Equine sperm-oocyte interaction: results after intraoviductal and intrauterine inseminations of recipients for oocyte transfer

In vitro maturation of equine oocytes followed by two vitrification protocols and subjected to either intracytoplasmic sperm injection (ICSI) or parthenogenic activation

The aim of this study was determine the viability and developmental competence of equine oocytes after IVM and vitrification using the Rapid-I method, as part of an effort to develop an effective equine oocyte vitrification protocol. Equine oocytes were collected by scraping ovarian follicles of slaughtered mares. A total of 1052 ovaries were used in this study, from which 3135 oocytes were obtained. Of the 2853 oocytes retrieved, 2557 underwent in vitro maturation for approximately 36 h. After in vitro culture, 1202 oocytes (47%) had a first polar body. To evaluate the toxicity of the solutions (Experiment I), oocytes were exposed to vitrification media without cryopreservation. Of all the experimental groups evaluated, the best results were obtained for IVM oocytes exposed to EquiproVitKit media (IVM + TOX EquiVitKit), with a viability rate of 69.5%. In the Experiment II, oocytes, either freshly collected from the ovary or after in vitro maturation (IVM), were vitrified using either the EquiPro VitKit or an in-house medium containing 18% Ficoll, 40% ethylene glycol and 0.3 M sucrose. Oocytes were stained with fluorescein diacetate and ethidium bromide to evaluate viability. In vitro matured oocytes vitrified using EquiproVitKit media (IVM + VIT EquiVitKit) had a cryosurvival rate of 63%. In the last part of the study (Experiment III), vitrified IVM oocytes were activated by 7.5 μM ionomycin in TCM-199 for 5 min TCM 199 (5 min) combined with 2 mM 6-DMAP in TCM-99 with 10% FBS (4.5 h) or in vitro fertilized using ICSI. Development of potential embryos after activation in TCM-199 medium, showed a cleavage rate was 10.2%, compared to 22.5% of oocytes cultured in G1/G2 medium. ICSI of vitrified IVM oocytes resulted in 20% embryo development to the 16-cell stage, compared to 33.3% in the control. The vitrification of oocytes after IVM by Rapid-I method is a good way to preserve genetic material in horses.

Use of different pressures for transvaginal follicular aspiration in mares

ABSTRACT The success of transvaginal follicular aspiration in mares can be influenced by several factors, such as vacuum pump pressure levels. The present study aimed to investigate the effect of different negative pressures (150, 280 and 400mmHg) of the vacuum pump on the oocyte recovery in the mares. The mares (n=10) were undergoing follicular aspiration using three different negative pressures for three consecutive estrous cycles as follows: G150 = 150mmHg (n = 10); G280 = 280mmHg (n = 10); G400 = 400mmHg (n = 10). Every estrous cycle, the group that the mare would participate was drawn, and each animal participated once in each group. Only preovulatory follicle was used, about 30 to 36 hours after application of hCG. To compare the results, the chi-square test was used (5% significance) and Fisher exact test, when recommended. Thirty preovulatory follicles (diameter 36.1±1.80mm) were aspirated and ten oocytes were recovered (33.3%). There was no statistical difference between the experimental groups (p=0.59). Thus, accord to the results observed in this study, we could conclude that the negative pressure of the vacuum pump used was not efficient to increase oocyte recovery.

Assisted reproduction techniques in the horse

This paper reviews current equine assisted reproduction techniques. Embryo transfer is the most common equine ART, but is still limited by the inability to superovulate mares effectively. Immature oocytes may be recovered by transvaginal ultrasound-guided aspiration of immature follicles, or from ovaries postmortem, and can be effectively matured in vitro. Notably, the in vivo-matured oocyte may be easily recovered from the stimulated preovulatory follicle. Standard IVF is still not repeatable in the horse; however, embryos and foals can be produced by surgical transfer of mature oocytes to the oviducts of inseminated recipient mares or via intracytoplasmic sperm injection (ICSI). Currently, ICSI and in vitro embryo culture are routinely performed by only a few laboratories, but reported blastocyst development rates approach those found after bovine IVF (i.e. 25%–35%). Nuclear transfer can be relatively efficient (up to 26% live foal rate per transferred embryo), but few laboratories are working in this area. Equine blastocysts may be biopsied via micromanipulation, with normal pregnancy rates after biopsy, and accurate genetic analysis. Equine expanded blastocysts may be vitrified after collapsing them via micromanipulation, with normal pregnancy rates after warming and transfer. Many of these recently developed techniques are now in clinical use.

Fertilidade de éguas inseminadas no corpo ou no ápice do corno uterino com diferentes concentrações espermáticas

Foram utilizados 72 ciclos estrais de 37 éguas mestiças, com idade variando de quatro a 20 anos, distribuídas ao acaso em dois grupos experimentais (G I e G II) para estudar o efeito do local de deposição do sêmen no sistema genital sobre a fertilidade. As inseminações no ápice do corno uterino (G II) foram realizadas por via intravaginal profunda, utilizando-se a pipeta de inseminação IVI pippette (75cm), contendo 1/5 (3mL) da dose inseminante utilizada para o corpo do útero (15mL-G I). As éguas foram rufiadas diariamente e inseminadas às segundas, quartas e sextas-feiras, a partir de um folículo de 3,0 a 3,5cm de diâmetro, com sêmen fresco diluído em diluidor de leite desnatado-glicose. Apenas um garanhão de 20 anos e de fertilidade conhecida foi utilizado. As taxas de concepção/ciclo para as inseminações realizadas no corpo (42,9%-15/35) e ápice do corno uterino (45,9%-17/37) com concentrações médias de 489 e 102 milhões de espermatozoides móveis, respectivamente, não foram diferentes (P>0,05).

Advanced insemination techniques in mares

Advanced artificial insemination techniques, such as deep uterine,hysteroscopic, oviductal, and intrafollicular insemination, are described in the context of the different types of spermatozoa that are now available for insemination, including fresh, chilled, frozen,sex-sorted, and epididymal spermatozoa. The implementation of these new technologies answers and poses questions about the interactions of sperm and oocytes in vivo.

Factors affecting the success of oocyte transfer in a clinical program for subfertile mares

Oocyte transfer is a potential method to produce offspring from valuable mares that cannot carry a pregnancy or produce embryos. From 2000 through 2004, 86 mares, 19.2 +/- 0.4 yr of age (mean +/- S.E.M.), were used as oocyte donors in a clinical program at Colorado State University. Oocytes were collected from 77% (548/710) of preovulatory follicles and during 96% (548/570) of cycles. Oocytes were collected 21.0+/-0.1h after administration of hCG to estrous donors and cultured 16.4 +/- 0.2 h prior to transfer into recipients' oviducts. At 16 and 50 d after transfer, pregnancies were detected in 201 of 504 (40%) and 159 of 504 (32%) of recipients, respectively, with an embryo-loss rate of 21% (42/201). Pregnancy rates were similar (P > 0.05) for cyclic and noncyclic recipients and for recipients inseminated with cooled, fresh or frozen semen. One or more recipients were detected pregnant at 16 and 50 d, respectively, for 80% (69/86) and 71% (61/86) of donors. More donors <20 than > or = 20 yr (mean ages +/- S.E.M. of 15.5 +/- 0.4 and 23.0 +/- 0.3 yr, respectively) tended (P = 0.1) to have one or more pregnant recipients at 50 d (36/45, 80%; 28/45, 62%, respectively). Results of the program confirm that pregnancies can consistently be obtained from older, subfertile mares using oocyte transfer.

Low-dose insemination—Why, when and how

The typical dose for insemination into the uterine body of the mare is > 300 x 10(6) progressively motile spermatozoa (PMS) and an insemination dose of > 200 x 10(6) PMS is recommended for frozen-thawed semen. Low-dose insemination techniques allow for a drastic reduction in the numbers of spermatozoa required to achieve pregnancy. Acceptable pregnancy rates can be achieved with doses ranging from 1 to 25 x 10(6) PMS in volumes ranging from 20 to 1000 microL. Two techniques have been described: hysteroscopic insemination and transrectally guided deep horn insemination using a pipette. Similar pregnancy rates can be attained by either method when 5 x 10(6) PMS are used. Hysteroscopic insemination may provide an advantage when the dose is 1-3 x 10(6) PMS. These techniques have the potential to make more efficient use of frozen-thawed or sex-sorted semen from certain stallions. The use of low-dose insemination to improve fertility of infertile stallions warrants further investigation.

Use of parentage testing to determine optimum insemination time and culture media for oocyte transfer in mares

Parentage identification was used to test the developmental competence of oocytes cultured under different conditions and fertilized in vivo after oocyte transfer. Oocytes were collected transvaginally from follicles of estrous mares approximately 22 h after administration of human chorionic gonadotropin. Oocytes were cultured for approximately 16 h in one of three media, with or without addition of hormones and growth factors. Groups of three or four oocytes, cultured in different media, were transferred into the oviduct contralateral to a recipient’s own ovulation. Recipients were inseminated with semen from two different stallions at 15 h before and 2.5 h after oocyte transfer. Sixteen days after transfer, embryos were recovered from uteri and submitted for parentage testing. The percentage of oocytes resulting in embryonic vesicles was nearly identical (P > 0.05) for transferred oocytes (32/44, 73%) versus ovulated oocytes of recipients (9/13, 69%). More (P < 0.01) oocytes were fertilized by sperm inseminated before (35/38, 92%) versus after (3/38, 8%) oocyte transfer. Tissue culture medium (TCM)-199 was superior to equine maturation medium I (EMMI; a SOF-based medium) for culturing oocytes (P < 0.05), although addition of hormones and growth factors during culture did not improve (P > 0.05) development of embryos.

Oocyte transfer and gamete intrafallopian transfer in the mare

Methods for the collection and transfer of equine oocytes have been developed, and uses of these techniques have resulted in new clinical and research possibilities. Because oocyte transfer avoids reproductive problems associated with the oviduct, uterus, and cervix, pregnancies can be produced from many mares that cannot carry a pregnancy or produce embryos. Oocytes for clinical transfers are usually collected from preovulatory follicles and cultured for a short interval or transferred directly into a recipient's oviduct. For oocyte transfer, the recipient is inseminated within the uterus. A large number (1 x 10(9) to 2 x 10(9)) of motile sperms are preferred for inseminations. In contrast, sperm and oocyte are transferred into the oviduct during gamete intrafallopian transfer (GIFT). Therefore, a lower number (1 x 10(5) to 2 x 10(5)) of sperm can be used. Potentially, GIFT could be used in situations where sperm numbers are limited. Use of oocyte transfer and GIFT in clinical and research settings will aid us in understanding the interactions between oocyte, sperm, and oviduct in the equine.

Low dose insemination in the mare: an update

The generally recommended minimum number of spermatozoa required for conventional artificial insemination in the mare is in excess of 200 x 10(6) progressively motile spermatozoa. Recent developments in different insemination techniques such as deep uterine, hysteroscopic and oviductal insemination, which have been designed to use significantly fewer spermatozoa, are reviewed in this paper. A number of studies have demonstrated that ultrasound guided deep uterine insemination of 5 x 10(6) fresh spermatozoa can produce satisfactory pregnancy rates. The use of hysteroscopic insemination enables the insemination dose to be successfully reduced to 1 x 10(6) fresh or 3 x 10(6) frozen-thawed spermatozoa. Further reduction of the insemination dose is possible and satisfactory pregnancy rates can also be achieved by surgical oviductal insemination of mares with as few as 2 x 10(5) fresh spermatozoa. The refinement of these insemination techniques will allow us to maximise the use of frozen-thawed semen, use new technology such as sex-preselection of spermatozoa and to conserve and utilise epididymal spermatozoa at the time of castration or death of a stallion.

Oocyte transfer in mares with intrauterine or intraoviductal insemination using fresh, cooled, and frozen stallion semen

The objectives were to compare embryo development rates after oocyte transfer with: (1) intrauterine or intraoviductal inseminations of fresh semen versus intraoviductal insemination of frozen semen; (2) intraoviductal versus intrauterine inseminations of cooled semen. In Experiment I, oocytes were transferred into the oviduct, and recipients were inseminated into the uterus with 1 x 10(9) fresh spermatozoa, or into the oviduct with 2 x 10(5) fresh or frozen-thawed spermatozoa. In Experiment II, semen was cooled to 5 degrees C before intrauterine insemination with 2 x 10(9) spermatozoa or intraoviductal inseminations of 2 x 10(5) spermatozoa (deposited with the oocytes). In Experiment I, embryo development rates were similar (P>0.05) for intrauterine versus intraoviductal inseminations when fresh semen was used (8/14, 57% and 9/11, 82%, respectively). However, embryo development rates were lower (P<0.05) when frozen spermatozoa were placed within the oviduct (1/12, 8%). In Experiment II, embryo development rates were higher (P<0.05) when cooled semen was used for intrauterine (19/23, 83%) versus intraoviductal (4/16, 25%) inseminations. We concluded that intraoviductal insemination can be successfully performed using fresh spermatozoa. However, the use of cooled and frozen spermatozoa for intraoviductal inseminations was less successful, and needs further investigation.

Pregnancies attained after collection and transfer of oocytes from ovaries of five euthanatized mares

After euthanasia, ovaries were removed from 5 horses and shipped to a laboratory where 46 oocytes were collected. The oocytes were cultured for 24 to 30 hours, and 36 oocytes were transferred to 10 recipient mares via flank laparotomies. Recipient mares were inseminated with semen from various stallions. Sixteen days after transfer, 4 of the recipients were pregnant with at least 1 embryonic vesicle. Embryonic death occurred in 3 recipients, whereas a healthy live foal was born from 1 recipient. Ovaries from valuable mares can be a source of viable oocytes after death of the mare. For shipping to a laboratory, fluctuations in temperature should be minimized and the ovaries should not be chilled.