Investigations on the detrimental effect of prostaglandin F2α-regulated estrus on the number and condition of sperm in the reproductive tract of the ewe

Ewes in the luteal phase of the estrous cycle were treated with prostaglandin F₂α (PGF), mated to rams at the ensuing estrus 2 days later, and necropsied at 2 or 23 hr after mating. At 2 hr after mating, ewes in PGF-regulated estrus had significantly fewer sperm in the middle and anterior one-thirds of the cervix and in the uterus than did ewes mated during natural estrus. At 23 hr, soon after ovulation, significantly fewer ewes in PGF-regulated estrus had sperm in the oviducts than did ewes in natural estrus.In Experiment 2, ewes in PGF-regulated or natural estrus were laparotomized, inseminated by deposition of semen in the uterine lumen, and necropsied 2 or 23 hr later. Intrauterine insemination prevented most of the reduction in sperm numbers in the reproductive tract at PGF-regulated estrus.In Experiment 3, ewes in PGF-regulated or natural estrus were either mated to rams or inseminated in the uterine lumen and necropsied 2 hr later. Sperm were recovered from three segments of the cervix and were counted and evaluated for motility, response to live-dead staining, and acrosomal morphology. Intrauterine insemination again reduced the detrimental effect of PGF-regulated estrus on sperm numbers. However, the percentages of sperm recovered from the cervix that were motile, live, and had normal acrosomes were much lower in ewes in PGF-regulated estrus than in ewes in natural estrus. Compared with natural mating, intrauterine insemination reduced but did not eliminate the detrimental effects of PGF-regulated estrus on the viability and morphology of sperm. Regulating estrus with PGF resulted in damage to sperm in the cervix regardless of whether sperm reached the cervix from the vagina or from the uterus.     

Fertility and sperm transport in Merino ewes at the first oestrus following embryonic death.

The embryos of ewes were killed with colchicine on Day 17 of gestation and the ewes were mated at the subsequent oestrus. Fertility was reduced at this mating, and fewer spermatozoa were found in the uterus and oviducts than in control animals. The total number of spermatozoa in the cervix and their distribution between the lumen and walls of the cervix were not altered, but the linear distribution along the cervical walls was changed. The density of the reamining spermatozoa in the control animals after flushing the cervix showed a progressive decrease from the posterior to the anterior segments. This did not occur in the untreated ewes. It seems likely that impaired sperm transport contributed to the lowered fertility.     

Cineradiography of uterine motility in the cycling ewe

Five cinehysterography sessions during oestrus and three during metoestrus were performed in four ewes for the assessment of uterine motility. Radio-opaque material was deposited in the uterine body through a permanent catheter in the cervix, and the changes in the shape and size of the uterine lumen, as well as the conveyance of radio-opaque material therein were traced. The changes in the lumen consisted of temporary widenings and constrictions resulting in segmentary divisions of the lumen. The radio-opaque material, which never passed the cervix or uterotubal junctions, was repeatedly conveyed to and fro between the uterine horns. One two-way transport was completed within about 40 s.These findings show the relation in vivo between uterine motility and the transport of particles in the uterine lumen, and the blocking activity of the cervix and the uterotubal junctions.     

Inhibition of sperm transport and fertilization in superovulating ewes

In Experiment 1, all ewes were treated with follicle stimulating hormone (FSH-P) to induce superovulation. Ewes came into natural estrus or were treated with prostaglandin F(2)alpha (PGF(2)alpha) or 6-methyl-17-acetoxyprogesterone (MAP) to regulate the time of estrus. The ewes were mated during estrus and necropsied 3 h after mating. Regulation of estrus with either compound reduced the number of sperm recovered from the cervix, uterus, and oviducts and increased the proportions of sperm recovered from the cervix and uterine body that were immotile, dead, or had disrupted membranes. In Experiment 2, all ewes were in natural estrus. They either ovulated naturally or were superovulated, and ewes in each group were necropsied at 3 or 23 h after mating. Superovulation reduced the number of sperm in oviducts, uterus, and anterior segments of the cervix at both time intervals and increased the proportions of sperm that were immotile, dead, or had disrupted membranes. In Experiment 3, of 3x2 design, ewes were in either natural estrus or estrus regulated with PGF(2)alpha or with MAP; they ovulated naturally or were superovulated. Ewes were necropsied 3 d after mating and ova were examined. Both regulation of estrus and superovulation reduced the proportion of ova that were fertilized and reduced the number of accessory sperm attached to fertilized ova.     

Concentrations of spermatozoa in the vagina of heifers after deposition of semen in the uterine horns, uterine body or cervix

In Exp. I, virgin Holstein heifers (N = 18) were induced into oestrus with PGF-2 alpha. Animals which stood to be mounted were paired for insemination approximately 8 h later with 56.1 x 10(6) spermatozoa from a single bull. Semen was deposited in the uterine body of one female. Each matched female was inseminated by deposition of one-half of the inseminate into the right uterine horn and one-half into the left uterine horn approximately 7.0 cm anterior to the internal cervical os. In Exp. II, additional heifers (N = 18) were induced into oestrus and inseminated by deposition into the uterine horns or cervix (2.0 cm anterior to the external cervical os). A 1.0 ml aspirate of vaginal mucus was collected at hourly intervals for 8 h after insemination. Concentration of spermatozoa was determined by haemocytometry. In Exp. I, cumulative percentage spermatozoa recovered in an 8 h collection period were similar (P greater than 0.10) for insemination into the uterine horns (17.9 +/- 2.9%) and uterine body (18.5 +/- 4.5%). In Exp. II, cumulative % sperm recovery from the vagina was greater (P less than 0.10) for cervical deposition (59.1 +/- 14.1%) than for that into the uterine horns (30.9 +/- 7.8%). In Exp. II, the insemination treatment x hour of sample interaction was significant (P less than 0.08). Recovery of spermatozoa from the vagina was greatest (P less than 0.05) within 3 h after cervical insemination (31.4 +/- 9.9% compared to 9.4 +/- 2.5% for uterine horn deposition). Percentage recovery of spermatozoa from the remaining hourly collections were similar (P greater than 0.10).(ABSTRACT TRUNCATED AT 250 WORDS)     

Persistent infertility in ewes after prolonged exposure to oestradiol-17 beta

Merino ewes were treated with implants which released 300 micrograms oestradiol-17 beta per day or 5 mg progesterone per day, or both, for 9 months (Months 1-9), and after an 11-month intermission were treated again for 6 months (Months 20-26). Ewes were run with rams at Months 16, 28 and 40. Fertility was not affected by the first exposure period, but the second exposure to oestradiol reduced the fertility of ewes at both subsequent mating periods. Affected ewes returned to service more frequently (P less than 0.01) and were less likely to conceive (P less than 0.05). After mating, a normal population of spermatozoa was established in the caudal cervix, but transport through the cervix was impaired in affected ewes and there were fewer spermatozoa (P less than 0.01) in the cranial cervix. In affected ewes, the spinnbarkeit of cervical mucus was reduced (P less than 0.05), and the histological appearance of the cervix changed, looking like that of the uterus. Treatment with progesterone did not affect fertility, cervical mucus or sperm transport, but diminished the histological abnormalities produced by oestradiol (P less than 0.05). These results show that oestradiol-17 beta given after puberty can cause the same kind of permanent sexual transdifferentiation that is produced by the oestrogenic isoflavones in ewes with clover disease. The results suggest that this change may require more than a single exposure to oestrogen.     

Lambing rates and litter sizes following intrauterine or cervical insemination of frozen/thawed semen with or without oxytocin administration

Intrauterine insemination by laparoscopy is required to achieve acceptable lambing rates in ewes when using frozen semen but the procedure has evoked welfare concerns. Oxytocin has been used to dilate the cervix as a means of accessing the uterus during conventional cervical insemination, but its effect on fertility is not well documented. Three hundred crossbred ewes were synchronised in estrus and randomly allocated to one of three insemination procedures using frozen/thawed semen containing 400 x 10(6)/ml progressively motile sperm: single cervical (0.2 ml), multiple cervical (4 x 0.05 ml) or laparoscopic (0.05 ml per uterine horn). The effects of each insemination procedure on lambing rate (percentage of treated ewes lambing) and litter size (lambs per ewe lambing) were tested with and without oxytocin (10 IU given i.m.) prior to fixed-time insemination. Oxytocin did not permit complete cervical penetration in any ewes and neither lambing rate nor litter size was influenced by the number of inseminations. Lambing percentages were 69 and 42 (P < 0.01) for the laparoscopic and cervical insemination methods, respectively, and oxytocin reduced these to 58 (NS) and 10 (P < 0.001) percent, respectively. Corresponding litter sizes for ewes not receiving oxytocin were 1.91 and 1.51 and for those receiving oxytocin, 1.83 and 1.41 (laparoscopic versus cervical, P < 0.02). Thus, in the absence of complete cervical penetration at insemination, 10 IU oxytocin decreased the number of ewes lambing but had no effect on their litter size.     

Experiments on egg transfer in the cow and ewe: dependence of conception rate on the transfer procedure and stage of the oestrous cycle.

The effects on embryo survival of procedures used in transferring eggs non-surgically were investigated in three experiments in ewes and heifers. In Exp. 1, two techniques for introducing eggs into the uterus through the cervix in heifers were compared; namely (i) deposition of the eggs high into the uterine horn or (ii) into the body of the uterus. Both methods were followed by inflation of the uterus with carbon dioxide. Out of a total of 34 heifers, only one became pregnant by the use of Method (i). Non-surgical egg tansfers early (Days 3 to 5) or later (Days 6 to 9) in the oestrous cycles of heifers were carried out in Exp. 2. Three transfer procedures were compared: (i) pipette transfer of an egg into the body of the uterus through the cervix (control), (ii) the control procedure performed under Fluothane anaesthesia, or (iii) followed by inflation of the uterus with carbon dioxide. Wide transfers carried out early in the cycle, pregnancies resulted in 1/10, 0/10 and 1/10 of the heifers in the control, carbon dioxide and Fluothane groups, respectively. With late transfers, 7/20, 1/10 and 8/20 heifers became pregnant in the respective treatment groups. This trend for pregnancy rate to be improved when late transfers were done in the control and Fluothane groups was significant only at the 10% level of probability when both groups were pooled. It was tentatively concluded, however, that non-surgical transfers of fertilized eggs to heifers may be best done during mid-cycle, after Day 6. Fluothane anaesthesia did not improve conception rate. Inflation of the uterus with carbon dioxide appeared to be deleterious when used at the mid-cycle stage in heifers. In Exp. 3, it was found that inflation of the ewe's uterus with carbon dioxide or nitrogen following the surgical thansfer of an egg did not affect the incidence of pregnancy. The introduction of 50 mul liquid Fluothane into the lumen of the uterus was embryotoxic.     

Sperm movement in the ooplasm, dithiothreitol pretreatment and sperm freezing are not required for the development of porcine embryos derived from injection of head membrane-damaged sperm

The present study investigated the correlation of sperm movement in the ooplasm, pretreatment of sperm with dithiothreitol (DTT) and sperm freezing with the development of porcine embryos derived from modified intracytoplasmic sperm injection (ICSI). In vitro, matured gilt oocytes without centrifugation were injected with head membrane-damaged spermatozoa aspirated tail-first. In Exp. 1, frozen-thawed sperm were categorized into three groups: impaired, immotile or motile. Oocytes injected with motile sperm (43.6%) showed a higher (P < 0.05) fertilization rate compared to oocytes injected with impaired or immotile sperm (34.5 or 37.2%). The survival rate was significantly higher (P < 0.05) in oocytes injected with impaired sperm (92.9%) than in oocytes injected with immotile or motile sperm (84.8 or 86.7%). No differences were observed in the rates of cleavage or blastocyst formation, and in total cell number of blastocysts among three groups of oocytes. In Exp. 2, motile frozen-thawed sperm were pretreated with DTT before injection and non-treated sperm served as controls. Higher rates (P < 0.05) of fertilization, male pronucleus (MPN) and decondensed sperm head (DSH) formation were observed in oocytes injected with control sperm (41.1, 50.0 and 91.1%, respectively) than in oocytes injected with DTT-treated sperm (22.1, 30.2 and 72.1%, respectively). No differences in embryo development and total cell number of blastocysts were observed between two groups of oocytes. In Exp. 3, motile frozen-thawed or fresh sperm without DTT pretreatment were injected into oocytes. The rates of fertilization and MPN formation were significantly higher (P < 0.05) in oocytes injected with fresh sperm (59.8 and 73.5%) than in oocytes injected with frozen-thawed sperm (36.7 and 59.2%). No differences in embryo development and total cell number of blastocysts were observed between two groups of oocytes. In conclusion, the present study clearly demonstrated that sperm movement in the ooplasm, use of DTT and fresh spermatozoa did not significantly affect on embryo development in porcine modified ICSI.     

Transcervical artificial insemination in sheep: effects of a new transcervical artificial insemination instrument and traversing the cervix on pregnancy and lambing rates

Cervical anatomy limits the use of transcervical intrauterine artificial insemination (TC AI) in sheep. We have developed an instrument to cope atraumatically with the cervix; although this instrument has not affected fertilization rate or pregnancy rate through Day 3, the effects on sperm transport and pregnancy after Day 3 are not known. The objective of the present study was to determine whether our TC AI instrument affected sperm transport, pregnancy rates, or lambing rate. In Experiment 1, ewes were assigned to two treatments: TC AI using the new TC AI instrument (n=10) or AI via laparotomy using a laparoscopic AI instrument (n=10). Twenty hours after artificial insemination, the uterine horns and oviducts were recovered and flushed to collect spermatozoa. Sperm transport did not differ (P>0.05) between the two treatments. In Experiment 2, ewes were assigned to three treatments: TC AI using the new TC AI instrument+sham intrauterine AI via laparotomy (n=29); sham TC AI+intrauterine AI via laparotomy using a laparoscopic AI instrument (n=29); and sham TC AI+intrauterine AI via laparotomy using the new TC AI instrument (n=30). On Day 14 after AI, uteri were collected and flushed to recover blastocysts. Transcervical deposition of semen reduced (P<0.05) Day 14 pregnancy rate (17.2% versus 61%), but intrauterine deposition of semen using the TC AI instrument via midventral laparotomy increased (P<0.05) Day 14 pregnancy rate (76.6% versus 44.8%). In Experiment 3, ewes were assigned to two treatments: sham cervical manipulation (n=40) or cervical manipulation to mimic TC AI (n=40). Immediately after treatment, each ewe was mated with a ram and watched until the ram mounted and ejaculated into the ewe. Treatment did not affect Day 30 or 50 pregnancy rate (67.5 and 66.2%, respectively), determined ultrasonically, or lambing rate (62.5%). The differences between Days 30 and 50 pregnancy rates and lambing rate were not significant. In Experiment 4, ewes were assigned to two treatments: TC AI (n=99) or laparoscopic AI (n=99). Transcervical AI reduced (P<0.01) Day 30 (TC AI versus laparoscopic AI; 5.0% versus 46.0%) and Day 50 pregnancy rates (4.0% versus 41.0%), determined ultrasonically, and lambing rate (4.0% versus 41.0%). Although the TC AI procedure significantly reduced pregnancy and lambing rates, large numbers of spermatozoa deposited at natural insemination seemed to compensate. Because our TC AI procedure has all but eliminated any visual evidence of trauma, and because the procedure does not seem to affect sperm transport or embryonal survival until Day 3, we speculate that cervical manipulation associated with TC AI may activate pathways that interrupt pregnancy between Days 3 and 14.     

The effect of oestrogen administered during the progestational phase of the cycle on transport of spermatozoa in ewes.

Two split-plot factorial experiments are described, the first with 72 entire cyclic ewes and the second with 80. The pattern of transport of spermatozoa through the reproductive tract was studied, following treatments with progestagen and oestrogen or with oestrogen alone during 2 weeks preceding insemination. A daily dose of 25 mug oestradiol-17 beta administered to ewes for 14 days preceeding oestrus had a deleterious effect on the passage of spermatozoa through the cervix into the uterus within the first 2 hr after insemination. The numbers of spermatozoa recoverable from the cranial region of the cervix 2 hr after insemination appeared to be related to the numbers in the oviducts at 24 hr. These numbers were related to fertility data from an earlier experiment using similar treatments. The data for log numbers of spermatozoa recoverable from the cervix formed a near-normal distribution and so were suitable for formal statistical analysis. There was an interaction between progestagen and oestrogen influence before mating on the pattern of sperm transport through the cervix.     

Ovulation rates of first cross booroola compared with local breed ewes following differential feeding

The effect of at least 6 weeks of differential nutrition (high v. low plane) on live weight and ovulation rate was studied in Booroola cross ewes with (F+) and without (++) the putative Booroola gene for fecundity, and non-Booroola local breed ewes. In three experiments, significant differences (range 8–9.6 kg) in live weight at laparoscopy resulted from the differential feeding. Across genotypes, differences in ovulation rate between high and low plane ewes approached significance in Exp. 1 (2.11 vs. 1.76) and were significant in Exp. 2 (1.83 vs. 1.59) and Exp. 3 (2.68 vs. 2.20). Despite significantly higher ovulation rates in F+ Booroola cross ewes compared with ++ ewes (2.99 vs. 1.45), there was no significant interaction between nutrition and genotype; that is, both Booroola genotypes, and non-Booroola ewes exhibited similar ovulation rate responses to nutritionally induced differences in live weight.     

Regulation of the estrous cycle in ewes with progestin containing implants: Influence of dose and day of cycle at treatment

Implants containing Norgestomet (G. D. Searle and Co., Chicago) were inserted subcutaneously in ewes on selected days of the estrous cycle. When ewes were treated for 13 days with 2 or 3 mg Norgestomet, implantation 13 days post-estrus reduced the number of ewes in estrus within 5 days of implant removal and reduced the number of estrous ewes that lambed compared with ewes implanted 4 days post-estrus. When ewes were implanted with 3 or 6 mg Norgestomet 4 or 13 days post-estrus, no difference in estrus response was found. Conception rate was not influenced by day of treatment, but was higher in those ewes treated with 6 mg than ewes treated with 3 mg. Compared to no treatment, treatment with 3 or 6 mg Norgestomet reduced the number of uterine and oviducal sperm recovered 12 or 24 hr after insemination from ewes implanted for 12 days 2 or 12 days post-estrus. However, more sperm were recovered from ewes treated 2 days than 12 days post-estrus with the principal increase occurring in ewes treated with 6 mg of Norgestomet.     

Continuous live-dead discrimination of ram sperm during freezing

Use of the dye amaranth (Color Index 16185) as a supravital stain for ram sperm is described. At a concentration of 0.4% in diluted semen, the dye was completely excluded by motile sperm and had no effect on sperm motility. The nuclei of immotile sperm were stained pink by amaranth. The decrease in sperm motility during 24-h storage at 5°C was accompanied by a corresponding increase in stained sperm nuclei. The presence of the dye during freezing had no effect on sperm cryosurvival but tended to reduce sperm motility during post-thaw incubation. Insemination of ewes with fresh semen containing amaranth or with semen frozen in the presence of amaranth resulted in pregnancies in 7/10 ewes in each group, compared to 6/9 in the case of ewes inseminated with fresh semen without dye.     

Effect of injected bovine interferon-alpha I1 on estrous cycle length and pregnancy success in sheep

In Exp. 1 twice daily i.m. injections of 2 mg recombinant bovine IFN-alpha I1 (rboIFN-alpha I1) (N = 24) or placebo (N = 25) were administered to ewes from Day 12 to Day 16 during a normal oestrous cycle. Treatment did not increase (P greater than 0.10) oestrous cycle length (20.7 +/- 1.2 versus 18.5 +/- 1.4 days). In Exp. 2, ewes were injected twice daily with 2 mg IFN (N = 34) or placebo (N = 36) from Days 11 to 18 after natural mating. The rboIFN-alpha I1 significantly (P = 0.05) improved pregnancy rate (79% versus 58%) as determined by a failure of ewes to return to oestrus within 50 days. The number of ewes that lambed was greatest in the rboIFN-alpha I1-treatment group (71% versus 50%; P = 0.07), and no teratogenic effects were observed in the young born to IFN-treated ewes. The study was repeated a second year with a more fecund group of ewes (Exp. 3). More (P = 0.08) ewes injected with rboIFN-alpha I1 (58/65) than placebo-treated ewes (48/61) were judged pregnant by ultrasound. Again more ewes lambed (55 versus 45) and more lambs were born (98 versus 80) from the rboIFN-alpha I1-treated group. Combining the data from both studies revealed a significant (P = 0.01) effect of treatment. The amount of antiviral activity in jugular vein blood of ewes injected with rboIFN-alpha I1 (2 mg) was determined over time in Exp. 4. Activity rose to a maximum (approximately 450 IRU/ml) within 1-2 h and declined by over 75% in 24 h. Single injections of 1, 2 and 5 mg in buffer or 2 mg emulsified in sesame oil all gave similar profiles of antiviral activity in jugular blood over a 48-h period. In Exp. 5, antiviral activity was measured in uterine vein, ovarian artery and jugular vein serum of untreated pregnant (N = 7) and non-pregnant (N = 11) ewes at Day 15 after mating. Activity was detected in the uterine vein (58 +/- 19 IRU/ml) of all pregnant ewes. The observations in Exps 1-5 are consistent with a role for conceptus-derived IFN-alpha in maternal recognition of pregnancy and suggest that supplemental IFN-alpha might be useful in improving pregnancy success in sheep.     

Sperm transport and motility in the mouse oviduct: observations in situ

Sperm transport and motility were studied through the transparent walls of the mouse oviduct by direct microscopic observation and videomicrography. Observations were made on excised female tracts 1-2 h post-coitus (pc) and 1-2 h before and after the approximate time of ovulation. Motile sperm were seen at the uterine entrance to the uterotubal junction (UTJ) in all females at 1-2 h pc, but in fewer females at later times. The intramural UTJ was usually constricted and held few sperm. The extramural UTJ and adjacent lower isthmus contained many motile sperm at 1-2 h pc. Apparently, the column of sperm moved upwards because in some females, sperm were found in the upper isthmus and not in the UTJ at the later time points. Few sperm were seen in the ampulla in the periovulatory period, and none at 1-2 h pc. There appeared to be two mechanisms retaining sperm in the lower oviduct: immobilization and adherence to the epithelium. Columns of immotile sperm were seen in the lower isthmus of some females. Motile sperm usually appeared to adhere by their heads to the oviductal epithelium, only occasionally breaking free to move vigorously about the lumen.     

Calcium alters capacitation and progressive motility of uterine spermatozoa from +/+ and congenic tw32/+ mice.

The importance of calcium-dependent sperm processes for fertilization in vitro is well known, but their interaction with sperm transport in vivo is not yet clear. To determine whether exposure to calcium alters sperm physiology after incubation in the uterus, spermatozoa from +/+ mice were incubated in medium with 1.7 mM calcium prior to artificial insemination (AI). Spermatozoa from congenic tw32/+ mice were also tested because their flagella are hypersensitive to calcium. As a control, spermatozoa were incubated in calcium-deficient medium before AI. When recovered from the uterus 60 min post-AI, neither prior exposure to calcium nor genotype affected numbers of spermatozoa, or percentage of motile or acrosome-reacted spermatozoa. However, significantly more calcium-treated spermatozoa were capacitated and significantly fewer were progressively motile than spermatozoa preincubated without calcium. In addition, significantly fewer spermatozoa from tw32/+ mice than from +/+ mice were progressively motile. These results suggest that uterine sperm physiology is changed by prior exposure of sperm to calcium. Since the level of progressive motility of spermatozoa recovered from the uterus was correlated with their ability to reach the oviduct (as determined in a previous study), these data support the hypothesis that progressive motility of uterine spermatozoa is important for passage to the oviduct and fertility.     

Inhibition of an IUD-induced precocious luteolysis by prostaglandin E1 (PGE1) in sheep

Fifteen ewes were assigned as they came into estrus to one of three randomized treatment groups: 1. Sham IUD + Vehicle, 2. IUD + Vehicle or 3. IUD + PGE1 in vehicle. An IUD was inserted adjacent to the luteal-bearing ovary on day 3 postestrus. Prostaglandin E1 (500 micrograms) in vehicle (Na2CO3) or vehicle was given intrauterine through an indwelling uterine cannula every four hours from day 3 postestrus until ewes returned to estrus. Precocious estrus was induced in both the sham IUD and IUD groups receiving vehicle. Prostaglandin E1 prevented an IUD-induced premature luteolysis based on daily concentrations of progesterone in peripheral blood and the interestrous interval. It is concluded that an IUD-induced premature luteolysis is not necessarily via physical distention by the IUD. It is also concluded that chronic intrauterine infusions of PGE1 can prevent an IUD-induced premature luteolysis.     

Movement of cynomolgus and rhesus monkey spermatozoa collected from the lower female reproductive tract

Postcoital (pc) cervical mucus was collected in 73 menstrual cycles of cynomolgus monkeys and in 43 cycles of rhesus monkeys at 2,6,10,30 hr pc. Videomicrography was used to analyze sperm numbers and movement in the mucus. Both cynomolgus and rhesus monkeys had comparable populations of motile sperm in the mucus at 2 hr pc. However, by 6 hr pc, cervical mucus from cynomolgus monkeys contained twice as many total sperm and motile sperm as mucus from rhesus monkeys (P <.05). Mean swimming speeds of the free-swimming cervical sperm were similar for the two species at this time. No motile sperm were recovered in mucus from rhesus monkeys at 30 hr pc. In cynomolgus monkeys, however, 14 of the 26 animals examined at 30 hr pc had motile sperm in their mucus. These sperm exhibited lower percent molility, percent free-swimming sperm, and swimming speed than those sperm observed at 6 hr pc. Uterine sperm were collected by transcervical or transuterine aspiration from cynomolgus monkeys. In the transcervical technique, sperm were successfully obtained in four of nine animals examined at 6 hr and in four of five animals at 30 hr pc. The percentage of motile sperm in the uterine fluid was high, 82% ± 4%, and the swimming speeds (86 ± 2μm/sec) were higher than those observed in cervical mucus. Approximately 5–10% of the uterine sperm exhibited swimming motions similar to the hyperactivated motility seen in most mammals. These findings indicate that the sperm cervical mucus interaction in vivo in cynomolgus monkeys has more similarities to the human situation than does the interaction in rhesus monkeys.     

Cervical dilation with exogenous oxytocin does not affect sperm movement into the oviducts in ewes

Exogenous oxytocin aids in the transcervical passage of an AI gun into the uterus of ewes, and it may be an effective adjunct to sheep AI procedures. However, the effects of oxytocin on sperm transport and fertility are unclear. Thus, experiments were conducted to evaluate the effects of oxytocin on variables that may affect fertility. In Experiment 1, five ewes/group received intravenous injections of 0, 50, 100, 200 or 400 USP units of oxytocin. Oxytocin enhanced (P < 0.001) uterine entry; the rates were 0% for control, 60% for the 50- and 100-unit doses, and 100% for the 200- and 400-unit doses. In Experiment 2, five ewes/group received intravenous injections of 0, 50, 100, 200, or 400 USP units of oxytocin, and the effect on uterine contractions was observed with a laparoscope. Oxytocin induced myometrial tetany within 2 min. The dose affected (P < 0.05) the duration of tetany, which was 0, 21, 27, 29, and 41 min for the 0-, 50-, 100-, 200- and 400-unit doses, respectively. In Experiment 3, either 0 or 200 USP units of oxytocin were injected intravenously 52 h after removal of progestogen pessaries from 20 ewes. Ewes were inseminated laparoscopically 10 min later with fresh, extended semen (500 × 10⁶ sperm cells) into the right uterine horn. Ewes were slaughtered 20 h after AI, and the numbers of spermatozoa were determined. Oxytocin did not affect (P > 0.05) the movement of spermatozoa throughout the uterus and into both oviducts. In summary, oxytocin induced myometrial tetany and permitted the passage of the tip of an AI gun into the uterus. However, oxytocin did not disrupt sperm transport to the oviducts. We conclude that oxytocin-induced cervical dilation may be a useful adjunct to transcervical intrauterine AI procedures for sheep.