Autotransfer of Day 4 embryos from oviduct to oviduct versus oviduct to uterus in the mare

Embryo autotransfer is defined as the collection of an embryo from and the transfer of this embryo into the same animal. The objectives of this study were to: 1) test the hypothesis that oviduct transport of the equine embryo from the oviduct into the uterus is not dependent on a unilateral embryo-corpus luteum interaction, 2) develop an embryo autotransfer technique for the mare and 3) compare the success rates of Day 4 embryos surgically autotransferred from the oviduct ipsilateral to ovulation to either the oviduct (n=10 mares) or the uterine horn (n=10 mares) contralateral to ovulation. Seventy percent (7 10 ) of the Day 4 embryos which were autotransferred to the oviduct contralateral to ovulation were transported through the oviduct and subsequently developed into embryonic vesicles detectable by ultrasonography between 10 and 21 days postovulation. This finding supported the hypothesis that oviductal embryo transport is not dependent upon the ipsilateral corpus luteum. Overall, sixty percent (12 20 ) of the autotransfers were successful. The success rate of uterine-transferred embryos was not significantly less (P>0.3) than that of oviductal-transferred embryos (5 10 vs 7 10 , respectively). Therefore, the Day 4 equine embryos were apparently mature enough to survive in the mare's uterus.     

Oviductal and uterine influence on the development of Day-2 equine embryos in vivo and in vitro

The objective of this experiment was to contrast the influence of the oviductal and uterine environments on development of Day-2 embryos. Embryos were transferred to oviducts or uteri of synchronous recipient mares, or were incubated in oviductal co-culture, in uterine co-culture or in defined culture medium. Significantly more (P < 0.02) embryos transferred to the oviduct versus the uterus survived until Day 11 after ovulation (5 7 vs 0 7 , respectively). Significantly more (P < 0.001) embryos developed to expanded and hatched blastocysts in uterine co-culture than in culture medium (6 7 vs 0 7 , respectively). The rate of embryo development to expanded blastocysts was not significantly different (P > 0.1) in oviductal co-culture versus uterine co-culture (3 7 vs 6 7 , respectively), or in oviductal co-culture versus culture in medium (3 7 vs 0 7 , respectively). Three of 7 and 6 of 7 embryos developed to hatched blastocysts greater than 2000 mum in diameter during oviductal and uterine co-culture, respectively, while 0 of 7 embryos cultured in medium expanded to greater than 500 mum in diameter. Proportions of embryos that developed for at least 9 days.     

Hastened transport of equine embryos through the oviduct of the mare

The purposes of this experiment were 1) to test the hypothesis that placing rabbit embryos into the mare's uterus would hasten oviduct transport and 2) to determine if placing fluid into the uterus of bred mares on Day 4 and/or Day 5 would subsequently disrupt the mare's pregnancy. The hypothesis that placing rabbit embryos into the mare's uterus would hasten oviduct transport was not supported, since the uterine recovery rate of equine embryos on Day 5 was not significantly higher (P>0.05) for mares receiving rabbit embryos on Day 4 than for mares receiving no uterine infusion on Day 4 (1 10 vs 0 10 , respectively). However, placing fluid into the mare's uterus on Day 4 was apparently responsible for hastened oviduct transport, since mares with media infused into the uterus on Day 4 had a significantly higher (P<0.05) recovery rate of equine embryos on Day 5 than did mares receiving either rabbit embryos or no uterine infusion on Day 4 post ovulation (5 10 vs 1 10 or 0 10 , respectively). The Day-14 pregnancy rate was significantly higher (P<0.05) for mares receiving no uterine infusion on Day 4 or Day 5 than for mares receiving uterine infusion on Day 5 or uterine infusion on both Days 4 and 5 (9 10 vs 4 10 , 2 10 and 0 10 , respectively).     

Time of embryo transport through the mare oviduct

The objectives of this study were 1) to determine the time of embryo transport through the mare oviduct, 2) to determine whether equine embryos increase in diameter prior to the time of oviductal transport, and 3) to assess the stage of equine embryonic development at the time of oviductal transport. The time of oviductal transport (interval from ovulation to uterine entry) was estimated by collecting embryos from the mare oviduct or uterus at 2-hour intervals from 120 to 168 h postovulation. The time of oviductal transport was 130 to 142 h, since 9 9 embryos were located in the oviduct from 120 to 128 h; 7 14 embryos were in the oviduct and 7 14 embryos were in the uterus from 130 to 142 h; and 13 14 embryos were in the uterus from 144 to 168 h postovulation. Embryos collected during the period of oviductal transport (130 h to 142 h) were not significantly larger (P>0.1) in diameter than embryos collected prior to the period of oviductal transport (162.5+/-3.7 vs 156.7+/-3.1 mum, respectively). During the period of oviductal transport, embryos collected from the uterus were not significantly larger (P>0.1) in diameter than embryos collected from the oviduct (160.7+/-3.2 vs 164.3+/-7.0 mum, respectively). During this same period 12 14 embryos were compact morulae, and 2 14 embryos were blastocysts.     

Effects of cervical dilation and intrauterine infusions on the timing of oviductal transport of equine embryos

Equine embryos spend 5 to 6 d in the oviduct before entering the uterus as expanded blastocysts, and cannot be consistently collected nonsurgically until Day 7. Technologies such as cryopreservation and embryo splitting, which are most successful with embryos at the morula or early blastocyst stage, have not been used in mares because equine morulae and early blastocysts are located in the oviduct and cannot be recovered nonsurgically. These experiments test the hypothesis that transport of equine embryos through the oviduct can be hastened by cervical dilation or by acute, sterile endometritis induced by intrauterine oyster glycogen treatment. Cervical dilation with or without intrauterine infusion of 0.5 ml PBS on Day 4 did not appear to hasten the transport of embryos into the uterus since Day 5 uterine embryo recovery rates were not higher (P > 0.1) for mares with cervical dilation or cervical dilation plus PBS infusion vs mares receiving no treatments (0 of 5 and 0 of 5 vs 0 of 10, respectively). Intrauterine infusions of 40 ml of 1% oyster glycogen or 40 ml of PBS on Day 3 did not appear to hasten the transport of embryos into the uterus since Day 5 uterine embryo recovery rates were not higher (P > 0.1) for oyster glycogen- or PBS-treated vs untreated mares (2 of 12 and 3 of 11 vs 0 of 10, respectively). Cervical and uterine treatments on Day 3 or Day 4 and uterine lavages on Day 5 decreased (P < 0.05) Days 11 to Day 15 pregnancy rates compared with that of untreated mares. Day 11 to Day 15 pregnancy rates were 1 of 5 for mares with Day 4 cervical dilation and Day 5 uterine lavage, 1 of 5 for mares with Day 4 PBS infusion and Day 5 uterine lavage, 2 of 12 for mares with Day 3 oyster glycogen infusion and Day 5 uterine lavage, and 3 of 11 for mares with Day 3 PBS infusion and Day 5 uterine lavage vs 7 of 10 for mares that received no treatment or lavage. Cervical and uterine manipulations on Day 3 or 4 and uterine lavage on Day 5 appeared to decrease pregnancy rates by Days 11 to 15. The results of these experiments do not support the hypothesis that cervical dilation or uterine infusion hasten oviductal transport, since neither cervical manipulation nor transcervical infusion of oyster glycogen or PBS into the uterus significantly hastened the rate of embryo transport into the uterus.     

Survival of equine embryos co-cultured with equine oviductal epithelium from the four- to eight-cell to the blastocyst stage after transfer to synchronous recipient mares

In this study we examined the ability of equine oviductal epithelial cells (OEC) to support the development of four- to eight-cell equine embryos in vitro and investigated the ability of co-cultured embryos to continue normal development after transfer to synchronous recipient mares. Equine embryos obtained at Day 2 after ovulation were cultured with or without OEC for 5 days. Those OEC co-cultured embryos that reached the blastocyst stage and embryos recovered from the uterus at Day 7 were surgically transferred to synchronous recipient mares. Co-culture with OEC improved (P < 0.01) development of four- to eight-cell embryos to blastocysts compared to medium alone (11/15 vs 0/6) during 5 days in vitro. Embryos co-cultured with OEC were smaller (P < 0.05) and more delayed in development than Day-7 uterine blastocysts. There was no difference in the Day-30 survival rate of co-cultured blastocysts (3/8) or Day-7 uterine blastocysts (5/8) after transfer to recipient mares. These results indicate that co-culture with OEC can support development of four- to eight-cell equine embryos in vitro and that co-cultured embryos can continue normal development after transfer to recipient mares.     

Survival of bisected rabbit morulae transferred to synchronous and asynchronous recipients

The rabbit was used as a model to test the concept that temporal asynchrony is required to establish physiological synchrony when embryos are bisected to produce demiembryos. In preliminary studies with intact embryos it was confirmed that embryos harvested on days 2, 3, 4, or 5 (day 0 = day of breeding) can be transferred with +/- 1 day of asynchrony to the uteri of recipient rabbits. Three experiments were conducted with bisected embryos. In experiment 1, 192 bisected and 194 control day 3 embryos were transferred to uteri of day 2, 2.5, and 3 recipients (ovulated 0, 12, and 24 h after the donors), with 14% of the bisected and 39% of the intact embryos (P less than .05) resulting in young. Only 4% (2/48) of the day 3 bisected embryos vs. 39% (P less than .05) of the intact day 3 embryos survived in the uteri of day 2 recipients. In experiment 2, day 3 bisected and intact embryos were transferred to the oviducts of day 3, 3.5, or 4 recipients, the speculation being that the oviduct might provide a more neutral environment than the uterus. However, embryo survival was very low, except for the intact embryos transferred to synchronized recipients (42% young born). In experiment 3, 150 intact and 162 (81 pairs) bisected day 3 embryos collected from uteri were transferred to uteri of day 2.5, 3.0, and 3.5 recipient does. Significantly more pregnancies (100% vs. 47%, P less than .01) and young born (56% vs. 19%, P less than .01) resulted from intact embryos than from bisected embryos, irrespective of the uterine age.(ABSTRACT TRUNCATED AT 250 WORDS)     

Embryo transport through the mare's oviduct depends upon cleavage and is independent of the ipsilateral corpus luteum.

Two experiments were conducted using 14 mares. In Exp. 1, mares were inseminated with semen treated with TEPA, which, in other species, has been shown to lead to an arrest in ovum cleavage at 2--4 cells. The oviducts and/or uterus were then flushed 7--10 days after ovulation in 6 mares (Group A) or 2--6 days after ovulation in 5 mares (Group B). Fresh eggs were found in the oviduct flushes of 5 Group A and 5 Group B mares: 9 of the 10 eggs appeared to have cleaved, but none had developed beyond 16-cells. Seven eggs contained spermatozoa and 3 of 4 eggs from each group showed evidence of fertilization when examined ultrastructurally. Group A mares had thus retained fertilized eggs in the oviduct beyond the time at which they would normally have entered the uterus (6 days), indicating that development beyond at least the 2- to 4-cell stage is necessary for normal transport. In Exp. 2, 5 attempts were made to recover the embryo within 4 days of ovulation and transfer it to the contralateral oviduct. A single pregnancy resulted, indicating that a unilateral interaction with the corpus luteum was not necessary for the transport of the embryo to the uterus.     

Comparison of culture and insemination techniques for equine oocyte transfer

This study was designed to test 3 approaches for insemination and transfer of oocytes to recipient mares. Oocytes were recovered transvaginally from naturally cycling donor mares 24 to 26 h after an intravenous injection of 2500 IU of hCG when follicles reached 35 mm in diameter. Multiple oocytes (1 to 4) were transferred surgically into the oviducts of 4 or 5 recipient mares per group. Three groups of transfers were compared: 1) transfer of oocytes cultured in vitro for 12 to 14 h postcollection with insemination of the recipient 2 h postsurgery; 2) transfer of oocytes into the oviduct within 1 h of collection, with completion of oocyte maturation occurring within the oviduct, and insemination of the recipient 14 to 16 h postsurgery; and 3) transfer of spermatozoa and oocytes (cultured 12 to 14 h in vitro) into the oviduct. Numbers of embryos detected by Day 16 of gestation were not different (P>0. 1) for groups 1, 2, and 3 (57%, 43% and 27%). Therefore, equine oocytes successfully completed the final stages of maturation within the oviduct, and sperm deposited within the oviduct were capable of fertilizing oocytes.     

Possible expansion of "Window of Implantation" in pseudopregnant mice: time of implantation of embryos at different stages of development transferred into the same recipient

Blastocyst implantation and successful establishment of pregnancy require delicate interactions between the embryo and maternal environment. It is believed that the growth of transferred embryos of different ages is synchronized during preimplantation development and that such embryos are implanted in the uterus at the same time. To define the time of synchronization for developing embryos of different ages, embryos at two different stages of development were transferred separately into the oviducts of the same recipient. We then examined the subsequent development of the embryos at various time intervals after transfer. Pronucleus (PN) stage eggs were transferred separately to the right or left oviduct of recipients on Day 0, while eight-cell embryos (8C) were transferred to the other oviduct. For 8C, 5%, 63%, and 74% of transferred embryos were implanted in the uterus at 42, 66, and 90 h posttransfer, respectively. In contrast, none of the transferred PN was implanted until 90 h posttransfer. At 90 h posttransfer, 59% of the PN had successfully implanted. Histological examination revealed that developmental stage of the embryos in both groups synchronized around 162 h posttransfer, even though the implantation was accelerated in 8C compared with PN. Our results indicate that embryos of advanced stage transferred to the oviduct implant in the uterus in advance of younger embryos and that the uterine development is synchronized at the neural plate, presomite stage. Our results strongly suggest that uterine receptivity for implantation is expandable in pseudopregnant mice.     

Limitations of oviductal transfers in swine

Eighty-six crossbred gilts were used in a series of experiments 1) to determine if eight-cell embryos enter the uterus before four-cell embryos do, and 2) to investigate the effects of transferring older, more developed embryos, either with or without intact zona pellucidae, to the oviducts of swine. Results of these experiments suggested that both four-and eight-cell embryos randomly enter the uterus on Days 3.5 to 4 (Day 0 = onset of estrus). Though there were no differences in survival rates or subsequent morphology of recovered embryos when transferred to the oviduct or uterus on Day 4, the transfer. of Day-6 embryos to the oviduct resulted in lower (P < 0.01) survival rates, and the recovered embryos were smaller (P < 0.01) than those introduced into the uterus. Survival rates were lower (P < 0.06) for zonae-free embryos transferred to the oviduct than for zonae-intact embryos; however, these differences were not evident when zonae-free embryos were transferred into the uterus. These experiments demonstrate that oviductal transfer procedures in swine are limited to zonae-intact, preblastocyst stage embryos.     

The influence of ovarian hormones on the rat oviductal and uterine concentration of noradrenaline and 5-hydroxytryptamine

This paper describes the effects of estradiol and progesterone on the concenirations of noradrenaline and 5-hydroxytryptamine in the Wistar rat oviduct and uterus. The levels of noradrenaline and 5-hydroxytryptamine are higher in the oviduct than in the uterus whereas p-tyrosine and tryptophan are similar in both tissues. Estradiol treatment reduced the oviductal concentration of noradrenaline but not 5-hydroxytryptamine in oviduct, while the concentrations of both noradrenaline and 5-hydroxytryptamine were reduced in uterine horn. The levels of noradrenaline in the oviduct and uterus in rats in estrus were lower than those of diestrous rats. Bilateral ovariectomy produced an increase in uterine noradrenaline and 5-hydroxytryptamine levels. These changes were reversed in the presence of ovarian hormones as indicated by experiments where unilateral ovariectomy was performed. Reserpine administration reduced noradrenaline concentration in both the oviduct and the uterus but did not change oviductal or uterine 5-hydroxytryptamine.These results indicate the existence of noradrenaline within postganglionic sympathetic nerve terminals and suggest that estrogens increase the utilization and the synthesis of noradrenaline in both the oviducts and the uterine horns. With respect to 5-hydroxytryptamine the data support the concept that it is mainly associated with mast cells.     

The functional importance of the oviduct in neonatally estrogenized mouse females for early embryo survival.

Eight-week-old virgin untreated female mice were induced to ovulate using equine chorionic gonadotropin (eCG) and human chorionic gonadotropin (hCG), and were then caged with males overnight. Females with a vaginal plug on the following morning were killed 24 hours later and 2-cell embryos were flushed from the oviduct. These embryos were transferred to the oviduct of 8-week-old control females, to females of the same age treated with 5 micrograms diethylstilbestrol (DES) sc in olive oil for the first 5 days after birth, or to females treated with 1 microgram estradiol-17 beta for 2 days before and 2 days after transfer (estrogen dominated/ED/females). Two days after transfer, a significantly lower number of embryos were recovered from oviducts of DES females compared to control females and a still lower number from ED females. The recovered embryos were cultured in vitro for 4 days testing trophoblast outgrowth ("implantation stage"). The incidence of embryos reaching this stage after development in DES-exposed oviducts was only half of that for embryos passing control oviducts or ED oviducts. It is concluded that the adult oviductal environment in neonatally DES-treated females significantly decreases early embryo developmental potential. The oviductal factor(s) harmful to the embryo may be related to a persistent and possibly increased level of circulating estrogen level in DES females.     

Synthetic microspheres transferred to the rat oviduct on day 1 of pregnancy mimic the transport of native ova

Microspheres of various materials and diameters were transferred microsurgically to the rat oviduct on Day 1 of pregnancy and autopsies were done at various times thereafter up to Day 10 to assess the recovery and segmental distribution of microspheres and eggs in the genital tract or the viability of embryos. The number and distribution of eggs in the treated and control sides after unilateral transfers were not different on Day 4 and 5 and the number of embryos implanted on Day 10 was not significantly affected after bilateral transfers. The segmental distribution of eggs and starch microspheres within the oviduct on Days 2, 3 or 4 showed that both are transported partly intermingled from ampulla to uterus. When microspheres of poly(DL-lactide-co-glycolide), starch, dextran or dextran blue were transferred, their distribution in the genital tract in the morning of Day 5 showed that poly(DL-lactide-co-glycolide) and dextran microspheres stayed longer in the oviduct while starch and dextran blue microspheres were transported to the uterus at the same time as the eggs. Transfer of starch microspheres of 40-60 microns to one oviduct and 180-200 microns in diameter to the opposite oviduct showed that distribution on one side was nearly identical to that of the other side from Days 2 to 5. We conclude that the behaviour of synthetic surrogate ova in rats differs from that in rabbits. The rat oviduct does not change the rate of transport of native eggs following transfer of synthetic surrogate ova.(ABSTRACT TRUNCATED AT 250 WORDS)     

Embryos of different ages transferred to the rat oviduct enter the uterus at different times

Indirect evidence of embryo signalling to the oviduct was sought in rats by examining the transport of embryos of different ages. One-cell or four-cell embryos were transferred to the oviducts of recipient rats on Day 1 of pregnancy, and the number, condition, and location of native and transferred embryos was assessed on Day 4. To control for the effect of the presence of foreign embryos and excess number of eggs and the transfer procedure upon the fate of native embryos, other groups of rats were sham-operated or left undisturbed. Recipients had a mean number of ova significantly higher than controls. In controls and recipients of 1-cell embryos, the majority of eggs reached the morula stage and all of them were located in the oviducts. In those animals receiving 4-cell embryos, half of the eggs had reached the blastocyst stage and 28% were in the uteri (p less than 0.005). These results support the idea that advanced embryos can influence the timing of their entrance to the uterus in rats.     

Decreased embryonic survival of in-vitro fertilized oocytes in rats is due to retardation of preimplantation development

Immature female rats (60-65 g) were injected with 4 i.u. PMSG on Day -2 and allocated to 3 groups. On the evening of Day 0, rats in Groups I and II were allowed to mate. Embryos were collected on Day 4 (Group I, control morulae) or Day 5 (Group II, control blastocysts) and were transferred into the oviduct or uterine horn of Day-4 pregnant recipient rats. On the transfer side of the recipients, the bursa had been peeled from around the ovary to prevent endogenous oocytes from entering the oviduct. For Group III, unmated donors were killed 65-67 h after PMSG injection. Ovulated oocytes recovered from the oviducts were fertilized in vitro and transferred 16-18 h later. Embryos developing from in-vitro fertilized (IVF) oocytes were recovered on Day 5, separated into morulae (Group IIIm) and blastocysts (Group IIIb) and transferred into Day-4 pregnant recipients similar to control embryos. Some embryos from each group were used to determine the mean number of cells/embryo. Embryo recipients were killed on Day 20. After transfer, the development of IVF oocytes was retarded compared to control embryos. IVF morulae contained significantly fewer cells/embryo than did control morulae but were able to implant and grow to fetuses, in proportions similar to controls, if transferred into the oviduct of the recipients. These results suggest that the developmental potential of rat oocytes fertilized in vitro is limited due to asynchrony between the embryo and the uterine environment at the time of implantation, rather than possible defects incurred by the oocyte during the fertilization procedure.     

In vitro maturation and transfer of equine oocytes after transport of ovaries at 12 or 22 degrees C

Transportation of equine ovaries would allow shipment of oocytes for research purposes or transfer after the death of a valuable mare. The objective of this study was to compare two temperatures for maintaining ovaries during a transport interval of 18-24 h. The goal was to obtain pregnancies after transport of ovaries, maturation of oocytes in vitro, and transfer of oocytes. Each shipment was composed of ovaries four to seven mares collected from an abattoir. From each mare, one ovary was packaged at approximately 12 degrees C, and the other was packaged at approximately 22 degrees C. Upon arrival at our laboratory, oocytes were collected and cultured for 24 h. For each transfer, between 9 and 15 oocytes from each group were placed into the oviducts of estrous mares through standing flank laparotomies. Recipients received human chorionic gonadotropin (hCG; 2000 IU, i.v.) 30-36 h before transfer (to synchronize ovulation). Recipients were inseminated 18-20 h before transfers with 2 x 10(9) progressively motile sperm. Uteri of recipients were examined with ultrasound to determine the number of developing embryos. On Day 16 ( ovulation = day 0), developing embryos were recovered by uterine lavage. Parentage verification was performed on recovered vesicles. Pregnancy rates were analyzed by Chi-square. The percentage of oocytes that developed into embryonic vesicles on Day 16 was not different between transport temperatures (22 degrees C, 13/73, 18% versus 12 degrees C, 11/73, 15%). In conclusion, pregnancies were obtained from in vitro matured oocytes that were recovered from ovaries transported for 18-24h at 12 or 22 degrees C.     

Effect of various procedures on the viability of mouse embryos containing half the normal number of blastomeres

Half embryos produced from 8-cell or compacted stages were cultured in vitro for 1-2 days and transferred to oviducts or uteri of recipients at different stages of pseudopregnancy. The proportion of live fetuses was low (8-12%), except for one group (27%) in which half embryos were cultured in vitro for 1 day and transferred into oviducts on the 1st day of pregnancy. Monozygotic twin production rate, however, was low (1 out of 10) even in this group. Fetal weight on the 18th day of gestation was significantly lower after transfer of half embryos than after transfer of similarly treated but undivided embryos. Half embryos produced from the 2-cell stage were inserted into empty zonae, embedded in agar, cultured in ligated mouse oviducts for 2-4 days and transferred to oviducts of recipient females on the 1st day of pregnancy or pseudopregnancy. When twin embryos cultured for 2-3 days were transferred to pseudopregnant recipients together with control embryos, 4 sets of monozygotic twins and 5 singletons out of 10 sets of twin embryos were obtained on Days 18-19 of gestation, giving a survival rate of 65%.     

Fertilization rates in superovulated and spontaneously ovulating mares

Embryo recovery per ovulation has been shown to be lower in superovulated mares than in untreated controls. The objectives of this study were to 1) determine whether follicles stimulated with superovulatory treatment ovulate or luteinize without ovulation, 2) determine fertilization rates of oocytes in oviducts of superovulated and control mares, and 3) evaluate viability of early stage embryos from superovulated and control mares when cultured in equine oviductal cell-conditioned medium. Cyclic mares were randomly assigned to 1 of 2 groups (n=14 per group) on the day of ovulation (Day 0): Group 1 received 40 mg of equine pituitary extract (EPE; i.m.) daily beginning on Day 5 after ovulation; mares assigned to Group 2 served as untreated controls. All mares were given 10 mg PGF(2alpha) on Day 5 and Day 6, and 3,300 IU of human chorionic gonadotropin (hCG) were administered intravenously once mares developed 2 follicles >/=35 mm in diameter (Group 1) or 1 follicle >/=35 mm in diameter (Group 2). Mares in estrus were inseminated daily with 1 x 10(9) progressively motile spermatozoa once a >/=35 mm follicle was obtained. Two days after the last ovulation the ovaries and oviducts were removed. Ovaries were examined for ovulatory tracts to confirm ovulation, while the oviducts were trimmed and flushed with Dulbeccos PBS + 10% FCS to recover fertilized oocytes. All fertilized oocytes (embryos) recovered were cultured in vitro for 5 d using TCM-199 conditioned with equine oviductal cells. Ninety-two percent of the CL's from EPE mares resulted from ovulations compared with 94% for mares in the control group (P>0.05). The percentages of ovulations resulting in embryos were 57.1 and 62.5% for EPE-treated and control mares, respectively (P>0.05). Eighty-eight (Group 1) and 91% (Group 2) of the freshly ovulated oocytes recovered were fertilized (P>0.05). After 5 d of culture, 46.4 and 40.0% of the embryos from EPE-treated and control mares developed to the morula or early blastocyst stage (P>0.05). In summary, the CL's formed in superovulated mares were from ovulations not luteinizations. Although embryo recovery was less than expected, fertilization rates and embryo development were similar (P>0.05) between superovulated and control mares.     

In vitro development of day-2 equine embryos co-cultured with oviductal explants or trophoblastic vesicles

This study compared the in vitro development of Day-2 equine embryos co-cultured with either trophoblastic vesicles or oviductal explants. Embryos were collected surgically from the oviducts of pony mares 2 d after ovulation and assessed for stage of development. Culture medium was Ham's F12 and Dulbecco's Modified Eagle's Medium (50:50 v/v) in a humidified atmosphere of 5% CO(2) in air at 38.5 degrees C with either trophoblastic vesicles or oviductal explants. The quality score of embryos was assessed daily. After 4 d in culture, embryos were stained (Hoechst 33342) and evaluated with epifluorescence to determine the number of nuclei present. Six of seven embryos co-cultured with oviductal exmplants developed to the morula/blastocyst stage, while four of seven embryos co-cultured with trophoblastic vesicles developed to the morula stage. More (P = 0.1) embryos co-cultured with oviductal explants reached the blastocyst stage than embryos co-cultured with trophoblastic vesicles (3 7 vs 0 7 , respectively). The number of cells was higher (P = 0.1) for embryos co-cultured with oviductal explants than for embryos co-cultured with trophoblastic vesicles (162.6 +/- 32 vs 87.3 +/- 28, respectively). The number of cells for embryos co-cultured with either oviductal explants or trophoblastic vesicles appeared to be lower than for embryos matured in vivo that were recovered from the uterus at Day 6 (378, 399, >1000). The co-culture of early equine embryos in a completely defined medium with either trophoblastic vesicles or oviductal explants can support development to at least the morula stage. The co-culture of embryos with oviductal explants resulted in superior development of four-to eight-cell embryos, as indicated by the proportion that reached the blastocyst stage and by the number of cells.