Artificial insemination of ewes with frozen-thawed semen at a synchronized oestrus. 1. Effect of time of onset of oestrus, ovulation and insemination on fertility

In three experiments, the onset of oestrus, time of ovulation and lambing after intrauterine insemination with frozen-thawed semen were examined following synchronisation of oestrus using intravaginal progestagen-impregnated sponges (inserted for 12 days) and an injection of PMSG at sponge removal.

The number (and percentage) of ewes detected in oestrus 12, 24, 36, 48, 60 and 72 h after sponge removal was 1 (0.3), 2 (0.6), 17 (5.2), 120 (36.7), 65 (20.0) and 10 (3.1) respectively. One hundred and twelve ewes (34.3%) remained unmarked. Egg fertilisation rates were not different between ewes irrespective of time of onset of oestrus or whether or not ewes were marked.

The median time of ovulation with respect to sponge removal (with 95% fiducial limits) for ewes joined with vasectomised rams (10:1) at spronge removal (teased ewes) was 55.8 h (54.61–57.09) and for unteased ewes 59.7 h (58.27–61.12).

In the third experiment, a total of 394 ewes were inseminated by laparoscopy with frozen-thawed semen. The percentage of ewes lambing and lambs born per ewe inseminated, and number of lambs born per ewe lambing for inseminations 48, 60, 72 and 78 h after sponge removal were 45.9, 57.7 and 1.25; 55.1, 72.0 and 1.31; 57.4, 80.9 and 1.41; and 39.3, 60.7 and 1.54, and for 59 control ewes receiving fresh semen by cervical insemination 47.5, 69.5 and 1.46 respectively. The lambing data after insemination with frozen semen was not different to that of the controls. The percentage of ewes lambing and lambs born per ewe inseminated increased with time of insemination at 48, 60 and 72 h (linear, P < 0.01) but was lower for inseminations at 78 h after sponge removal. Number of lambs born per ewe lambing increased with time of insemination after sponge removal (linear, P < 0.05).     

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 GnRH synchronized ovulation, leading to 91% of ovulations appearing between 36 and 48 h after sponges were withdrawn.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.     

Artificial insemination of ewes with frozen-thawed semen at a synchronised oestrus. 2. Effect of dose of spermatozoa and site of intrauterine insemination on fertility

Three experiments were conducted to examine the effect of dose of inseminate, number of uterine horns inseminated and site of insemination on subsequent fertility of Merino ewes after synchronisation of oestrus, with progestagen-impregnated sponges (inserted for 12 days) and an injection of PMSG, and intrauterine insemination with frozen-thawed semen.The percentages of ewes lambing after insemination with 0.5, 5, 25 and 50 × 10⁶ spermatozoa were 29.3, 26.8, 56.3 and 62.1% respectively. A similar trend was observed in a second test resulting in 23.5, 38.8 and 53.1% ewes lambing after insemination with 5, 10 and 20 × 10⁶ spermatozoa respectively.The percentage of ewes lambing was higher for ewes inseminated in two uterine horns than one horn (76.8 vs. 44.9, P < 0.001). When semen was deposited in the tip, middle and bottom of the uterine horn, the percentages of ewes lambing and lambs born per ewe inseminated were 43.6 and 52.7, 52.8 and 84.9, and 41.2 and 64.7% respectively. Although site of insemination did not affect the percentage of ewes lambing, the percentage of lambs born per ewe inseminated was higher after insemination in the middle of the uterine horn than at the other sites (P < 0.001).     

The effects of the prostaglandin E analogue Misoprostol and follicle-stimulating hormone on cervical penetrability in ewes during the peri-ovulatory period

Two experiments in parous Welsh Mountain ewes determined the pattern of natural cervical relaxation over the peri-ovulatory period and investigated FSH and Misoprostol as cervical relaxants to facilitate transcervical passage of an insemination pipette into the uterine cavity. Following synchronisation of oestrus using progestagen sponges and PMSG (500 IU) the depth of cervical penetration was determined using a modified cattle insemination pipette as a measuring device. Penetration of the cervix was least at the time of sponge removal and increased to a maximum at 72 h after sponge removal and then declined. Intra-cervical administrations of either ovine FSH (Ovagen; 2mg) or Misoprostol (1mg; a Prostaglandin E(1) analogue) facilitated cervical penetration. Ovagen given 24h after sponge removal allowed transcervical intrauterine penetration in 100% of ewes at 54 and 60 h after sponge removal while Misoprostol given 48 h after sponge removal allowed trans-cervical penetration in 100% of ewes at 54 h. A combination of Ovagen and Misoprostol was as effective but not more so than Ovagen or Misoprostol alone. These results show that there is natural relaxation of the cervix at oestrus and that maximum relaxation occurs 72 h after sponge removal, which is too late for the correct timing of insemination. The intra-cervical administration of FSH or Misoprostol enhanced relaxation of the cervix and both were able to relax the cervix to allow intrauterine penetration 54 h after sponge removal, the optimum time for insemination. The results also show that FSH is biologically active after intracervical, topical application.     

Oestrus, time of ovulation, ovulation rate and conception rate in progestagen-treated ewes given Gn-RH, Gn-TH analogues and gonadotrophins.

The influence of Gn-RH, hCG and a PMSG-hCG mixture (PG600) on the time of ovulation, ovulation rate and on the occurrence of oestrus in ewes treated with progestagen-impregnated sponges for 12 days examined. The effects of Gn-RH analogues on plasma LH, oestrus, ovulation and conception rate were also investigated. Six separate experiments were carried out. When 50 micrograms Gn-RH were given 24 h after sponge removal ovulation occurred in 44--46% of ewes within 24 h and in all ewes by 34 h. Gn-RH was a more potent ovulation synchronizer than hCG. Both hCG and PG600 reduced the incidence of overt oestrus. Gn-RH also had this effect in ewes treated during February and May but not in August and September. Gn-RH analogues given 2 days before sponge removal significantly increased ovulation rate. The display of oestrus was not affected in ewes treated 2 days before sponge removal but was suppressed in 43-69% of ewes treated with an analogue at the time of sponge removal. Ovulation occurred in 50-62% of ewes within 30-35 h of injection of Gn-RH analogues, regardless of the time of their administration. The release of LH in response to one analogue was not influenced by the presence of the progestagen-impregnated sponge in the vagina. When given a Gn-RH analogue 2 days before sponge removal or at the time of sponge removal 63 and 62% of mated ewes became pregnant compared with 70% of control ewes.     

Influence of sperm number and seminal plasma on fertility of progestagen-treated sheep in confinement

Progestagen-impregnated vaginal sponges + PMSG were used to synchronize oestrus in crossbred adult ewes which were inseminated 56 h after sponge removal with 0.5 ml diluted semen containing 400, 200, 100, 50 or 25 x 10(6) spermatozoa per insemination. The diluent was skim milk-citrate or pooled seminal plasma. There was no difference in reproductive performance due to the insemination medium. Fertility (no. of ewes lambing) after insemination of 400 or 200 x 10(6) spermatozoa was 68% and was similar to that observed after natural service at progestagen-induced oestrus. When less than or equal to 100 x 10(6) spermatozoa were inseminated, fertility fell markedly and the number of lambs per ewe inseminated decreased. A decrease in litter size also occurred. The data indicate that insemination of 200 x 10(6) spermatozoa, i.e. less than 10% of the number in a single ram ejaculate, allows normal conception rates in progestagen-treated ewes.     

A comparison of PMSG and LHRH agonist treatment in the induction of ovulation in the anoestrous ewe

The aim of this experiment was to compare the use of pregnant mares' serum gonadotrophin (PMSG) with that of a luteinizing hormone releasing hormone (LHRH) agonist in the induction of ovulation in anoestrous sheep. Anoestrous ewes were treated with progestagen-impregnated sponges for 12 days. They were given either PMSG at the time of sponge withdrawal or the LHRH agonist D-Ser(But)⁶desGlyNH₂¹⁰LHRH ethylamide 20 h after sponge withdrawal. This protocol was followed over 2 consecutive years. Plasma concentrations of oestradiol and LH were measured, and in the first year a comparison was made of the ovulation rate, conception rate and luteal function of the two groups after artificial insemination. During the first year, all of the PMSG-treated group but none of the agonist-treated group exhibited oestrus. Five of the eight PMSG-treated ewes had embryos in utero at slaughter whilst none was present in the agonist-treated ewes. The secretion of progesterone was greatest in the PMSG-treated ewes (P < 0.001). During the second year, a more frequent blood-sampling regime was employed. Increased plasma concentrations of LH occurred within 3 h of agonist administration. Plasma oestradiol concentrations peaked at 20 h and 45 h after sponge withdrawal in both groups. Both peaks were larger in the agonist-treated group. It is concluded that a single dose of the highly potent LHRH agonist is unable to produce normal luteal function or conception using the present protocol.     

Effect of artificial insemination on submission rates of lactating dairy cows synchronised and resynchronised with intravaginal progesterone releasing devices and oestradiol benzoate

This study investigated the hypothesis that a reduction in submission rates at a resynchronised oestrus is not due to the resynchrony treatment involving intravaginal progesterone releasing devices (IVDs) and oestradiol benzoate (ODB) but is associated with artificial insemination (AI) at the first synchronised oestrus. In Experiment 1, cows were synchronised for first oestrus with IVDs, with ODB administered at the time of device insertion (Day 0, 2 mg IM) and 24 h after removal (Day 9, 1 mg IM) and PGF(2alpha) injected at the time of device removal. Cows were then either inseminated (I) for 4 days or not inseminated (NI) following detection of oestrus (first round of AI). Every animal was resynchronised for a second round of AI by reinsertion of IVDs on Day 23 with administration of ODB (1 mg IM) at the time of insertion as well as 24 h after removal (Day 32). Cows detected in oestrus and inseminated for 4 days at the second round of AI were resynchronised for a third round by repeating the resynchrony treatment starting on Day 46 and inseminating cows on detection of oestrus for 4 days. In Experiment 2 the same oestrous synchronisation and resynchronisation treatments were used, but the timing of treatments differed. The cows had their cycles either presynchronised (treatment start Day -23) without AI and then resynchronised, starting on Day 0, for the first round of AI for AI at detected oestrus for 4 days, or they were synchronised (treatment start Day 0) for the first round of AI. In Experiment 1, 91.4% (64/70) and 92.6% (63/68) (P = 0.79) of cows in the I and NI treatments, respectively, were detected in oestrus after the initial synchronisation. At the second round of AI, submission rates for insemination were lower in the I group compared to the NI cows (74.5%, 35/47 versus 92.6%, 63/68, respectively; P = 0.007). Pregnancy rates (proportion treated that were classified as becoming pregnant) in I and NI cows 4 weeks (61.4%, 43/70 versus 63.2%, 43/68) and 7 weeks (77.1%, 54/70 versus 69.1%, 47/68) after the AI start date (AISD) did not differ significantly between treatments. In Experiment 2, presynchronisation and then resynchronisation of oestrous cycles before the first round of AI did not affect oestrous detection rates at the first round of AI (100%, 44/44 versus 98.0%, 50/51; P = 0.54), or pregnancy rates 1 week (63.6%, 28/44 versus 60.8%, 31/51; P = 0.70), 4 weeks (72.7%, 32/44 versus 76.5%, 39/51; P = 0.76) and 7 weeks (81.8%, 36/44 versus 88.2%, 45/51; P = 0.40) after AISD compared to cows that had their cycles synchronised for the first round of AI. These findings support our hypothesis that a reduction in submission rates at a resynchronised oestrus is associated with AI at the first synchronised oestrus and not due to a resynchrony treatment involving IVDs and ODB. This study supports the concept that early embryonic loss following AI at a synchronised oestrus could cause a reduction in submission rates following resynchronisation of oestrus, although investigation of the effect of passing an AI catheter or semen components were not studied per se.     

Effect of storage duration, storage temperature, and diluent on the viability and fertility of fresh ram sperm

Cervical artificial insemination (AI) in sheep with fresh semen yields a much higher pregnancy rate than when frozen-thawed semen is used, and consequently frozen semen is only acceptable for laparoscopic insemination. The short life span of fresh semen is a major constraint on the use of AI in genetic improvement programs for sheep. The main objective of this study was to examine the effects of storage conditions on viability and fertilization ability of fresh ram (Ovis aries) semen up to 72 h postcollection. Experiment 1 was designed to evaluate the effect of diluent type (standard skim milk, AndroMed, OviPro, and INRA 96) and storage temperature (5 °C and 15 °C) on the motility and viability of fresh ram semen. Storage temperature, irrespective of diluent, had a significant effect on both motility and viability. Storage at 5 °C maintained acceptable motility and viability up to 72 h compared with that of storage at 15 °C. In Experiment 2, the penetrating ability of fresh ram semen, diluted in either skim milk, AndroMed, or INRA 96, was assessed using artificial mucus. Flat capillary tubes containing artificial mucus were suspended in 250 μL semen at a sperm concentration of 20 × 10⁶/mL. Semen was stored at 5 °C and tested after 6, 24, 48, and 72 h. There was a significant diluent by time interaction. In Experiment 3, the fertilizing ability of fresh ram semen stored at 5 °C was evaluated in vitro. Fresh semen (diluted in either skim milk, AndroMed, or INRA 96) was added to matured ewe oocytes at 6, 24, or 72 h after semen collection. Cleavage rate was recorded at 48 h postinsemination, and blastocyst development was recorded on Days 6 to 9. There was a significant treatment effect on cleavage and blastocyst rates; insemination of semen stored for 24 h resulted in higher rates than those for storage at 72 h. In Experiment 4, the fertilizing ability of fresh ram semen was evaluated in vivo. Semen was diluted in INRA 96, stored at 5 °C, and used to inseminate ewes on the day of collection or at 24, 48, and 72 h postcollection. Multiparous ewes were cervically inseminated at a synchronized estrus. Fertility rate decreased linearly (P < 0.001) up to 72 h after semen collection.     

High fertility using artificial insemination during deep anoestrus after induction and synchronisation of ovulatory activity by the "male effect" in lactating goats subjected to treatment with artificial long days and progestagens

The response to the male effect was studied in two Saanen and two Alpine flocks over 5 consecutive years. Adult male and female goats were exposed to artificial long days (16h light and 8h darkness, 16L:8D) in open barns for approximately 3 months (between December 1 and April 15) followed by a natural photoperiod. Goats were treated for 11 days with fluorogestone acetate (FGA) or progesterone (CIDR) immediately before joining. Bucks carrying marking harnesses with adapted aprons joined females 49-63 days after the end of the long-day treatment (between April 30 and June 5) and were left with them for 5 days. In experiment 1 (n=142), FGA- and CIDR-treated goats were inseminated at a time based on the detection of oestrus. Two insemination groups were distinguished by the occurrence of marking over a 48-h period. Earlier (group 1) and later (group 2) buck-marked goats received one single insemination 12-24h or 0-12h after marking, respectively. Unmarked goats were inseminated along with group 2. In experiment 2 (n=344), FGA-treated goats were inseminated 52 and 70 h (52 h:70 h group) or 52 and 75 h (52 h:75 h group) after joining. In experiment 3 (n=285), FGA-treated goats were inseminated 52 h (1-AI group) or 52 and 75 h (2-AI group) after joining. In all experiments, an external control group given the "classical" insemination program was analysed. Over the 5-year period, 92% of the goats exhibited an LH surge during days 1-4 after joining and 98% of them ovulated. Eighty-seven percent of the LH surges detected in milk occurred during the 33-57 h interval after joining, indicating that ovulation took place around 45-69 h. In experiment 1, 96% of the goats were marked 22-70 h after joining. Kidding rate (KR; 78%) was similar between insemination groups and between FGA- and CIDR-treated goats (p>0.05). Most of the goats (95%) were inseminated during the interval between 15h before and up to 4h after ovulation. KR was not affected by the time between detection of marking and insemination or between insemination and ovulation (p>0.05). In experiment 2, KR (75%) was similar in both insemination groups (p>0.05). In experiment 3, KR was higher (p<0.05) in the 1-AI (71%) than the 2-AI group (57%). In all experiments, KR of the control group (68-73%) was similar to that achieved in goats induced to ovulate by the male effect. Prolificity (2.1+/-0.7) was not affected by any of the factors examined (p>0.05). In conclusion, high fertility can be achieved during anoestrus when 1 or 2 inseminations are performed over a 24h period, determined by oestrus or by the introduction of the buck, if light-treated goats receive 11-day FGA or CIDR treatment and are then induced to ovulate by the male effect.     

Effect of solid storage at 15 degrees C on the subsequent motility and fertility of rabbit semen

We conducted two studies to improve preservation of rabbit semen. The objective of the first study was determine whether a glucose- and fructose-based extender with two different amounts of gelatin would solidify at 15 degrees C, and to evaluate the influence of gelatin supplementation on sperm motility parameters after storing semen up to 10 days at 15 degrees C. The fertility of rabbit semen diluted in the best gelatin-supplemented extender established in Study 1 and stored for up to 5 days was evaluated in the second study. In Study 1, semen was collected with an artificial vagina from 40 bucks. Each ejaculate was diluted to (80-100) x 10(6) spermatozoa/mL (1:3, semen/extender) at 37 degrees C in one of the three following glucose- and fructose-based extenders: control (standard liquid extender), semi-gel or gel (0.7 or 1.4 g gelatin in 100 mL extender, respectively). Pools of semen were allocated among 0.6 mL plastic artificial insemination (AI) guns. Thirty (10 per extender group) AI doses were immediately analyzed (0 h) and the remainder stored in a refrigerator (15 degrees C) for 12, 24, 36, 48, 72, 96, or 240 h. All doses with gelatin extenders solidified at 15 degrees C. Semen samples, prewarmed to 37 degrees C, were evaluated with a computer-assisted sperm analysis (CASA) system. The percentage of motile cells was significantly lower using the liquid compared to the gel extenders during semen storage from 0 to 96 h. Although significance was lost, these differences persisted after 240 h of storage. Motility of spermatozoa in the semi-gel extender was intermediate between that of liquid and gel extender throughout the study. Study 2 was performed on 1250 multiparous lactating does. Five homogeneous groups of 250 does previously synchronized were inseminated using semen previously stored for 120, 96, 72, 48 or 24 h, respectively. Rabbit does receiving 24 h-stored semen (diluted with the control extender used in Study 1) served as controls. The remaining females received seminal doses supplemented with 1.4 g/100mL gelatin (gel extender used in Study 1). Kindling rates for rabbit does inseminated with gelatin-supplemented (solid) semen doses stored for 48 h (88%) or 72 h (83%) were similar to those recorded for liquid controls stored for 24 h (81%), whereas rates significantly decreased when the semen was solid and stored for 96 h (64%) or 120 h (60%) before AI. In conclusion, rabbit spermatozoa were effectively stored in the solid state at 15 degrees C, with fertility preserved for up to 5 days. Solid storage of rabbit semen would facilitate commercial distribution.     

Effect of site of deposition on the fertility of sheep inseminated with frozen-thawed semen

The widespread use of artificial insemination (AI) in sheep is currently prevented due to the lack of a cost effective insemination technique utilising frozen-thawed semen. The objective of the present study was to determine if the deposition of frozen-thawed semen in the vaginal fornix would result in a pregnancy rate comparable to that achieved following cervical insemination. Multiparous ewes of various breeds were synchronised and inseminated into either the vaginal fornix (n=78) or the cervix (n=79), at 57 h post sponge removal, with frozen-thawed semen. Information on mucus secretion and the depth to which it was possible to penetrate the cervix at insemination (cervically inseminated ewes only) was recorded at the time of AI. Pregnancy rate was subsequently determined either by return to service (oestrus) or after slaughter 30 days post insemination. Insemination site did not significantly influence pregnancy rate using frozen-thawed semen (36.2% compared to 27.6% for cervical and vaginal fornix insemination, respectively; P=0.26). Whilst depth of cervical penetration was positively associated with pregnancy rate (P<0.05), this association needs to be interpreted with caution as none of the ewes where the cervix could not be penetrated (score=0) was pregnant. In conclusion, pregnancy rate following insemination of frozen-thawed semen into the vaginal fornix was within 10% points of that obtained following cervical AI of frozen-thawed semen. As insemination into the vaginal fornix is technically easier than cervical insemination, it may be more practical for use in large scale applications.     

Advances in cooled semen technology.

In the horse industry, milk or milk-based extenders are used routinely for dilution and storage of semen cooled to 4-8 degrees C. Although artificial insemination (AI) with chilled and transported semen has been in use for several years, pregnancy rates are still low and variable related to variable semen quality of stallions. Over the years, a variety of extenders have been proposed for cooling, storage and transport of stallion semen. Fractionation of milk by microfiltration, ultrafiltration, diafiltration and freeze-drying techniques has allowed preparation of purified milk fractions in order to test them on stallion sperm survival. Finally, a high protective fraction, native phosphocaseinate (NPPC), was identified. A new extender, INRA96, based on modified Hanks' salts, supplemented with NPPC was then developed for use with cooled/stored semen.Four experiments were conducted to compare INRA96 and milk-based extenders under various conditions of storage. The diluted semen was maintained under aerobic conditions when stored at 15 degrees C, and anaerobic conditions when stored at 4 degrees C. In experiment 1, split ejaculates from 13 stallions were diluted either in INRA96 extender then stored at 15 degrees C or diluted in Kenney or INRA82 extenders and then stored at 4 degrees C for 24h, until insemination. In experiment 2, semen from two stallions was extended in INRA96 then inseminated immediately or stored at 15 degrees C for 3 days until insemination. In experiment 3, semen from three stallions was diluted in INRA96 then stored at 15 or 4 degrees C for 24h until insemination, finally, in experiment 4, split ejaculates from four stallions were diluted in INRA96 or E-Z Mixin extenders then stored at 4 degrees C for 24h until insemination. Experiment 1 demonstrated that at 15 degrees C, INRA96 extender significantly improved pregnancy rate per cycle compared to Kenney or INRA82 extenders at 4 degrees C after 24h of storage (57%, n=178 versus 40%, n=171, respectively; P<0.01). Experiment 2 showed that semen stored at 15 degrees C for 3 days can achieve pregnancy at a fertility rate per cycle of 48% (n=52) compared to 68% (n=50, immediate insemination, P=0.06). Experiment 3 demonstrated that INRA96 extender can be as efficient at 15 degrees C (54%, n=37) as at 4 degrees C (54%, n=35) after 24h of storage. Finally, experiment 4 showed that INRA96 extender used at 4 degrees C (59%, n=39) seems to improve fertility per cycle compared to E-Z Mixin at 4 degrees C (49%, n=39, P=0.25), but this result has to be confirmed.These results demonstrate that semen diluted in INRA96 extender and stored at 15 degrees C can be an alternative to semen diluted in milk-based extenders and stored at 4 degrees C for "poor cooler" stallions. Furthermore, INRA96 extender can be as efficient at 15 degrees C as at 4 degrees C, for preserving sperm motility and fertility.     

Successful uterine insemination of fallow deer with fresh and frozen semen

Six fallow does were inseminated directly into the uterine horns 72 h (three does) or 78 h (three does) after the removal of progestagen intravaginal sponges. Three does were inseminated with fresh (two at 72 h and one at 78 h) or frozen-thawed (one at 72 h and two at 78 h) semen. The semen used had been collected by electroejaculation and had been stored for 2 yr in liquid nitrogen in a Tris, citric acid, glycerol diluent containing 2.25% egg yolk. Three does each produced a live fawn to insemination and all does had been inseminated 72 h after removal of sponges; two with fresh semen and one with frozen semen. The remaining three does failed to conceive to insemination, but did produce fawns to mating at a subsequent estrus.     

Induction of estrus with intramuscular injections of GnRH or PMSG in lactating goats (Capra hircus ) primed with a progestagen during seasonal anestrus

In Experiment 1, goats in seasonal anestrus (n=154) were treated with sponges impregnated with 1 of 2 types of progestagen (MAP or FGA) followed by PMSG (400 IU im) 48 h before sponge removal. The type of progestagen used had no effect on kidding, abortion, pseudogestation, multiple births, stillbirths, number of live births per doe or gestation length. In Experiment 2, lactating goats (n=24) in seasonal anestrus were treated with progestagen sponges (MAP). At sponge removal they received one of the following treatments: 1 injection of PMSG (400 IU im), 1 injection of GnRH (125 mug im; GnRH-1), or 2 injections of GnRH (125 mug/injection im; GnRH-2) at a 48 h interval. Serum samples were taken at 6-h intervals for 96 h, starting 12 h after sponge removal. Heterologous radioimmunoassays were validated for the measurements of goat FSH, LH, E(2) and P(4). The onset of estrus (P=0.004), mean doe receptivity (P=0.0006), maximum preovulatory E(2) concentrations (P=0.0001) and LH peak concentrations (P=0.08) occurred significantly later for GnRH-1 and GnRH-2 than for PMSG treatment. The PMSG treatment induced a preovulatory LH peak in a greater number of goats (P=0.05) and gave a higher gestation rate than GnRH-1 and GnRH-2 treatments (57 vs 0 vs 12%; P=0.03). It is likely that the GnRH treatments administered did not reactivate the hypothalamo-pituitary-gonadal axis. Thus, intramuscular injections of GnRH in lactating goats primed with a progestagen were not as effective in regulating reproductive performance during seasonal anestrus as were injections of PMSG.     

Plasma progesterone concentrations, ovarian and endocrinological response and sperm transport in ewes with synchronized oestrus

Two experiments involving 24 and 54 Australian Merino ewes were conducted in which the establishment of a cervical population of spermatozoa and several endocrinological events were studied after several regimens for the synchronization of oestrus. Intravaginal sponges impregnated with 500 mg (Exp. 1) or 200, 400 or 600 mg (Exp. 2) progesterone resulted in the maintenance of plasma progesterone concentrations of 1.5-4.9 ng/ml over a 12-day insertion period compared with 1.9-6.9 ng/ml during dioestrus in control ewes. In Exp. 1 basal concentrations of less than or equal to 0.25 ng/ml plasma were attained by 4 h after sponge withdrawal and this decline was much more rapid than in normal luteolysis. This was associated with fewer spermatozoa recovered from the cervix 2 h after insemination, and PMSG had no significant effect. In Exp. 2 injection of a supplementary dose of progesterone at sponge withdrawal resulted in a rapid increase in plasma progesterone concentrations followed by an equally rapid decrease and an attenuation of the rise in plasma oestradiol-17 beta, the LH surge, and the onset of oestrus. The numbers of spermatozoa recovered 4 h after insemination were not increased, and PMSG had no significant effect. Two factors were significant, namely the dose of progesterone in the sponge (600 mg greater than 400 or 200 mg, P less than 0.05) and stage of oestrus when inseminated (mid- or late oestrus greater than early). The data demonstrated that an adequate dose of progesterone/progestagen incorporated into intravaginal sponges and accurate timing of insemination relative to the LH surge are the most important factors involved in penetration of the cervix by spermatozoa.     

Effect of time of artificial insemination on fertility of progestagen and PMSG treated indigenous Greek ewes,during non-breeding season

A total of 2567 indigenous Greek ewes (Chios, Vlachiki and Vlachiki×Chios breeds) were used to determine the optimum time for insemination, following synchronization of oestrus with MAP-impregnated intravaginal sponges and PMSG during non-breeding season. Within each breed group, the ewes were divided into three subgroups and submitted to a double blind cervical artificial insemination 48 and 60 h (subgroup I), 60 and 72 h (subgroup II) and 48 and 72 h (subgroup III) after sponge withdrawal. From the results of the present investigation it can be concluded that the conception rate in the Chios island breed is better than that in the Vlachiki×Chios breed, with the latter being better than that in the Vlachiki breed. Using fixed time for AI, a better conception rate is obtained when applied 48 and 72 h after sponge withdrawal for Chios and Chios×Vlachiki breeds, while for Vlachiki breed a better conception rate is obtained when fixed AI is applied 48 and 60 h after sponge withdrawal.     

Short-duration insemination with frozen semen increases fertility rate in nulliparous dairy goats

Standard artificial insemination (AI) using a speculum in dairy goats does not result in acceptable fertility rates in nulliparous does. An explanation might be the difficulties to pass the cervical canal in nulliparous females with the insemination gun, increasing the time needed for semen deposition. Nulliparous Alpine dairy goats were used to evaluate whether time interval from insertion to withdrawal of the speculum is a factor influencing pregnancy rates to first AI with frozenthawed semen. Oestrus was synchronized using fluorogestone acetate intravaginal sponges (FGA, 40 mg) for 11 days, associated with 50 mg i.m. of cloprostenol and 250 IU i.m. eCG 48 ± 2 h before sponge removal. In the first experiment (n = 52; 3 herds), the average duration of the AI procedure was 42 ± 10 s, with a median of 39 s. AI performed in less than 39 s resulted in higher pregnancy rates (75%, n = 28) than AI lasting for more than 39 s (46%, n = 24). In the second experiment, does (n = 325; 5 herds) were randomly assigned into two treatment groups according to a short (20 s) or long (60 s) AI procedure. We showed that the duration of AI affected fertility after a first insemination, and that pregnancy rate was significantly improved using a short-duration AI (61.2%; n = 169) compared with a long-duration AI (44.2%; n = 156). We have previously shown in the ewe that genital stimulation during AI enhanced uterine motility. Other authors reported a negative correlation between increased uterine motility at the time of AI and fertility rates in small ruminants. The results of this study suggest that rapid semen deposition may limit the reflex activation of uterine contractions provoked by the speculum and the movement of the insemination gun, and thus ameliorates reproductive performance to first AI in nulliparous goats.     

The effects of different insemination regimes on fertility in mares

This study investigated the effects of different artificial insemination (AI) regimes on the pregnancy rate in mares inseminated with either cooled or frozen-thawed semen. In essence, the influence of three different factors on fertility was examined; namely the number of inseminations per oestrus, the time interval between inseminations within an oestrus, and the proximity of insemination to ovulation. In the first experiment, 401 warmblood mares were inseminated one to three times in an oestrus with either cooled (500 x 10(6) progressively motile spermatozoa, stored at +5 degrees C for 2-4 h) or frozen-thawed (800 x 10(6) spermatozoa, of which > or =35% were progressively motile post-thaw) semen from fertile Hanoverian stallions, beginning -24, -12, 0, 12, 24 or 36 h after human chorionic gonadotrophin (hCG) administration. Mares were injected intravenously with 1500 IU hCG when they were in oestrus and had a pre-ovulatory follicle > or =40mm in diameter. Experiment 2 was a retrospective analysis of the breeding records of 2,637 mares inseminated in a total of 5,305 oestrous cycles during the 1999 breeding season. In Experiment 1, follicle development was monitored by transrectal ultrasonographic examination of the ovaries every 12 h until ovulation, and pregnancy detection was performed sonographically 16-18 days after ovulation. In Experiment 2, insemination data were analysed with respect to the number of live foals registered the following year. In Experiment 1, ovulation occurred within 48 h of hCG administration in 97.5% (391/401) of mares and the interval between hCG treatment and ovulation was significantly shorter in the second half of the breeding season (May-July) than in the first (March-April, P< or =0.05). Mares inseminated with cooled stallion semen once during an oestrus had pregnancy rates comparable to those attained in mares inseminated on two (48/85, 56.5%) or three (20/28, 71.4%) occasions at 24 h intervals, as long as insemination was performed between 24 h before and 12 h after ovulation (78/140, 55.7%). Similarly, a single frozen-thawed semen insemination between 12 h before (31/75, 41.3%) and 12 h after (24/48, 50%) ovulation produced similar pregnancy rates to those attained when mares were inseminated either two (31/62, 50%) or three (3/9, 33.3%) times at 24 h intervals.In the retrospective study (Experiment 2), mares inseminated with cooled semen only once per cycle had significantly lower per cycle foaling rates (507/1622, 31.2%) than mares inseminated two (791/1905, 41.5%), three (464/1064, 43.6%) or > or =4 times (314/714, 43.9%) in an oestrus (P< or =0.001). In addition, there was a tendency for per cycle foaling rates to increase when mares were inseminated daily (619/1374, 45.5%) rather than every other day (836/2004, 42.1%, P = 0.054) until ovulation.It is concluded that under conditions of frequent veterinary examination, a single insemination per cycle produces pregnancy rates as good as multiple insemination, as long as it is performed between 24 h before and 12 h after AI for cooled semen, or 12 h before and 12 h after AI for frozen-thawed semen. If frequent scanning is not possible, fertility appears to be optimised by repeating AI on a daily basis.     

Induction/synchronization of oestrus and ovulation in dairy goats with different short term treatments and fixed time intrauterine or exocervical insemination system

Two experiments were carried out on Ionica dairy goats in order to test the efficiency of: (1) short term-5-day combined progestogen-PGF2α-GnRH treatments on induction/synchronization of oestrus and fertility after natural mating in lactating goats and during the transition period (Experiment 1); (2) short term-9-day FGA-PGF2α-eCG treatments on synchronizing oestrus and ovulation (Experiment 2.1) and artificial insemination (AI) fixed time system in synchronized does (Experiment 2.2), during the breeding season. In Experiment 1, four treatment groups (N=24) were considered: (1) FPe-11d - control, FGA intravaginal sponges (11 days)+PGF2α (9th d)+eCG (11th d); (2) FPe-5d, FGA (5 days)+PGF2α (5th d)+eCG (5th d); (3) PFe-5d, PGF2α (D0)+FGA (5 days)+eCG (5th d); (4) GPe-5d, GnRH (D0)+PGF2α (5th d)+eCG (5th d). Goats were checked for oestrus and naturally mated. The occurrence of oestrus was 75.0, 78.3, 86.4, and 58.3% for groups 1-4, respectively, with significant differences (P<0.05) between groups 3 and 4. Interval to oestrus was earlier (P<0.05) in GPE-5d than in FPe-11d control group. There were no differences between the groups (P>0.05) in fertility or in prolificacy. In Experiment 2.1, 22 goats were subdivided into two treatment groups (N=11): (T1) FPe-11d (control), FGA (11 days)+PGF2α (9th d)+eCG (11th d); (T2) FPe-9d, FGA (9 days)+PGF2α (7th d)+eCG (9th d). Oestrus and ovulation times were monitored every 4h; ovulation rate was also determined. The induction of oestrus ranged from 91 to 100% and all goats ovulated. Intervals to oestrus, from the onset of oestrus to ovulation, from sponge removal to ovulation, and ovulation rates were 28.2±4.9 and 26.0±4.0h, 25.3±9.2 and 28.9±7.4h, 53.5±7.6 and 54.9±7.1h, 3.7±1.6 and 2.4±1.4 corpora lutea (P<0.05) for T1 and T2, respectively. In T2 a great abnormal ovulatory response was observed. In Experiment 2.2, 48 goats were synchronized with FPe-9d treatment and subjected to AI, performed 50h after s.r. with frozen semen, and subdivided into 2 AI system groups (N=24): T3, exocervical AI (100×10(6)Spz/doe); T4, intrauterine AI (20×10(6)Spz/doe). Fertility rate was higher (P<0.05) in T4. It seems that short term-5-day combined progestogen-PGF2α-GnRH-eCG treatments need to be investigated for AI fixed time.