the CL regressed gradually, and a preovulatory follicle was identifiable by Day 17 to 18, it increased in size and reached a maximum of 28 to 30 mm by Day 20 after ovulation and was identifiable throughout the rest of the cycle. Administration of 0 mg of EV resulted in a rapid reduction in the size of the CL. Growth of a large follicle was observed in all treated animals around Days 16 to 20, but having reached a maximum diameter of 12 to 24 mm it regressed without resulting in ovulation. Subsequent ultrasound pictures of EV-treated cows were characterized by the absence of a new CL and the presence of medium-sized persistent follicles. Estradiol valerate treatment induced early luteolysis (43 +/- 05 h post EV vs 101 +/- 22 h) and an LH surge (41 +/- 11 h vs 125 +/- 17 h).     

Effect of progesterone administration on the ovarian response to superovulatory treatments in cattle

To evaluate ovarian response in Angus cows previously treated with progesterone (P4), animals were randomly assigned to two groups: T600 group (n=14), 600 mg of P4/day. P4 was injected from days 3 to 7 of the estrous cycle. On day 7, superovulatory treatments began. The control group (n=12) was given vehicle only. The superovulatory treatments in the control group began on days 7-9 of the estrous cycle. The superovulatory total treatment dose of 400mg NIH FSH P1 was given twice a day over a 4-day period. Ultrasonography of the ovaries was conducted 3 days preceding the initiation of superovulatory treatment, every 24h. In both groups, an additional ultrasonographic evaluation was made at 24h after the end of superovulatory treatment. Blood samples were collected 4 days preceding the initiation of superovulatory treatment, every 24h. Additional samples were taken from the P600 group for 12 day after of initiation of superovulatory treatment every 24h, except on the fifth day after the initiation of superovulatory treatment. In the P600 group, P4 concentrations were greater than in the control group (P<0.01) and remained over 1 ng/ml up to day 11 after beginning of superovulatory treatment. The diameter of the dominant follicle was larger in the animals of the control group (P<0.01). Cows of the P600 group had a greater number of Class I (3-4mm) follicles (P<0.01). A significant day and treatment effect (P<0.01) were observed in Class II (5-9 mm) follicles. Effects due to treatment on the number of Class III follicles (P<0.05) were observed. In the P600 group, no estrous post-superovulatory was observed and there were no ovulations that occurred. Conversely, 100% of the cows of the control group showed estrous. In the P600 group, there were a greater number of Class III follicles (P<0.01) and a lesser number of Class II follicles (P<0.05) at 24h after the end of superovulatory. In the control group, 66.7% of the cows responded to superovulatory treatments. In conclusion, the daily administration of 600 mg of P4, from days 3 to 7 of the estrous cycle, produces an increase of plasma concentrations of this hormone from day 4, resulting in changes in follicular dynamics (absence of follicles greater than 10mm of diameter and an increase of the population of Class I follicles). As to the ovarian stimulation using Folltropin V in animals receiving a daily injection of 600 mg of P4 from days 3 to 7 of the estrous cycle, a greater population of follicles>or=10mm developed by 24h after superovulatory treatments were completed.     

Gonadotropic and ovarian hormone response in dairy cows treated with norgestomet and estradiol valerate

Injection of estradiol valerate in conjunction with receiving a norgestomet ear implant (Syncro-Mate-B) reduced plasma progesterone (P<.001) and FSH (P<.02) and increased estradiol (P<.01) in postpartum cows during the treatment period. Occurrence of LH and FSH peaks (P<.05) varied between 12 and 48 hr follwing removal of SMB implants and estrous behavior was minimal. FSH was strongly correlated to LH and was inversely related to progesterone in untreated cows and to estradiol in treated cattle. Syncro-Mate-B suppressed luteal activity and peak gonadotropin release during treatment and elicited variable endocrine and behavioral response following treatment.     

Association between numbers of ovarian follicles in the first follicle wave and superovulatory response in ewes

The aim of this study was to examine the variability in the number of ovarian follicles in sheep and to determine if the average number of follicles per day influences the response to superovulation and resulting embryo quality. Ewes (n = 83) were synchronized and the number of follicles (≥2 mm diameter) in the ovaries were counted daily between Days 0 and 4 of the oestrous cycle using transrectal ultrasonography. Fourteen to 21 days later, 47 ewes were randomly chosen from the group and were treated with an intravaginal progestagen pessary for 12 days and superovulated with 1500 IU eCG administered as a single injection 10 days after sponge insertion. Ewes were mated and reproductive tracts were recovered after slaughter on Day 6 of pregnancy. The number of corpora lutea was counted, uterine horns were flushed and the morphology and developmental stage of the recovered oocytes/embryos was assessed. The mean daily number (±S.D.) (≥2 mm diameter) of follicles per ewe was 8.5 ± 2.8 (ranging between 3 and 16). After superovulation animals with few follicles (Low group: <8 follicles/day; n = 21) had fewer (P < 0.005) corpora lutea, total structures (unfertilized oocytes and embryos), good quality and total embryos compared to animals with many follicles (High group: ≥8 follicles/day; n = 23). No difference was found in the proportion of good quality embryos (relative to the total number; Low 0.68 ± 0.11 versus High 0.79 ± 0.08; P = 0.21) between the two groups, or the recovery rate, the number of unfertilized oocytes or the number of poor quality embryos per animal. We conclude that ewes with a higher number of follicles (≥8) during the first follicular wave had a better superovulatory response (in terms of corpora lutea and high quality embryos) 2–3 weeks later; however, there was no relationship between the number of follicles and the proportion of good quality embryos per animal.     

Follicular dynamics and superovulatory response in heifers

The study examined whether the response of heifers to exogenous gonadotrophin superovulatory treatment could be predicted from a knowledge of previous antral follicular dynamics. During a pretreatment monitoring phase, of 24 normal oestrous cycles (20.1 ± 0.33 days long) observed in 17 heifers, one, 15 and seven cycles showed one, two and three antral follicular waves respectively, as measured by ultrasonography. The subsequent ovulatory response (number of corpora lutea) to ovine FSH stimulation, after a CIDR-B/oestradiol benzoate/prostaglandin analogue cycle synchronisation regime, was not correlated with either oestrous cycle length or follicle wave number during the monitoring phase or with the number of follicles observed at the start of FSH treatment, but was related to the number of follicles observed during the monitoring phase (r = 0.47, P < 0.05). In conclusion, the present results show that the outcome of FSH superovulatory stimulation in heifers cannot be predicted from a knowledge of prior follicular dynamics.     

Improved superovulatory response in beef cattle following ovarian follicular ablation using a simplified transvaginal device

The influence of the timing for the ablation of dominant follicle(s) prior to superovulatory treatment, and its effect on ovarian follicular growth and embryo yield, still remain elusive in cattle. The present study was designed to evaluate the effects of: (1) the day of the estrous cycle, at mid-diestrus, for the onset of superstimulation of follicular development, (2) the presence or absence of large ovarian follicles (ovary status) and (3) the time of follicular ablation, in hours, prior to the superovulatory treatment, on the superovulatory response in cattle. From a total of 244 superovulatory treatments and embryo collections in nulliparous and multiparous females, 76 were conducted after follicular ablation using a simplified transvaginal puncture cannula. Results from the present study indicated that the presence of large palpable follicle(s) at the onset of superstimulation of follicular development markedly reduced the superovulatory response. In addition, follicular ablation at 0 h or at 24 h prior to the onset of the superstimulation treatment significantly increased the number of total viable embryos. However, superovulatory responses were not affected by the day of the estrous cycle for the onset of follicular superstimulation and by the animal category (heifers or cows). In conclusion, the ablation of palpable follicle(s) 24 h or immediately prior to the onset of gonadotropin treatment, from days 8 to 12 of the estrous cycle (day 0, behavioral estrus), increased the total number of transferable embryos per flushing in cattle.     

Effect of estradiol valerate on ovarian follicles, emergence of follicular waves and circulating gonadotropins in heifers

An experiment was designed to examine the effect of estradiol valerate (EV) on the growth and regression of follicles of a wave and on the emergence of the next follicular wave. Twenty-six beef heifers were xamined daily by ultrasonography and randomly allocated to 1 of 4 treatment groups at the time of ovulation (Day 0): unterated control heifers and those that received 5 mg EV intramuscularly on Day 1, Day 3 or Day 6. Maximum diameter of the dominant follicle was greater (P<0.05) in control heifers than in heifers treated on Day 1 or Day 3. Mean day of onset of regression of the dominant follicle was later (P<0.05) in control heifers than in heifers treated on Day 1 but was not different from heifers treated on Day 3. In heifers treated on Day 6, cessation of growth, maximum diameter and onset of regression were not different from that of control heifers. The emergence of the next follicular wave was earlier (P<0.05) in heifers treated on Day 1 than in control heifers, whereas wave emergence was delayed (P<0.05) in heifers treated on Day 3 or Day 6. The mean day of maximum concentration of FSH prior to the emergence of the next wave was earlier in heifers treated with EV on Day 1 and later in heifers treated on Day 3 or Day 6 compared with that of the controls (P<0.05). Treatment on Day 1 or Day 3 resulted in a significant LH surge in 8 13 heifers, whereas no LH surges were detected in control heifers or in heifers treated on Day 6. The hypothesis that EV suppresses the growth of the dominant follicle, was supported. Estradiol valerate treatment resulted in early emergence of the next follicular wave in heifers treated on Day 1, but treatment on Day 3 or Day 6 resulted in delayed emergence of the next follicular wave.     

Effect of progestogen plus estradiol-17beta treatment on superovulatory response in beef cattle

A series of 3 experiments were conducted to evaluate superovulatory response following exogenously controlled follicular wave emergence in cattle. In Experiment 1 the hypothesis was tested that treatments with progestogen plus estradiol-17beta (E-17beta) would result in the emergence of a wave of ovarian follicles that are as responsive to exogenous gonadotropins as those of a spontaneous follicular wave. Beef cows and heifers either received a progestogen ear implant on Day 0 (ovulation) plus 5 mg im E-17beta on Day 1 and were superstimulated on Day 5, or did not receive implants but were superstimulated on Day 8 (expected day of emergence of the second follicular wave). The cattle received 400 mg NIH-FSH-P1 of Folltropin-V, given in a single subcutaneous injection or twice daily as intramuscular injections over 4 d. No significant differences were detected between the 2 groups in the number of corpora lutea (CL), ova/embryos collected, fertilized ova and transferable embryos. In Experiment 2 superstimulatory responses to a single subcutaneous injection of Folltropin-V were compared between heifers in which follicle wave emergence was synchronized with progestogen plus E-17beta at unknown stages of the estrous cycle with those treated following a conventional method of superstimulation at middiestrus. Superstimulation 4 d after E-17beta treatment in heifers with progestogen implants resulted in a similar superovulatory response and higher fertilization rates than those initiated 8 to 12 d after estrus. In Experiment 3 the ovarian response to a single- versus multiple-injection superstimulatory treatment protocol was compared in heifers given progestogen plus E-17beta to induce synchronous wave emergence. The number of CL, ova/embryos collected, fertilized ova and viable embryos were not different between groups. Superstimulatory treatments initiated 4 d after E-17beta treatment of cattle with progestogen implants resulted in comparable ovulatory responses to treatments initiated at the time of spontaneous wave emergence or during middiestrus. Synchronizing wave emergence in a group of randomly cycling cattle obviated the need of estrus detection and synchronization prior to superstimulation.     

Preovulatory evaluation of the superovulatory response in donor cattle

Dairy cows and heifers (n = 134) were induced to superovulate with exogenous gonadotrophins. In 103 animals, peripheral plasma concentrations of progesterone (P4) and luteinizing hormone (LH) were measured during the preovulatory period. On the basis of these measurements, normal and deviating profiles of P4 and LH were defined. A high degree of correlation existed between the normality of the two profiles; when the P4 profile was normal, the probability for the LH profile also to be normal was greater than 10:1. This relationship was utilized to evaluate donors based on four preovulatory measurements of P4. When used on 31 animals used for collection of eggs, a superior superovulatory response was encountered in animals with normal vs deviating P4 profiles (eggs recovered: 7.2 +/- 1.1 vs 0.5 +/- 0.3, P < 0.001; transferable embryos: 4.4 +/- 0.9 vs 0.3 +/- 0.2, P < 0.01). It is concluded that evaluation of donors by measurements of progesterone in plasma at four preovulatory sampling points allows for the early exclusion of donors with inferior embryo yield.     

Effect of time and dose of recombinant follicle stimulating hormone agonist on the superovulatory response of sheep

The objective of this study was to determine the superovulatory potential of a single-chain analog of human FSH (Fcα) when administered to ewes either 3 days before, or coincident with, simulated luteolysis (pessary removal [PR]). A total of 40 animals were randomly assigned to receive Fcα at doses of 0.62, 1.25, or 2.5 IU/kg of body weight (bwt) 3 days before PR or 0.31, 0.62, 1.25, or 2.5 IU/kg of bwt at PR. Control ewes received protein without FSH activity. Blood samples were collected during the periovulatory period and ovarian tissue was collected 11 days after PR. Ovulation rate did not differ from the control group in ewes receiving the smallest doses of Fcα (0.31 and 0.62 IU/kg). However, a significant superovulatory response was noted in sheep receiving Fcα at doses of 1.25 and 2.5 IU/kg and this response was comparable in animals receiving the largest dose levels of Fcα at, or 3 days before, PR. The interval between PR and the LH surge was significantly extended and the LH surges were less synchronous in animals receiving Fcα at PR when compared with animals receiving the potent FSH agonist 3 days before PR. Taken together, these data indicate that the human single-chain gonadotropin with FSH activity promotes superovulation in ewe lambs in the breeding season. A single injection of the recombinant gonadotropin 3 days before luteolysis synchronizes the LH surge. The use of the single-chain analog of FSH in assisted reproduction for domestic animals is likely to be of practical significance as an alternative to conventional gonadotropins in superovulation protocols in livestock species.     

Ultrasonography and endocrinology of ovarian dysfunctions induced in heifers with estradiol valerate

This study monitored the long-term follicular dynamics and changes in ovarian steroid hormones associated with an experimental model of cystic ovarian degeneration (COD) in the heifer. In the treated group (n = 7), Holstein heifers received a single injection of 500 microg of cloprostenol (prostaglandin F2a, PG) and 5 mg of estradiol valerate (EV) on either Day 17, 18 or 19 of the estrous cycle. The control group (n = 7) received only PG. Transrectal ultrasound was performed daily, beginning 8 to 10 d before injection and continuing until a return to normal cyclicity (40 to 74 d). Blood samples were taken twice daily over the same period. The EV disrupted the normal follicular development as well as the plasma progesterone and estradiol profiles of 6/7 heifers in the treated group. Two different types of responses were observed. The Type-I response (n = 2) was characterized by a premature ovulation followed by a corpus luteum (CL) which persisted for over 30 d. The Type-II response (n = 4) was characterized by anovulation followed by the emergence of a large ovarian structure which could further be subtyped. In Type- IIA (n = 2), this follicle ovulated at an exaggerated size of 19 or 24 mm (mean diameter of controls: 13.4 +/- 2.7 mm). The subsequent cavernous CL was very large at 35 and 37 mm (mean diameter of CL in controls: 23.8 +/- 2.0 mm). In Type- IIB (n = 1), the follicle present at the time of injection continued to grow and became a luteinized cyst. In Type-IIC (n = 1), several waves of follicular cysts developed and persisted for 52 d. This study suggests that EV induces a range of ovarian dysfunctions including different forms of COD. The individual differences in the stage of folliculogenesis at the time of injection of EV may be responsible for the different types of responses.     

Effect of presence of a dominant follicle on the superovulatory response in buffalo (Bubalus bubalis)

Ten buffalo were superovulated by administration of 8 doses of FSH in a descending schedule spread over 4 d (5.5/5.5, 4.5/4.5, 3.5/3.5 and 2.5/2.5 mL, i.m.; total dose of 64 AU in 32 mL) beginning on Day 10 of an unstimulated estrous cycle, and 30 and 20 mg Lutalyse was given alongwith the 5th and 6th injections of FSH, respectively, to induce luteolysis. The number of corpora lutea (CL) was determined on 6 d post estrus. The ovaries were examined daily by ultrasonography from Day -5 to Day 5 (Day 0 = day of start of superovulation). The animals were retrospectively classified into 2 groups depending upon the presence (n = 4) or absence of a dominant follicle (n = 6). The mean diameter of the largest follicle (F1) increased from 8.25 +/- 0.48 mm on Day -5 to 10.75 +/- 0.25 mm on Day 0 in the dominant group, whereas in the nondominant group the F1 follicle exhibited a progressive decrease from 9.00 +/- 0.45 mm to 7.00 +/- 0.65 mm during the same period, the difference in profiles between the 2 groups was significant (P = 0.042). The profile of the diameter of the second largest follicle (F2) and the difference in diameters between largest and second largest follicles (F1-F2) were not significantly different between the 2 groups. The profile of mean number of large (> or = 10 mm diameter), but not small (2 to 5 mm diameter) or medium (6 to 9 mm diameter) follicles differed significantly (P = 0.001) between the 2 groups from Day -5 to Day 5 (P = 0.030). The number of CL was not significantly different between nondominant (4.00 +/- 0.97) and dominant groups (3.25 +/- 1.31). The number of CL was positively correlated (P < 0.01) with the number of medium follicles and the total number of follicles on the day of initiation of superovulation, but not with follicles of any size category or total number of follicles on any previous day. The results of this study indicate that following the use of morphological criteria based on the size of the largest follicle alone, the superovulation response is not affected by the presence of a dominant follicle at the initiation of superovulation in buffalo.     

Development of persistent ovarian follicles during synchronization of estrus influences the superovulatory response to FSH treatment in cattle

The synchronization of estrus with synthetic progestins or progesterone (P(4)) results in the development of a large, persistent ovarian follicle. The objectives of the present study were to determine if development of a persistent ovarian follicle during synchronization of estrus suppresses recruitment of additional follicles during FSH treatment. On Day 5 of the estrous cycle (estrus = Day 0), beef cows were treated with 0.5 or 2.0 P(4) releasing intravaginal devices (PRIDs) for 8 d (Experiment 1, n = 20), 5 or 2 d (Experiment 2, n = 44) before initiation of FSH treatment. Prostaglandin F(2alpha) (25 mg) was administered on Days 5 and 6. Superovulation was induced with 24 mg of recombinant bovine FSH (rbFSH, Experiment 1) or 28 mg of FSH-P (Experiment 2) over a 3- or 4-d period, respectively. The PRIDs were removed concurrently with the 5th injection of rbFSH or FSH-P. There was a treatment-by-day interaction (P < 0.001) for the concentration of 17beta-estradiol in cows treated for 8, 5 or 2 d before FSH treatment. In Experiment 1, FSH treatment initiated 8 d after insertion of a 0.5 PRID did not affect the number of CL (6.9 +/- 1.4 vs 6.7 +/- 1.6), ova/embryos (3.7 +/-1.3 vs 3.0 +/- 1.3) and transferable embryos (2.4 +/- 0.9 vs 3.0 +/- 0.9) compared with that of the 2.0 PRIDs. In Experiment 2, FSH treatment initiated 5 d after insertion of a 0.5 PRID decreased the number of CL (4.0 +/- 0.5 vs 8.3 +/- 0.8; P < 0.001), ova/embryos (3.0 +/- 0.6 vs 5.9 +/- 1.2; P < 0.03) and transferable embryos (2.3 +/- 0.6 vs 5.1 +/- 1.0; P < 0.03) compared with that of a 2.0 PRID, respectively. Initiation of FSH treatment 2 d after insertion of a 0.5 PRID compared with a 2.0 PRID had no affect on the number of CL (8.0 +/- 2.1 vs 8.7 +/- 1.2), total ova (4.8 +/- 1.4 vs 6.9 +/- 1.4) and transferable embryos (2.9 +/- 1.2 vs 6.1 +/- 1.7). In conclusion, treatment with low doses of P(4) (0.5 PRID) for 5 d but not for 2 or 8 d before initiation of FSH treatment results in the development of a dominant ovarian follicle, which reduces recruitment of ovarian follicles, and the number of CL, total ova and transferable embryos.     

Selection of the dominant follicle in cattle: role of estradiol

Involvement of estradiol in the deviation in growth rates between the two largest follicles of a wave was studied in 39 heifers. In experiment 1, the largest follicle remained intact in a control group and was ablated in five estradiol-treated groups when the largest follicle reached 8.5 mm or larger (expected beginning of deviation; Hour 0). The ablation groups were given a single injection of 0, 0.004, 0.02, 0.1, or 0.5 mg of estradiol. Blood samples were taken from a jugular vein every hour at Hours 0 to 16. By Hour 8, FSH concentrations were greater (P < 0.05) in the ablation group that received 0 mg of estradiol than in the controls. Among the estradiol groups, that receiving 0.02 mg had the lowest detectable increase in estradiol. In this group, FSH concentrations were not suppressed below the control concentrations, but the increase in FSH concentrations following ablation of the largest follicle was delayed for 2 or 3 h. This delay in the increase of FSH concentrations corresponded to the hours that estradiol was maximal. In experiment 2, blood samples were taken every 4 h from the caudal vena cava cranial to the junction with the ovarian veins in heifers with the largest follicle intact (controls) or ablated at 8.5 mm or larger (Hour 0). Averaged over Hours 4 to 48, estradiol concentrations were higher (P < 0.04) in the controls than in the ablation group. During Hours 0 to 12, estradiol concentrations increased (P < 0.05) in the controls, whereas FSH concentrations decreased (P < 0.05). In the ablation group, estradiol concentrations were lower than in the controls by Hour 4, and FSH concentrations increased (P < 0.05) between Hours 4 and 12. These results support the hypothesis that the largest follicle releases increased estradiol into the blood at the beginning of follicular deviation, and that the released estradiol is involved in the continuing depression of FSH concentrations to below the requirement of the smaller follicles.     

Endocrine regulation of ovarian antral follicle development in cattle

Antral follicle growth in cattle occurs in two distinct phases; the first 'slow' growth phase spans the time from antrum acquisition to a size of approximately 3 mm detectable by transrectal ultrasound, and the second 'fast' phase is gondadotrophin-dependent and includes cohort growth, dominant follicle (DF) selection, and DF growth. This review summarises current concepts of the relative roles FSH and LH, ovarian and metabolic hormones play mainly in the second phase of antral follicle growth in animals of different reproductive and nutritional states. It is proposed that differential FSH response may enable one cohort follicle to become selected, and that follicular secretions, particularly inhibin, suppress FSH and thus are responsible for DF selection and dominance. Acute dependence of the DF on LH pulses will determine DF lifespan, and the LH pulse profile can be influenced by metabolic hormones such as leptin, providing one possible link for nutritional state and reproduction. Direct ovarian effects of acute and chronic changes in growth hormone, insulin and insulin-like growth factor (IGF)-I have been described on cohort follicles, DF oestrogen activity and on DF growth. Influences of metabolic hormones on early antral follicles undergoing their first 'slow' growth phase are less well described, yet metabolic hormones appear to enhance growth into the cohort available for FSH-induced emergence, and may influence subsequent developmental competence of oocytes.     

The effects of FSH-priming and dominant follicular regression on the superovulatory response of cattle

Thirty superovulatory treatments were administered to 19 mixed-breed, nonlactating cows. In 10 superovulatory treatments, the cows were primed with follicle stimulating hormone (FSH) on the second and third day of the estrous cycle, and in another 10 superovulatory treatments, the cows received no priming dosage of FSH. Initiation of the superovulatory treatments in both groups was determined by ultrasonically monitoring for regression of the dominant anovulatory follicle. Still another 10 superovulatory treatments were begun on Day 10 without regard for regression of the dominant anovulatory follicle and without a priming dosage of FSH. The mean days for starting the superovulatory treatment in the FSH-primed cows, in the nonprimed cows and in the controls were 10.5, 11.9 and 10 days, respectively. All cows were treated with eight injections of FSH at 12-hour intervals in a declining dosage (36 mg total). Cows were bred naturally and embryos collected nonsurgically seven days later. There was no significant difference (P>0.05) between the total number of embryos or transferable embryos in the three treatment groups. In this study neither priming on Days 2 or 3 nor initiating the superovulatory treatment, based on the morphologic regression of the dominant anovulatory follicle, was an effective means for improving the superovulatory response in cattle.