norgestomet and estradiol-3-benzoate

The present study evaluated the effect of the type of norgestomet ear implant (new vs. used) on the ovarian follicular response (experiment 1) and pregnancy per artificial insemination (AI) (P/AI; experiment 2) of beef heifers subjected to an estradiol plus progestin timed artificial insemination (TAI) program. In experiment 1, 57 cyclic beef heifers were randomly assigned to one of two groups according to the type (new or previously used for 9 days) of norgestomet ear (NORG) implant. At the time of NORG implant insertion, the heifers were treated with 2 mg of intramuscular estradiol benzoate. Eight days later, the NORG implants were removed, and the heifers received an intramuscular administration of 150 μg of d-cloprostenol, 300 IU of equine chorionic gonadotropin, and 0.5 mg of estradiol cypionate. The heifers had their ovaries scanned every 12 hours from the time of NORG implant removal to 96 hours after verifying the occurrence and timing of ovulation. No difference (P = 0.89) was observed in the ovulation rates between the two treatments (new = 80.0%; 24/30 vs. used = 81.5%; 22/27). However, the heifers treated with a used NORG implant had (P = 0.04) higher proportion (36.4%; 8/22) of early ovulation (between 36 and 48 hours after NORG implant removal) compared with the heifers treated with a new NORG implant (8.3%; 2/24). In experiment 2, at the beginning of the synchronization protocol, 416 beef heifers were randomly assigned into two groups, as described in the experiment 1. Two days after the NORG implant removal, the heifers were reassigned to be inseminated at 48 or 54 hours after NORG implant removal. There was an interaction (P = 0.03) between the type of NORG implant and the timing of TAI on P/AI. The timing of insemination only had an effect (P = 0.02) on the P/AI when the heifers were treated with a used NORG implant [(TAI 54 hours = 41.9% (44/105) vs. TAI 48 hours = 58.6% (58/99)]. In conclusion, beef heifers synchronized with a used NORG implant plus estradiol exhibited a higher proportion of earlier ovulations, and TAI in these heifers should be performed 48 hours after removal of used NORG implants.

Topics: Animals; Cattle; Drug Administration Schedule; Drug Implants; Ear; Estradiol; Estrus Synchronization; Female; Gonadotropins, Equine; Insemination, Artificial; Ovulation Induction; Pregnancy; Pregnancy Rate; Pregnenediones

Two experiments evaluated the effects of timing of the induction of ovulation in superstimulated lactating Holstein donor cows that were fixed-time artificially inseminated. Secondary objectives were to evaluate the effects of the timing of progesterone (P4) device removal (Experiment 1) or the addition of a second norgestomet implant (Experiment 2) during superstimulation. In Experiment 1, 12 cows were allocated to one of four treatment groups with the timing of P4 device removal (24 or 36 h) and pLH treatment (48 or 60 h), after the first PGF as main factors, in a Latin Square (cross-over) design. There was an interaction (P = 0.03) between time of P4 device removal and time of pLH treatment. Mean (± SEM) numbers of transferable embryos were higher when the P4 device was removed at 36 h and pLH was administered at 60 h after the first PGF (P36LH60 =6.3 ± 1.4) compared to other treatments (P24LH60 =3.7 ± 1.1; P24LH48 =2.4 ± 0.8; or P36LH48 =2.2 ± 0.7). In Experiment 2, 40 cows were randomly allocated into one of four treatments with the number of norgestomet implants (one or two) and the time of induction of ovulation with GnRH relative to the first PGF (48 vs. 60 h) as main effects. The mean number of transferable embryos was higher (P = 0.02) when GnRH was administered at 60 h (4.2 ± 1.3) compared to at 48 h (2.7 ± 0.8), and the number of freezable embryos was increased (P = 0.01) in cows receiving two (3.0 ± 1.0) rather than one norgestomet implant (1.5 ± 0.5). In summary, embryo production in lactating Holstein cows was increased when the ovulatory stimulus (pLH or GnRH) was given 60 h after the first PGF, particularly when the P4 device was removed 36 h after the first PGF and when two norgestomet ear implants were used during the superstimulation protocol.

Topics: Animals; Cattle; Cross-Over Studies; Dairying; Drug Administration Schedule; Estradiol; Female; Fertility Agents, Female; Follicle Stimulating Hormone; Gonadotropin-Releasing Hormone; Insemination, Artificial; Lactation; Ovulation Induction; Pregnenediones; Superovulation

Aiming to achieve the ideal time of ovum pick-up (OPU) for in vitro embryo production (IVP) in crossbred heifers, two Latin square design studies investigated the effect of ovarian follicular wave synchronization with estradiol benzoate (EB) and progestins. For each experiment, crossbred heifers stage of estrous cycle was synchronized either with a norgestomet ear implant (Experiment 1) or a progesterone intravaginal device (Experiment 2) for 7d, followed by the administration of 150microg d-cloprostenol. On Day 7, all follicles >3mm in diameter were aspirated and implants/devices were replaced by new ones. Afterwards, implant/device replacement was conducted every 14d. Each experiment had three treatment groups. In Experiment 1 (n=12), heifers in Group 2X had their follicles aspirated twice a week and those in Groups 1X and 1X-EB were submitted to OPU once a week for a period of 28d. Heifers from Group 1X-EB also received 2mg EB i.m. immediately after each OPU session. In Experiment 2 (n=11), animals from Group 0EB did not receive EB while heifers in Groups 2EB and 5EB received 2 and 5mg of EB respectively, immediately after OPU. The OPU sessions were performed once weekly for 28d. Therefore, in both experiments, four OPU sessions were performed in heifers aspirated once a week and in Experiment 1, eight OPU sessions were done in heifers aspirated twice a week. Additionally, during the 7-d period following follicular aspiration, ovarian ultrasonography examinations were conducted to measure diameter of the largest follicle and blood samples were collected for FSH quantification by RIA. In Experiment 1, all viable oocytes recovered were in vitro matured and fertilized. Results indicated that while progestin and EB altered follicular wave patterns, this treatment did not prevent establishment of follicular dominance on the ovaries of heifers during OPU at 7-d intervals. Furthermore, the proposed stage of follicular wave synchronization strategies did not improve the number and quality of the recovered oocytes, or the number of in vitro produced embryos.

Topics: Animals; Cattle; Cell Survival; Cells, Cultured; Cleavage Stage, Ovum; Dinoprost; Drug Implants; Embryo Culture Techniques; Embryonic Development; Estradiol; Estrus Synchronization; Female; Fertilization in Vitro; Injections, Intramuscular; Oocyte Retrieval; Oocytes; Ovarian Follicle; Pregnenediones; Progestins; Quality Control; Ultrasonography

The present study aimed to evaluate the efficacy of different inducers of new follicular wave emergence (FWE) and ovulation in fixed-time artificial insemination (FTAI) synchronization protocols using norgestomet ear implants (NORG) in Bos indicus cattle. In Experiment 1, the synchronization of FWE was evaluated when two different estradiol esters in different doses [2mg estradiol benzoate (EB), 2.5mg EV or 5mg estradiol valerate (EV)] were administered with NORG implant insertion in B. indicus cattle (estrous cyclic heifers and cows with suckling calves; n=10 per treatment). After estradiol treatment, ovarian ultrasonic exams were performed once daily to detect the interval between treatment and FWE. There were significant treatment-by-animal category interaction (P=0.05) on the interval from the estradiol treatment to FWE. An earlier (P<0.0001) and less variable (P=0.02) interval from estradiol treatment to FWE was observed in heifers treated with EB (2.5±0.2; mean±SE) than in those treated with 2.5mg EV (4.2±0.3) or 5mg EV (6.1±0.6). Cows treated with 5mg EV (4.0±0.5) had longer (P=0.05) interval than cows receiving EB (2.5±0.2), however, there was an intermediate interval in those cows treated with 2.5mg EV (3.1±0.4). In Experiment 2, the number of uses of the NORG implant (new; n=305 or previously used once; n=314) and three different ovulation induction hormones [0.5mg estradiol cypionate (EC) at implant removal (n=205), 1mg EB given 24h after implant removal (n=219), or 100μg gonadorelin (GnRH) given at FTAI (n=195)] were evaluated in Nelore heifers (2×3 factorial design). Similar pregnancy per AI (P/AI; 30 days after FTAI; P>0.05) were achieved using each of the three ovulation induction hormones (EB=40.6%; EC=48.3%, or GnRH=48.7%) and with a new (47.2%) or once-used NORG implant (44.3%). In Experiment 3, the effect of different ovulation induction hormones for FTAI [1mg EC at NORG implant removal (n=228), 10μg buserelin acetate at FTAI (GnRH; n=212) or both treatments (EC+GnRH; n=215)] on P/AI was evaluated in suckled beef cows treated with a once-used NORG implant and EB to synchronize the FWE. Similar P/AI (P=0.71) were obtained using GnRH (50.9%), EC (51.8%) or both treatments (54.9%) as ovulation induction hormones. Therefore, both doses of EV (2.5 or 5.0mg) with NORG implant delayed and increased the variation of the day of new FWE compared with EB in B. indicus cattle. These effects were more pronounced in B. indicus heifers than cows. Sync

Topics: Animals; Buserelin; Cattle; Estradiol; Estrus Detection; Estrus Synchronization; Female; Insemination, Artificial; Ovarian Follicle; Ovulation; Ovulation Induction; Pregnancy; Pregnancy, Animal; Pregnenediones; Progesterone Congeners; Ultrasonography

A total of 177 Nelore heifers were examined by ultrasonography to determine the presence or absence of a corpus luteum (CL) and received a 3mg norgestomet ear implant plus 2mg of estradiol benzoate i.m. On Day 8, implants were removed and 150 microg of d-cloprostenol i.m. was administered. At the time of norgestomet implant removal, heifers with or without CL at the time of initiating treatment were assigned equally and by replicate to be treated with 0IU (n=87) or 400IU (n=90) eCG i.m. All heifers received 1mg of EB i.m. on Day 9 and were submitted to fixed-time artificial insemination (FTAI) 30-34h later. The addition of eCG increased the diameter of the largest follicle (LF) at FTAI (10.6+/-0.2mm vs. 9.5+/-0.2mm; P=0.003; mean+/-SEM), the final growth rate of the LF (1.14+/-0.1mm/day vs. 0.64+/-0.1mm/day; P=0.0009), ovulation rate [94.4% (85/90) vs. 73.6% (64/87); P=0.0006], the diameter of the CL at Day 15 (15.5+/-0.3mm vs. 13.8+/-0.3mm; P=0.0002), serum concentrations of progesterone 5 days after FTAI (6.6+/-1.0 ng/ml vs. 3.6+/-0.7ng/ml; P=0.0009), and pregnancy per AI [P/AI; 50.0% (45/90) vs. 36.8% (32/87); P=0.04]. The absence of a CL at the beginning of the treatment negatively influenced the P/AI [30.2% (16/53) vs. 49.2% (61/124); P=0.01]. Therefore, the presence of a CL (and/or onset of puberty) must be considered in setting up FTAI programs in heifers. In addition, eCG may be an important tool for the enhancement of follicular growth, ovulation, size and function of the subsequent CL, and pregnancy rates in progestin-based FTAI protocols in Bos indicus heifers.

Topics: Animals; Cattle; Chorionic Gonadotropin; Cloprostenol; Corpus Luteum; Drug Implants; Estradiol; Estrus Synchronization; Female; Horses; Insemination, Artificial; Luteolytic Agents; Ovarian Follicle; Ovulation; Pregnancy; Pregnenediones; Progesterone; Time Factors; Ultrasonography

The production of embryos from prepubertal lambs is inefficient, partly resulting from the low developmental competence of prepubertal lamb oocytes, and partly because a high proportion of lambs fail to respond to hormone stimulation. The development of a hormone stimulation regimen that all lambs respond to would increase the efficiency of breeding from prepubertal animals. Using a hormone stimulation regimen consisting of oestradiol benzoate (50 microg), a norgestomet implant (1.5 mg), pregnant mare serum gonadotrophin (400 IU) and follicle stimulating hormone (130 mg) all lambs (n = 19) responded to hormone stimulation. Uterine and ovarian weight ranged from 2.8 to 7.2 g (11.8 +/- 0.7 g) and from 1.7 to 54.1 (12.5 +/- 2.9 g), respectively. The number of ovarian follicles and oocytes recovered ranged from 20.0 to 500.0 (118.2 +/- 29.2) and from 13.0 to 455.0 (82.0 +/- 24.2), respectively, and oocytes suitable for in vitro production were obtained from all 19 lambs. Uterine weight was related to both bodyweight and growth rate (P < 0.05), although ovarian weight and the number of ovarian follicles were not related to either bodyweight or growth rate. Oocyte cleavage varied between hormone-stimulated lambs (0.0-93.0%; P < 0.05), and 484/775 (62.2%) of the oocytes cultured cleaved. Oocytes from 17 of the 19 lambs (89.5%) developed to the blastocyst stage in vitro , and the proportion of zygotes forming a blastocyst (by Day 7) ranged from 0.0 to 66.7% for individual lambs. Overall, 33.9% of zygotes (n = 164) developed to the blastocyst stage, producing 8.6 +/- 2.8 blastocysts per lamb.

Topics: Animals; Breeding; Embryonic Development; Estradiol; Female; Fertilization in Vitro; Follicle Stimulating Hormone; Gonadotropins, Equine; In Vitro Techniques; Oocytes; Organ Size; Ovulation Induction; Pregnenediones; Sheep; Uterus