Survival and viability of vitrified in vitro and in vivo produced ovine blastocysts

Ovine blastocysts were produced by maturation, fertilization and in vitro culture (IVM/IVF/IVC) of oocytes from slaughtered adult and prepubertal ewes and collection from superovulated and inseminated adult animals. Dulbecco's PBS supplemented with 0.3 mM Na Pyruvate and 20% FCS was used as the basic cryopreservation solution. The embryos were exposed to the vitrification solution as follows: 10% glycerol (G) for 5 min, then 10% G +20% ethylene glycol (EG) for 5 min. Embryos were placed into 25% G + 25% EG in the center of 0.25- mL straws and plunged immediately into LN2. Warming was done by placing the straws into a water bath at 37 degrees C for 20 sec, and their contents were expelled into a 0.5 M sucrose solution for 3 min; the embryos were then transferred into 0.25 M and 0.125 M sucrose solution for 3 min each. Warmed blastocysts were transferred to the culture medium for 24 h. Survival was defined as the re-expansion of the blastocoele. All surviving blastocysts were transferred to synchronized recipient ewes, and the pregnancy was allowed to go to term. Of 68 vitrified in vitro produced blastocysts, 46 re-expanded (67.6%) and 10 lambs were born (14.7%). From the 62 in vivo derived and vitrified embryos, 52 re-expanded (83.8%) and 39 lambs were born (62.9%). The lambing rate of in vitro produced fresh transfer embryos was 40% (20 lambs/50 blastocysts transferred), and of the 32 in vivo derived blastocysts and transferred fresh, 26 lambs were born (81.2%). The results indicate that in vitro produced embryos can be successfully cryopreserved by vitrification.     

Vitrification of in vivo and in vitro produced ovine blastocysts.

Although cryopreservation of bovine embryo has made great progress in recent years, little achievement was obtained in ovine embryo freezing, especially in vitro produced embryos. However, a simple and efficient method for cryopreservation of sheep embryos will be important for application of ovine embryonic techniques such as in vitro fertilization, transgenic, cloning and etc. In this study ovine blastocysts, produced in vivo or in vitro, were cryopreserved by vitrification in EFS40 (40% ethylene glycol (EG), 18% ficoll and 0.5 M sucrose) or GFS40 (40% glycerol (GL), 18% ficoll and 0.5 Mol sucrose). In vitro produced, early blastocysts were directly plunged into liquid nitrogen (LN2) after preparation by one of the following procedures at 25 degrees C: (A) equilibration in EFS40 for 1 min; (B) equilibration in EFS40 for 2 min; (C) equilibration in EFS40 for 30 s following pretreatment in 10% EG for 5 min; (D) equilibration in EFS40 for 30 s following pretreatment in EFS20 for 2 min (E) equilibration in GFS30 for 30 s following pretreatment in 10% GL for 5 min. The survival rates observed after thawing and in vitro culture for 12 h were A 78.0% (39/50), B 50.0% (26/52), C 93.3% (70/75), D 92.0% (46/50) and E 68.0% (34/50). Survival rates were not significantly different for treatments C and D (p>0.05), but those for groups C and D were significantly higher than for A, B and E (p<0.05). After 24 h in vitro culture, hatched blastocyst rates were A 28.0% (14/50), B 21.1% (11/52), C 49.3% (37/75), D 48.0% (24/50), E 32.0% (16/50) and control 54.0% (27/50). The hatching rates for groups A, B and E were significantly lower than the control (p<0.05) in which early IVF blastocysts were cultured in fresh SOFaaBSA medium following treatment in PBS containing 0.3% BSA for 30 min, but for groups C and D it was similar to the control (p>0.05). The freezing procedures A, B and C were used to vitrify in vivo produced, early blastocysts recovered from superovulated ewes. The survival rates of frozen-thawed in vivo embryos were A 94.7% (72/76), B 75.0% (45/60) and C 96.4% (54/56) and for group B was significantly lower than for the other two treatment groups (p<0.05). Hatched blastocyst rates were A 46.0% (35/76), B 26.6% (16/60), C 51.8% (29/56) and the control 56.7% (34/60) in which early blastocysts from superovulation were cultured in fresh SOFaaBSA medium following treatment in PBS containing 0.3% BSA for 30 min. The hatching rate for treatment B was significantly lower than for the control (p<0.05) but did not differ between groups A, C and the control (p>0.05). Frozen-thawed embryos vitrified by procedure C were transferred into synchronous recipient ewes. Pregnancy and lambing rates were similar for embryos transferred fresh or frozen/thawed for both in vivo and in vitro produced embryos. These rates did not differ between in vivo and in vitro embryos transferred fresh (p>0.05). However, for frozen-thawed embryos, both rates were significantly lower for in vitro than for in vivo produced embryos (p<0.05).     

Comparison of different vitrification protocols on viability after transfer of ovine blastocysts in vitro produced and in vivo derived

We compare different vitrification protocols on the pregnancy and lambing rate of in vitro produced (IVP) and in vivo derived (IVD) ovine embryos. Ovine blastocysts were produced by in vitro maturation, fertilization and culture of oocytes collected from slaughtered ewes or superovulated and inseminated animals. Embryos were cryopreserved after exposure at room temperature either for 5 min in 10% glycerol (G), then for 5 min in 10% G + 20% ethylene glycol (EG), then for 30 s in 25% G + 25% EG (glycerol group), or for 3 min in 10% EG + 10% dimethyl sulphoxide (DMSO), then for 30s in 20% EG + 20% DMSO + 0.3 M sucrose (DMSO group). One group of in vitro produced embryos was cryopreserved similarly to the DMSO group, but with 0.75 M sucrose added to the vitrification solution (DMSO 0.75 group). Glycerol group embryos were then loaded into French straws or open pulled Straws (OPS) while the DMSO group embryos were all loaded into OPS and directly plunged into liquid nitrogen. Embryos were warmed with either a one step or three step process. In the one step process, embryos were placed in 0.5 M sucrose. The three-step process was a serial dilution in 0.5, 0.25 and 0.125 M sucrose. The embryos of DMSO 0.75 group were warmed directly by plunging them into tissue culture medium-199 (TCM-199) + 20% foetal bovine serum (FBS) in the absence of sucrose (direct dilution). Following these manipulations, the embryos were transferred in pairs into synchronised recipient ewes and allowed to go to term. The pregnancy and the lambing rate within each group of IVP and IVD embryos indicated that there was no statistical difference among the vitrification protocols.     

Effect of sugars-addition on the survival of vitrified bovine blastocysts produced in vitro

We investigated the effect of addition of sugars to a vitrification solution on the survival rate of bovine blastocysts produced in vitro. In vitro-matured (IVM) and in vitro-fertilized (IVF) bovine Day-6 to Day-8 bovine blastocysts were classified into 3 developmental stages: early blastocysts, blastocysts and expanded blastocysts. The blastocysts were cryopreserved in 1 of 3 vitrification solutions: 1) 25% glycerol25% ethylene glycol (GE); 2) 20% glycerol20% ethylene glycol3/4 M sucrose (GES); and 3) 20% glycerol20% ethylene glycol3/8 M sucrose3/8 M dextrose (GESD). The basic solution was Dulbecco's PBS supplemented with 20% of fetal calf serum. Embryos were exposed to each vitrification solution in 3 steps, and after loading into 0.25-ml straws, were plunged into liquid nitrogen. After warming in water bath at 20 degrees C, cryoprotectants were diluted in 1/2 M and 1/4 M sucrose each for 5 min. Equilibration and dilution procedure except warming were conducted at room temperature (23 to 27 degrees C). After dilution, the embryos were cultured in Ham's F10 medium0.1 mM beta-mercaptoethanol20% fetal calf serum. Survival rates of embryos at 48 h of incubation of each of the 3 developmental stages (early blastocysts, blastocysts and expanded blastocysts) exposed to the 3 types of the vitrification solutions (GE, GES and GESD) were 23.5, 33.3, 65.8% (early blastocysts, blastocysts and expanded blastocysts respectively) in GE, 55.6, 71.9, 90.5% in GES and 84.6, 83.3, 95.8% in GESD respectively. These results indicate that a mixture of 25% glycerol25% ethylene glycol is not suitable for vitrification of early bovine blastocysts; however, addition of sugars to the solution significantly (P<0.01) improved the survival rate of the vitrified blastocysts, independently of their stage of development.     

Birth of calves expressing the enhanced green fluorescent protein after transfer of fresh or vitrified/thawed blastocysts produced by somatic cell nuclear transfer

The present study examined effects of genetic manipulation and serum starvation on in vitro developmental potential of bovine somatic cell nuclear transfer (SCNT) embryos and vitrification on in vivo developmental competence of transgenic SCNT blastocysts. Fetal oviduct epithelial cells (FOECs) were isolated from the oviduct of a Day 147 bovine fetus and transfected with a plasmid (pCE-EGFP-IRES-NEO) containing the enhanced green fluorescent protein (EGFP) and neomycin-resistant (Neor) genes. There were no significant differences (P > 0.05) in cleavage rates or development rates to the blastocyst stage for SCNT embryos derived from FOECs (72.5 and 47.8%, respectively) or transfected FOECs (TFOECs, 73.8 and 47.7%, respectively); nor from serum-fed (73.6 and 47.2%, respectively) or serum-starved (72.7 and 48.3%, respectively) cells. Seventeen of Day 7 GFP-embryos (eight fresh blastocysts and nine vitrified/thawed blastocysts ) were transferred to recipients with one embryo per recipient. Two (25%) recipients were confirmed pregnant at Day 60 in fresh blastocysts group, and three recipients (33%) were confirmed pregnant at Day 60 in vitrified/thawed blastocysts group. Two healthy calves (25%) were obtained from fresh blastocysts and one (11%) from vitrified/thawed blastocysts. Microsatellite analysis confirmed that the three clones were genetically identical to the donor cells. Moreover, PCR and Southern blot demonstrated integration of transgene in genomic DNA of all three cloned calves. Expression of GFP in skin biopsies isolated from transgenic cloned calves and fibroblasts derived from the skin biopsies revealed the activity of EGFP gene, and G418 resistance in vitro of these fibroblasts confirmed the activity of Neor gene. Our results show that genetic manipulation and serum starvation of donor cells (FOECs) do not affect in vitro developmental competence of bovine SCNT embryos, and vitrified transgenic SCNT blastocysts can develop to term successfully.     

Embryo survival and birth rate after minimum volume vitrification or slow freezing of in vivo and in vitro produced ovine embryos

The objective was to evaluate pregnancy outcomes and birth rate of in vivo derived vs. in vitro produced ovine embryos submitted to different cryopreservation methods. A total of 197 in vivo and 240 in vitro produced embryos were cryopreserved either by conventional freezing, or by vitrification with Cryotop or Spatula MVD methods on Day 6 after insemination/fertilization. After thawing/warming and transfer, embryo survival rate on Day 30 of gestation was affected by the source of the embryos (in vivo 53.3%, in vitro 20.8%; P < 0.05) and by the method of cryopreservation (conventional freezing 26.5%, Cryotop 52.0%, Spatula MVD 22.2%; P < 0.05). For in vivo derived embryos, survival rate after embryo transfer was 45.6% for conventional freezing, 67.1% for Cryotop, and 40.4% for Spatula MVD. For in vitro produced embryos, survival rate was 7.3% for conventional freezing, 38.7% for Cryotop, and 11.4% for Spatula MVD. Fetal loss from Day 30 to birth showed a tendency to be greater for in vitro (15.0%) rather than for in vivo produced embryos (5.7%), and was not affected by the cryopreservation method. Gestation length, weight at birth and lamb survival rate after birth were not affected by the source of the embryo, the cryopreservation method or stage of development (average: 150.5 ± 1.8 days; 4232.8 ± 102.8 g; 85.4%; respectively). This study demonstrates that embryo survival and birth rate of both in vivo and in vitro produced ovine embryos are improved by vitrification with the minimum volume Cryotop method.     

Embryo development rates after transfer of oocytes matured in vivo, in vitro, or within oviducts of mares

Objectives of the present study were to use oocyte transfer: 1) to compare the developmental ability of oocytes collected from ovaries of live mares with those collected from slaughterhouse ovaries; and 2) to compare the viability of oocytes matured in vivo, in vitro, or within the oviduct. Oocytes were collected by transvaginal, ultrasound-guided follicular aspiration (TVA) from live mares or from slicing slaughterhouse ovaries. Four groups of oocytes were transferred into the oviducts of recipients that were inseminated: 1) oocytes matured in vivo and collected by TVA from preovulatory follicles of estrous mares 32 to 36 h after administration of hCG; 2) immature oocytes collected from diestrous mares between 5 and 10 d after aspiration/ovulation by TVA and matured in vitro for 36 to 38 h; 3) immature oocytes collected from diestrous mares between 5 and 10 d after aspiration/ovulation by TVA and transferred into a recipient's oviduct <1 h after collection; and 4) im mature oocytes collected from slaughterhouse ovaries containing a corpus luteum and matured in vitro for 36 to 38 hours. Embryo development rates were higher (P < 0.001) for oocytes matured in vivo (82%) than for oocytes matured in vitro (9%) or within the oviduct (0%). However, neither the method of maturation nor the source of oocytes affected (P > 0.1) embryo development rates after the transfer of immature oocytes.     

Pregnancy rates following timed embryo transfer with fresh or vitrified in vitro produced embryos in lactating dairy cows under heat stress conditions

Timed embryo transfer (TET) using in vitro produced (IVP) embryos without estrus detection can be used to reduce adverse effects of heat stress on fertility. One limitation is the poor survival of IVP embryos after cryopreservation. Objectives of this study were to confirm beneficial effects of TET on pregnancy rate during heat stress as compared to timed artificial insemination (TAI), and to determine if cryopreservation by vitrification could improve survival of IVP embryos transferred to dairy cattle under heat stress conditions. For vitrified embryos (TET-V), a three-step pre-equilibration procedure was used to vitrify excellent and good quality Day 7 IVP Holstein blastocysts. For fresh IVP embryos (TET-F), Holstein oocytes were matured and fertilized; resultant embryos were cultured in modified KSOM for 7 days using the same method as for production of vitrified embryos. Excellent and good quality blastocysts on Day 7 were transported to the cooperating dairy in a portable incubator. Nonpregnant, lactating Holsteins (n = 155) were treated with GnRH (100 microg, i.m., Day 0), followed 7 days later by prostaglandin F2alpha (PGF2alpha, 25 mg, i.m.) and GnRH (100 microg) on Day 9. Cows in the TAI treatment (n = 68) were inseminated the next day (Day 10) with semen from a single bull that also was used to produce embryos. Cows in the other treatments (n = 33 for TET-F; n = 54 for TET-V) received an embryo on Day 17 (i.e. Day 7 after anticipated ovulation and Day 8 after second GnRH treatment). The proportion of cows that responded to synchronization based on plasma progesterone concentrations on Day 10 and Day 17 was 67.7%. Pregnancy rate for all cows on Day 45 was higher (P < 0.05) in the TET-F treatment than for the TAI and TET-V treatments (19.0 +/- 5.0,6.2 +/- 3.6, and 6.5 +/- 4.1%). For cows responding to synchronization, pregnancy rate was also higher (P < 0.05) for TET-F than for other treatments (26.7 +/- 6.4, 5.0 +/- 4.3, and 7.4 +/- 4.7%). In the TET-F treatment group, cows producing more milk had lower (P < 0.05) pregnancy rates than cows producing less milk. In conclusion, ET of fresh IVP embryos can improve pregnancy rate under heat stress conditions, but pregnancy rate following transfer of vitrified embryos was no better than that following TAI.     

Effect of lecithin on in vitro and in vivo survival of in vitro produced bovine blastocysts after cryopreservation

The use of soybean lecithin in an glycerol-based solution for slow freezing of in vitro matured, fertilized and cultured (IVMFC) bovine embryos was examined. Embryos were developed in vitro in INRA Menezo's B2 medium supplemented with 10% fetal calf serum (FCS) on Vero cells monolayers. Day 7 blastocysts were frozen in a two-step protocol consisting of exposure to 5% glycerol and 9% glycerol containing 0.2 M sucrose in F1 medium + 20% FCS. Soybean lecithin was either added or not to the freezing solutions at a final concentration of 0.1% (w/v). In Experiment 1, blastocysts were equilibrated in cryoprotectant solutions without cooling. Cryoprotectant was diluted from embryos with 0.5 M and 0.2 M sucrose. The percentages of fully expanded and hatched blastocysts treated with or without lecithin after 24 and 48 h in culture were not significantly different (100 versus 100% and 93.3 versus 100%, respectively). In Experiment 2, the in vitro survival of frozen-thawed IVMFC blastocysts was compared when cryoprotectant solutions were either supplemented or not with lecithin. No significant effect of lecithin was found on the ability of frozen-thawed blastocysts to re-expand after 48 h in culture (65.6 and 54.2%, respectively). However, the post-thaw hatching rate of embryos cryopreserved in the presence of 0.1% lecithin was significantly higher after 72 h in culture (52 and 31.8%, respectively). In Experiment 3, the ability of frozen-thawed IVMFC blastocysts to establish pregnancy following single embryo transfer was determined. Transfers of 58 and 66 frozen-thawed embryos cryopreserved with or without lecithin resulted in 6 and 10 (10.3 and 15.1%, respectively) confirmed pregnancies at Day 60. Addition of lecithin to cryoprotectants did not improve the in vivo development rate of cryopreserved IVMFC bovine blastocysts.     

Ultrastructural morphometry of bovine blastocysts produced in vivo or in vitro

The objective of this study was to compare the ultrastructure of bovine blastocysts produced in vivo or in vitro by using morphometric analysis. Blastocysts produced in vivo (multiple ovulations, MO) were obtained from superovulated Holstein cows. For blastocysts produced in vitro, cumulus-oocyte complexes aspirated from ovaries of Holstein cows were matured and fertilized in vitro. At 20 h postinsemination (hpi), zygotes were distributed into one of three culture media: 1) IVPS (in vitro produced with serum): TCM-199 + 10% estrous cow serum (ECS); 2) IVPSR (in vitro produced with serum restriction): TCM-199 + 1% BSA until 72 hpi, followed by TCM-199 + 10% ECS from 72 to 168 hpi; and 3) mSOF (modified synthetic oviductal fluid): mSOF + 0.6% BSA. At 168 hpi, six or seven grade 1 blastocysts from each of the four treatments (MO, IVPS, IVPSR, and mSOF) were fixed and prepared for transmission electron microscopy. Random micrographs of each blastocyst were used to determine the volume density of cellular components. Overall, as blastocysts progressed in development, the volume densities of cytoplasm and intercellular space decreased (P < 0.05) and the volume densities of mature mitochondria, nuclei, blastocoele, and apoptotic bodies increased (P < 0.05). Across treatments, the proportional volumes of nuclei and inclusion bodies were increased in inner cell mass cells compared with trophectoderm cells for mid- and expanded blastocysts. For blastocysts produced in vitro, the volume density of mitochondria was decreased (P < 0.05) as compared with that of blastocycts produced in vivo. The proportional volume of vacuoles was increased (P < 0.05) in blastocysts from the mSOF treatment as compared with blastocysts produced in vivo. For mid- and expanded blastocysts from all three in vitro treatments, the volume density of lipid increased (P < 0.05) and the volume density of nuclei decreased (P < 0.05) compared with those of blastocysts produced in vivo. In conclusion, blastocysts produced in vitro possessed deviations in volume densities of organelles associated with cellular metabolism as well as deviations associated with altered embryonic differentiation. However, the specific nature of these deviations varied with the type of culture conditions used for in vitro embryo production.     

Embryo transfer after autologous endometrial coculture improves pregnancy rates

Since the first in-vitro fertilization (IVF) baby born in 1978, the technique of in-vitro fertilization-embryo transfer (IVF-ET) has been well established and widely used by clinicians all over the world. However, the success rate of IVF-ET still remains relatively low. Sub-optimal embryo culture condition may consider as a factor contribute to the poor success rate. Autologous endometrial coculture is a newly developed technique able to enhance development of fertilized eggs using the patient's own endometrial cells. A clinical tryout was conducted in our institute. Patients underwent either classic IVF (n = 82) (i.e., control group) or autologous endometrial coculture (n = 134) (i.e., coculture group). The clinical pregnancy rate (per patient) was significantly higher in coculture group (48.5%) than control group (24.3%). Patients were further subgrouped according to their age. For each subgroup, the clinical pregnancy rates were again consistently higher and the miscarriage rates were consistently lower in the coculture group than in the control groups. Coculture also increased clinical pregnancy rate of patients who failed IVF at least twice from 0% to 26.6%. Our data confirmed that autologous endometrial coculture is an effective method to improve the success rate of IVF-ET. The evidence of improving clinical pregnancy rates and reducing abortion rates after coculture suggest that coculture indeed improved success rates by improving embryo quality.     

In vitro development to blastocysts of early porcine embryos produced in vivo or in vitro

The objective of this study was to compare the development of porcine embryos from the 2- and 4-cell stages to the blastocyst stage after in vivo or in vitro fertilization and in vivo or in vitro culture. Early-stage embryos were collected either from superovulated gilts 36 h after the second mating or after in vitro fertilization (IVF) of in vivo-matured oocytes, both followed by in vitro culture to the blastocyst stage. Blastocysts collected from superovulated donors served as controls. In the first experiment, a total of 821 2- and 4-cell embryos derived from in vivo-fertilized oocytes was cultured either in medium NCSU 23, modified Whittens' medium or modified KRB for 5 d. Significantly (P < 0.05 and P < 0.001) more embryos overcame the 4-cell block and developed to the blastocyst stage in medium NCSU 23 than in the 2 other culture media. Hatching was only observed in medium NCSU 23. In the second experiment, embryos derived from in vivo-matured oocytes fertilized in vitro were cultured in medium NCSU 23. Of 1869 mature oocytes 781 (41.8%) cleaved within 48 h after in vitro fertilization. A total of 715 embryos was cultured to the morula and blastocyst stages, and 410 (57.3%) overcame the developmental block stage, with 358 embryos (50.1%) developing to the morula and blastocyst stages. None of the embryos hatched, and the number of nuclei was significantly (P < 0.05) lower compared with that of in vivo-fertilized embryos (18.9 +/- 9.8 vs 31.2 +/- 5.8). In the third experiment, 156 blastocysts derived from in vitro fertilization and 276 blastocysts derived from in vivo fertilization and in vitro culture were transferred into synchronized recipients, while 164 blastocysts were transferred immediately after collection into 6 recipients, resulting in a pregnancy rate of 83.3%, with 35 piglets (on average 7.0) born. From the in vitro-cultured embryos, 58.3% (7/12) of the recipients remained pregnant at Day 35 after transfer, but only 33.3% maintained pregnancy to term, and 14 piglets (on average 3.5) were born. In contrast, the transfer of embryos derived from in vitro-fertilized oocytes did not result in pregnancies. It is concluded that 1) NCSU 23 is superior to modified Whittens' medium and modified KRB and 2) blastocysts derived from in vitro fertilization have reduced viability as indicated by the lower number of nuclei and failure to induce pregnancy upon transfer into recipients.     

Higher survival rate of vitrified and thawed in vitro produced bovine blastocysts following culture in defined medium supplemented with beta-mercaptoethanol

The present study was conducted to compare bovine embryo developmental quality, after culture in different defined culture media, up to blastocyst stage, and subsequently cultured in media supplemented with beta-mercaptoethanol (beta-ME) following blastocyst vitrification and thawing. In part one of this study, presumptive zygotes were randomly allocated into the following media: (1) CR1, (2) KSOM, (3) SOF, and (4) sequential KSOM-SOF. In the second part of the study, blastocysts derived from four different culture media were subjected to a solid surface vitrification (35% (v/v) ethylene glycol+0.5M Sucrose+5% (w/v) Polyvinylpyrrolidone (PVP), and tested for the effect of beta-ME on their post-vitrification survival. Following thawing, blastocysts were cultured with or without beta-ME. Culture medium had no effect on cleavage rates; however, a significantly greater number of zygotes cultured in KSOM, KSOM-SOF, or SOF developed to the 8-cell stage, compared with those cultured in CR1. A greater proportion of the zygotes cultured in SOF or KSOM-SOF reached blastocysts, than did those cultured in CR1 or KSOM. The use of sequential KSOM-SOF significantly increased total cell numbers of Day 7 expanded-blastocysts when compared to those cultured in CR1, KSOM, or SOF. Addition of beta-ME into culture media after vitrification and thawing improved blastocyst survival, hatching rates, and total cell numbers of blastocysts. In conclusion, supplementation of beta-ME into culture medium after vitrification and thawing significantly increased blastocyst survival, hatching rates, and their total cell numbers. These results suggest that vitrified IVF embryos should be thawed and briefly cultured in beta-ME medium prior to embryo transfer.     

Ultrastructural characterization of fresh and cryopreserved in vivo produced ovine embryos

Controlled slow freezing and vitrification have been successfully used for ovine embryo cryopreservation. Selection of embryos for transfer is based on stereomicroscopical embryo scoring after thawing, but the subjectivity inherent to this selection step has been demonstrated by ultrastructural studies of controlled slow frozen, in vivo produced ovine morulae and blastocysts. These studies have shown that certain abnormalities remain undetected by stereomicroscopy only. In the present study, using ovine in vivo produced morulae and blastocysts, we have studied the ultrastructural alterations induced by open pulled straw vitrification (OPS) and controlled slow freezing, compared stereomicroscopical embryo scoring with light microscopy evaluation of embryo's semithin sections, and related the ultrastructural cellular damage with the embryo classification by stereomicroscopical embryo scoring of embryos’ and semithin section evaluation by light microscopy. The ultrastructural lesions found for OPS-vitrified and controlled slow frozen embryos were similar, independently of embryo stage. A significant higher number of grade 3 embryos was found at stereomicroscopical scoring after controlled slow freezing (P = 0.02), and a significant higher number of grade 3 blastocysts was found at semithin sectioning after OPS vitrification (P = 0.037). The extension of ultrastructural damage, especially of mitochondria and cytoskeleton, was related to the semithin classification but not to stereomicroscopical scoring at thawing. This suggests that semithin scoring is a useful tool for predicting ultrastructural lesions and new improvements in cryopreservation and thawing methods of ovine embryos are still warranted, including in the case of blastocysts cryopreserved by OPS vitrification.     

Piglets born after non-surgical deep intrauterine transfer of vitrified blastocysts in gilts

The aims of this study were: (1) to evaluate the effect of the number of previous estrus of recipient gilts on effectiveness of intrauterine insertion of a flexible catheter designed for non-surgical deep intrauterine catheterization during diestrus in pigs; and (2) to determine the farrowing rate and the litter size after non-surgical deep intrauterine embryo transfer (ET) of porcine blastocysts vitrified by the open pulled straw (OPS) method. In experiment 1, 27 large white hyperprolific gilts (LWh) with 2-6 previous estrus were used. Intrauterine insertions of the flexible catheter were carried out at day 5.5-6 of the estrous cycle (D0=onset of estrus). During insertions, no or only moderate reactions were observed in 88.9% of gilts and was not related (P >0.05) to the number of estrus prior to the insertion periods. The number of the estrus had a significant effect (P <0.05) on the difficulties found during the procedure. In the 100% of gilts with two estrus (N=6) it was not possible to insert the flexible catheter through the cervix. In gilts with three or more estrus, it was possible to pass the cervix and to progress along a uterine horn in 80.9% of the cases. In 86.7% of the gilts, the tip of the flexible catheter achieved the second or third quarter of the uterine horn. In experiment 2, following non-surgical deep intrauterine transfer of 20 vitrified/warmed blastocysts, 9 Meishan recipients (42.9%) farrowed an average of 5.4 +/- 0.8 piglets (range 3-9) of which 0.6 +/- 0.3 piglets (range 0-2) were born dead. In conclusion, this study shows that it is possible to obtain birth of piglets following non-surgical deep intrauterine embryo transfer (ET) of vitrified/warmed blastocysts. Non-surgical deep intrauterine ET and OPS vitrification methods are promising procedures to be used together for the introduction of new genetic material in a farm.     

Pregnancy rates and births after unilateral or bilateral transfer of bovine embryos produced in vitro.

Late morulae and blastocysts produced in vitro were nonsurgically transferred to heifers by unilateral (n = 184) or bilateral (n = 94) transfer. Of the recipients, 58% had serum progesterone values greater than 1.4 ng ml-1 on day 21 and rectal palpation on day 35 showed that 50% (138 of 278) were pregnant. The embryonic mortality rate between days 21 and 35 was estimated to be about 14% and between days 36 and 90 to be about 12%. Of the animals, 8% aborted between days 91 and 250 of pregnancy. No difference was observed in pregnancy rates between unilateral transfer of one (47%) or two embryos (49%) and bilateral transfer (53%), or in the twinning rate between bilateral transfer (42%) and unilateral transfer of two embryos (33%). The pregnancy rate was 54% with embryos evaluated as morphologically excellent or good, 51% with fair embryos and 26% with poor ones. A higher pregnancy rate (60%) was obtained after embryo transfer when the synchrony between recipient and embryo was -1 day.     

Developmental,qualitative, and ultrastructural differences between ovine and bovine embryos produced in vivo or in vitro

The objective of this study was to compare bovine and ovine oocytes in terms of (1) developmental rates following maturation, fertilization, and culture in vitro, (2) the quality of blastocysts produced in vitro, assessed in terms of their ability to undergo cryopreservation, and (3) the ultrastructural morphology of these blastocysts. In vitro blastocysts were produced following oocyte maturation/fertilization and culture of presumptive zygotes in synthetic oviduct fluid. In vivo blastocysts were used as a control from both species. In Experiment 1, the cleavage rate of bovine oocytes was significantly higher than that of ovine oocytes (78.3% vs. 58.0%, respectively, P < 0.001). The overall blastocyst yield was similar for both species (28.7% vs. 29.0%). However, when corrected for cleavage rate, significantly more ovine oocytes reached the blastocyst stage at all time-points (36.6% vs. 50.0% on day 8, for bovine and ovine, respectively, P < 0.001). Following vitrification, there was no difference in survival between in vivo produced bovine and ovine blastocysts (72 hr: 85.7% vs. 75.0%). However, IVP ovine blastocysts survived at significantly higher rates than IVP bovine blastocysts at all time points (72 hr: 47.4% vs. 18.1%, P < 0.001). At the ultrastructural level, compared with their in vivo counterparts, IVP blastocysts were characterized by a lack of desmosomal junctions, a reduction in the microvilli population, an increase in the average number of lipid droplets and increased debris in the perivitelline space and intercellular cavities. These differences were more marked in bovine IVP blastocysts, which also displayed electron-lucent mitochondria and large intercellular cavities. These observations may in part explain the species differences observed in terms of cryotolerance. In conclusion, the quality of ovine blastocysts was significantly higher than their bovine counterparts produced under identical in vitro conditions suggesting inherent species differences between these two groups affecting embryo quality.     

Successful pregnancy after transfer of rabbit blastocysts grown in vitro from single-cell zygotes

To establish successful pregnancy in rabbits after the transfer of blastocysts cultured in vitro for 72 h, pregnancy rates were compared according to synchronization methods of recipient and embryo transfer sites. Also, the effect of RDH (1:1:1 mixture of RPMI, DMEM and Ham's F10) medium with additives such as BSA and taurine was evaluated for developmental capacity and cell number. Developmental capacity and cell number were considered important for implantation. When we evaluated the relative survival of rabbit one-cell embryos after culture in Ham's F10, in RD or in RDH for 72 h, embryos cultured in RDH and RD developed much better than in Ham's F10. When the effects of BSA and taurine in RDH medium were tested for rabbit embryo development, BSA or taurine promoted transition to the blastocyst stage and increased cell numbers of cultured embryos in RDH medium. The BSA and taurine together in RDH medium had a synergistic effect on embryo development. By transferring cultured blastocysts to the oviduct of the recipient doe synchronized one day behind the donor, live-born pups were obtained successfully. These results demonstrated that rabbit blastocysts can develop to normal pups after in vitro culture and embryo transfer.     

Successful piglet production after transfer of blastocysts produced by a modified in vitro system

Porcine in vitro production (IVP) systems, including in vitro maturation (IVM) and in vitro fertilization (IVF) of oocytes and their subsequent in vitro culture (IVC), have been modified by many researchers, but are still at a low level because of a low developmental rate of embryos to the blastocyst stage and their poor qualities. Our objectives were to establish reliable IVP procedures for porcine blastocysts and to examine the ability of the blastocysts to develop to term after transfer to recipients. Porcine cumulus-oocyte complexes were matured in vitro under 5% O(2) or 20% O(2), fertilized in vitro under 5% O(2), and subsequently cultured under 5% O(2) in 1) IVC medium supplemented with glucose (IVC-Glu) from Day 0 (the day of IVF) to Day 6; 2) IVC-Glu from Days 0 to 2, then IVC medium supplemented with pyruvate and lactate (IVC-PyrLac) from Days 2 to 6; 3) IVC-PyrLac from Days 0 to 2, then IVC-Glu from Days 2 to 6; and 4) IVC-PyrLac from Days 0 to 6. There were no significant differences in blastocyst formation rates on Day 6 between the 5% O(2) and 20% O(2) conditions (19.9% and 14.0%, respectively). However, the quality of blastocysts, as evaluated by the total cell number, was better after IVM under 5% O(2) than under 20% O(2) (mean cell number, 43.5 and 37.8, respectively). When IVP embryos were cultured in IVC-PyrLac from Days 0 to 2 and subsequently in IVC-Glu from Days 2 to 6, the rate of blastocyst formation (25.3%) and cell number (48.7) were higher than the rates (5.8% to 18.1%) and numbers (35.4 to 37.1) with the IVC-Glu then IVC-Glu, the IVC-Glu then IVC-PyrLac, and the IVC-PyrLac then IVC-PyrLac regimens, respectively. We then prepared conditioned medium (CM) from culture of porcine oviductal epithelial cells for 2 days in IVC-PyrLac and evaluated its effect on development to the blastocyst stage. Cultivation in CM for the first 2 days, followed by IVC-Glu for a further 4 days, had a significantly greater effect in increasing the number of cells in the blastocyst (58.3) than did in IVC-PyrLac (48.4). Finally, we evaluated the ability of blastocysts, generated by IVM under 5% O(2) and IVC in CM, to develop to term. When Day 5 expanding blastocysts (mean cell number, 49.7) were transferred to an estrus-synchronized recipient (50 blastocysts per recipient), the recipient remained pregnant and farrowed eight normal piglets. Furthermore, when Day 6 expanded blastocysts (mean cell number, 80.2) were transferred to two estrus-synchronized recipients, both gilts remained pregnant and farrowed a total of 11 piglets. These results suggest that an excellent piglet production system can be established by using this modified IVP system, which produces high-quality porcine blastocysts. This system has advantages for the generation of cloned and transgenic pigs.