Vitrification of porcine embryos at various developmental stages using different ultra-rapid cooling procedures

In this study, three different vitrification systems (open pulled straw: OPS; superfine open pulled straw: SOPS; and Vit-Master technology using SOPS: Vit-Master-SOPS) were compared in order to investigate the influence of cooling rate on in vitro development of vitrified/warmed porcine morulae, early blastocysts, or expanded blastocysts. Embryos were obtained surgically on Day 6 of the estrous cycle (D0 = onset of estrus) from weaned crossbred sows, classified and pooled according their developmental stage. A subset of embryos from each developmental stage was cultured to evaluate the in vitro development of fresh embryos; the remaining embryos were randomly allocated to each vitrification system. After vitrification and warming, embryos were cultured in vitro for 96 h in TCM199 with 10% fetal calf serum at 39 degrees C, in 5% CO(2) in humidified air. During the culture period, embryos were morphologically evaluated for their developmental progression. The developmental stage of embryos at collection affected the survival and hatching rates of vitrified/warmed embryos (P < 0.001). The vitrification system or the interaction of vitrification system and developmental stage had no effect on these parameters (P > 0.05). Vitrified expanded blastocysts showed the best development in vitro (P < 0.001), with survival and hatching rates similar to those of fresh expanded blastocysts. The hatching rate of fresh morula or early blastocyst stage embryos was higher than their vitrified counterparts. In conclusion, under our experimental conditions, cooling rates greater than 20,000 degrees C/min, as occurs when SOPS or Vit-Master-SOPS systems are used, do not enhance the efficiency of in vitro development of vitrified porcine embryos.     

Overall efficiency of in vitro embryo production and vitrification in cattle

In 5 replicates a total of 719 immature oocytes recovered from 94 slaughterhouse-derived bovine ovaries were matured and fertilized in vitro, then cultured for 7 to 9 d on a granulosa cell monolayer in TCM 199 supplemented with calf serum. Of 338 blastocysts (47% of oocytes cultured), 301 were vitrified in Hepes/bicarbonate buffered TCM-199 medium, 20% calf serum and dimethylsulfoxide and ethylene glycol as the cryoprotectants. After thawing in 1 M sucrose and subsequent culture in vitro, 237 (79%) of the blastocysts re-expanded and 177 (59%) hatched. Re-expansion and hatching rates differed between the blastocysts vitrified on Day 7 and Day 8 (84 and 69% vs 70 and 41%, respectively). We conclude that the applied methods are relatively simple and inexpensive to use, with an overall efficiency of the in vitro production/vitrification procedure being 1.9 hatched blastocyst/ovary. Therefore, this system seems suitable for large-scale production of cryopreserved bovine embryos for various purposes.     

Vitrification of mouse embryos at various stages by open-pulled straw (OPS) method

This study was performed to pursue the optimal condition for the cryopreservation of mouse morulae by a two-step OPS method and to investigate the feasibility of the optimal condition for vitrification of embryos at other developmental stages. First, the mouse morulae were vitrified in OPS using one-step procedure-that is, embryos were vitrified after direct exposure to EDFS30 (15% ethylene glycol (EG), 15% dimethyl sulfoxide (DMSO), Ficoll and sucrose), or two-step method-that is, embryos were first pretreated in 10%E + 10%D (10% EG and 10% DMSO in mPBS) for 30 sec, then exposed to EDFS30 for 15 to 60 sec, respectively. After vitrification and warming, the embryos were morphologically evaluated and assessed by their development to blastocysts, expanded/hatched blastocysts, or to term after transfer. The result showed that all the vitrified-warmed morulae had similar blastocyst rate compared to that of control (91.7% vs. 100%), and the highest developmental rate to expanded blastocysts (100%) or hatched blastocysts (62.3%) was observed when the morulae were pretreated with 10%E + 10%D for 0.5 min, exposed to EDFS30for 25 sec before vitrification and warming in 0.5 M sucrose for 5 min. After transfer, the survival rate (33.1%) in vivo of the vitrified morulae was higher (P > 0.05) than that of the fresh embryos (24.6%). Secondly, embryos at different stages were cryopreserved and thawed following the above program. Most (93.4 to 100%) of the embryos recovered after vitrification were morphologically normal at all the developmental stages. The blastocyst rates of the vitrified one-cell (52.5 to 66.7%) and the two-cell (63.3 to 68.9%) embryos were lower (P < 0.05) than those of the vitrified four-cell embryos (81.7 to 86.4%), the eight-cell embryos (90.0 to 93.3%), morulae (96.7 to 100%), and the expanded blastocysts rate (98.3 to 100.0%) of the vitrified early blastocysts. The highest survival rate in vivo of vitrified embryos were from the early blastocysts (40.4%), which was similar to that of fresh embryos (48.6%). The data demonstrate that the optimal protocol for the cryopreservation of morulae was suitable for the four-cell embryos to early blastocyst stages and that the early blastocyst stage is the most feasible stage for mouse embryo cryopreservation under our experimental conditions.     

Vitrification of Mouse Embryos at Various Stages by Open-Pulled Straw (OPS) Method

This study was performed to pursue the optimal condition for the cryopreservation of mouse morulae by a two-step OPS method and to investigate the feasibility of the optimal condition for vitrification of embryos at other developmental stages. First, the mouse morulae were vitrified in OPS using one-step procedure—that is, embryos were vitrified after direct exposure to EDFS30 (15% ethylene glycol (EG), 15% dimethyl sulfoxide (DMSO), Ficoll and sucrose), or two-step method—that is, embryos were first pretreated in 10%E+10%D (10% EG and 10% DMSO in mPBS) for 30 sec, then exposed to EDFS30 for 15 to 60 sec, respectively. After vitrification and warming, the embryos were morphologically evaluated and assessed by their development to blastocysts, expanded/hatched blastocysts, or to term after transfer. The result showed that all the vitrified-warmed morulae had similar blastocyst rate compared to that of control (91.7% vs. 100%), and the highest developmental rate to expanded blastocysts (100%) or hatched blastocysts (62.3%) was observed when the morulae were pretreated with 10%E+10%D for 0.5 min, exposed to EDFS30 for 25 sec before vitrification and warming in 0.5 M sucrose for 5 min. After transfer, the survival rate (33.1%) in vivo of the vitrified morulae was higher (P > 0.05) than that of the fresh embryos (24.6%). Secondly, embryos at different stages were cryopreserved and thawed following the above program. Most (93.4 to 100%) of the embryos recovered after vitrification were morphologically normal at all the developmental stages. The blastocyst rates of the vitrified one-cell (52.5 to 66.7%) and the two-cell (63.3 to 68.9%) embryos were lower (P < 0.05) than those of the vitrified four-cell embryos (81.7 to 86.4%), the eight-cell embryos (90.0 to 93.3%), morulae (96.7 to 100%), and the expanded blastocysts rate (98.3 to 100.0%) of the vitrified early blastocysts. The highest survival rate in vivo of vitrified embryos were from the early blastocysts (40.4%), which was similar to that of fresh embryos (48.6%). The data demonstrate that the optimal protocol for the cryopreservation of morulae was suitable for the four-cell embryos to early blastocyst stages and that the early blastocyst stage is the most feasible stage for mouse embryo cryopreservation under our experimental conditions.     

High developmental rates of vitrified bovine oocytes following parthenogenetic activation, in vitro fertilization, and somatic cell nuclear transfer

Successful cryopreservation of mammalian oocytes would provide a steady source of materials for nuclear transfer and in vitro embryo production. Our goal was to develop an effective vitrification protocol to cryopreserve bovine oocytes for research and practice of parthenogenetic activation, in vitro fertilization, and nuclear transfer. Bovine oocytes matured in vitro were placed in 4% ethylene glycol (EG) in TCM 199 plus 20% fetal bovine serum (FBS) at 39 degrees C for 12-15 min, and then transferred to a vitrification solution (35% EG, 5% polyvinyl-pyrrolidone, 0.4 M trehalose in TCM 199 and 20% FBS). Oocytes were vitrified in microdrops on a precooled (-150 degrees C) metal surface (solid-surface vitrification). The vitrified microdrops were stored in liquid nitrogen and were either immediately thawed or were thawed after storage for 2-3 wk. Surviving oocytes were subjected to 1) parthenogenetic activation, 2) in vitro fertilization, or 3) nuclear transfer with cultured adult fibroblast cells. Treated oocytes were cultured in KSOM containing BSA or FBS for 9 to 10 days. Embryo development rates were recorded daily and morphologically high-quality blastocysts were cryopreserved for nuclear transfer-derived embryos at Day 7 or Day 8 of culture. Immediate survival of vitrified/thawed oocytes varied between 77% and 86%. Cleavage and blastocyst development rates of vitrified oocytes following in vitro fertilization or activation were lower than those of the controls. For nuclear transfer, however, vitrified oocytes supported embryonic development as equally well as fresh oocytes.     

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.     

Sheep embryo cryopreservation by vitrification and conventional freezing

The survival of ovine embryos (morulae and blastocysts) either frozen by a conventional method or vitrified was investigated in culture. In Experiment I, embryos were vitrified using a solution containing 25% propylene glycol and 25% glycerol. A group of embryos (simulated control) was processed without freezing to evaluate the toxicity of the vitrification solution. In Experiment II, embryos were exposed to a solution of PBS containing 10% glycerol and 0.25 M sucrose placed horizontally in a programmable freezer. Automatic seeding was applied at -7 degrees C in 2 positions on straws and cooled at -0.3 degrees C/min to -25 degrees C and then stored in liquid nitrogen. In vitro development rates of vitrified embryos were 12% (morulae) and 19% (blastocysts). Simulated embryos showed a higher rate of survival than embryos cryopreserved by vitrification (67 and 63%, morulae and blastocysts respectively). In conventional cooling, the blastocysts showed the highest viability percentage (67%) of all the experimental groups but these values decreased significantly in morulae (31%). Differences in temperature between straws placed in distinct positions in the freezing chamber and thermic deviation were observed when automatic seeding was applied. Embryo viability differed from 51 to 75% according the relative position of the embryos within the chamber. Survival was higher when automatic seeding was applied on the meniscus of the embryo column versus the central point of this column (65 vs 21%). The damage of both cryopreservation methods on zona pellucida integrity (27 and 35% in vitrified and conventionally frozen embryos, respectively) had no effect on the in vitro survival.     

A new selection criterion to assess good quality ovine blastocysts after vitrification and to predict their transfer into recipients

The feasibility to accurately select viable embryos would be valuable for improving pregnancy rates and avoiding futile transfer attempts. The aim of our study was to assess if in vitro-produced embryo quality could be determined by the timing of blastocoelic cavity re-expansion after vitrification, warming, and in vitro culture using sheep as a model. Blastocysts were produced in vitro, vitrified/warmed, and cultured in TCM-199 plus 10% FCS for 72 hr. Embryos were divided into two groups: re-expanded within 8 hr (A) and from 8 to 16 hr (B) of IVC after warming. Fast re-expanded blastocysts showed higher in vitro hatching rates and total cell number calculated on the hatched blastocysts compared with slow re-expanded ones (P < 0.01). Peroxide status evaluation (P < 0.01) and TUNEL test (P < 0.05) revealed a higher number of positive cells in group B compared with group A. The quantitative analysis of protein synthesis revealed a higher synthesis in fast compared with slow re-expanded embryos (P < 0.05). Quantitative RT-PCR showed that 90-kDa Heat Shock Protein beta was more expressed in group A than in group B (P < 0.05), while the quantity of P34(cdc2), Cyclin b, Aquaporin 3, Na/K ATPase, and Actin did not differ between the two groups. Pregnancy rates after transfer to synchronized recipients were higher in fast compared to slow re-expanded blastocysts (P < 0.05). Our results evidenced that timing of blastocoelic cavity re-expansion after vitrification/warming and in vitro culture can be considered as a reliable index of in vitro produced embryo quality and developmental potential.     

Efficient cryopreservation of bovine blastocysts derived from nuclear transfer with somatic cells using partial dehydration and vitrification

Preservation by vitrification of Day 7 and Day 8 bovine blastocysts derived from nuclear transfer with cumulus cells was compared with preservation of in vitro fertilized blastocysts. In Experiment 1, embryos were vitrified in PBS containing 60% ethylene glycol. In Experiment 2, they were vitrified in combination with partial dehydration using a solution of 39% ethylene glycol + 0.7 M sucrose and 8.6% Ficoll. In Experiment 1, survival and hatching rates were 44 and 95% for nuclear transferred embryos, and 78 and 55% for in vitro fertilized embryos, respectively. In Experiment 2, survival and hatching rates were 93 and 95% for nuclear transfer embryos, and 77 and 85% for in vitro fertilized embryos, respectively. It is concluded that Day 7 and Day 8 bovine blastocysts derived from cumulus cells could be cryopreserved without the loss of viability by a simple and efficient method using a combination of partial dehydration and vitrification.     

Factors affecting the success rate of porcine embryo vitrification by the Open Pulled Straw method

The objectives of this study were: (1) to evaluate the influence of porcine embryo developmental stage on in vitro embryo development after vitrification, (2) to study the efficiency of the one-step dilution procedure, compared with conventional warming, for vitrified embryos at different stages of development, and (3) to determine the influence of the embryo donor on the in vitro survival of vitrified embryos at morulae and blastocyst stages. Two to four cell embryos, morulae and blastocysts were collected by laparotomy from weaned crossbred sows (n=55). Vitrification and conventional warming were performed using the OPS procedure with Superfine Open Pulled Straws (SOPS). For one-step dilution, embryos were placed in 800 microl TCM199-HEPES containing 20% of new born calf serum and 0.13 M sucrose for 5 min. To evaluate development, two to four cell embryos, morulae and blastocysts were cultured in vitro for 120, 48 and 24h, respectively. Some fresh embryos from each developmental stage were not vitrified and cultured as controls. Embryos were morphologically evaluated for their developmental capacity during the in vitro culture by stereomicroscopy. The total cell number of embryos was assessed by Hoechst-33342 staining and fluorescence microscope observation. There was a significant effect of the stage of development on the in vitro survival, perihatching rate and the number of cells of embryos after vitrification and warming (Experiment 1; p<0.001). The survival and perihatching rates of two to four cell embryos were lower than those obtained for morulae and blastocysts (p<0.001). No differences (p>0.05) in survival rates were found between vitrified and fresh blastocysts. The warming procedure did not affect the development and total cell number of vitrified two to four cell embryos, morulae or blastocysts (Experiment 2). However, donor had a significant effect (p<0.001) on the in vitro development and the number of cells of morulae and blastocysts after vitrification and warming (Experiment 3). In conclusion, the embryo developmental stage and the embryo donor were important factors that affected the development of porcine embryos after OPS-vitrification and warming. OPS-vitrification and the one-step dilution are efficient procedures to be used with intact porcine morulae and blastocysts.     

Vitrification of mouse embryos in two cryoprotectant solutions

The objective of this study was to compare the efficiency of 2 media on the vitrification of mouse compacted morulae, early blastocysts and expanded blastocysts after equilibration at room temperature of 4 degrees C. Embryos were equilibrated for 10 min in either 25% VS3 (Rall Equilibration Medium, REM) or 10% glycerol + 20% propylene glycol (Massip Equilibration Medium, MEM) in DPBS at 20 degrees C or 4 degrees C. For vitrification either 100% VS3 (Rall Vitrification Medium, RVM) or 25% glycerol + 25% propylene glycol (Massip Vitrification Medium, MVM) in DPBS was used. Embryos equilibrated at room temperature were loaded in 20 microL of vitrification media into 250 microL straws and then immediately (30 sec) plunged into liquid nitrogen (LN2). After equilibration at 4 degrees C the embryos were put into straws with 20 microL of precooled vitrification medium, and after 20 min at 4 degrees C they were plunged into LN2. Embryos from both groups were thawed in a 20 degrees C water bath for 20 sec, transferred to 1.0 M sucrose in DPBS for 5 min and then cultured for 24 to 48 h in Whitten's medium at 37 degrees C in 5% CO2 in air. In the groups of embryos prepared for vitrification at room temperature the survival rate of compact morulae vitrified in RVM was higher than those vitrified in MVM (65/70, 93% vs 49/74, 66%; P < 0.01). No difference was found in the survival rate of early blastocysts and expanded blastocysts vitrified in RVM or MVM (30/83, 36% vs 25/75, 33% and 4/66, 6% vs 4/76, 5%). No difference was found between the survival rate of compact morulae after equilibration with RVM or MVM at 4 degrees C (62/75, 83% vs 52/74, 70%). Both the early blastocysts and expanded blastocysts equilibrated at 4 degrees C MVM yielded a higher survival rate than RVM (28/74, 38% and 40/70, 57% vs 4/75, 5% and 4/77, 5%; P < 0.01). We conclude that, of the 3 developmental stages, compact morulae withstand the vitrification process best, and reduction of the temperature prior to plunging into LN2 is not required. A 10-fold increase in the survival rate of expanded blastocysts can be achieved using low temperature equilibration (4 degrees C) and MVM.     

The effect of media, serum and temperature on in vitro survival of bovine blastocysts after Open Pulled Straw (OPS) vitrification

The recently introduced Open Pulled Straw (OPS) vitrification technique has successfully been used for cryopreserving porcine embryos as well as for bovine embryos and oocytes. The aim of this work is to investigate several factors on the in vitro survival of bovine blastocysts. In 5 experiments, a total of 862 in vitro produced blastocysts and expanded blastocysts was vitrified and warmed using the OPS technology, then cultured in vitro for an additional 3 days. The culture medium in Experiments 1 to 4 was SOFaa with supplements and 5% calf serum (CS). In Experiment 1, the replacement of TCM-199 + 20% CS with PBS + 20% CS in the holding medium during vitrification and warming did not result in significant differences in the re-expansion (92 vs 95%) and hatching rates (79 vs 72%). In Experiment 2, the PBS holding medium was supplemented with either 20% CS, 5 mg/mL bovine serum albumin (BSA) or 3 mg/mL polyvinylalcohol (PVA). Although the re-expansion rates did not differ (98, 95 and 93%, respectively), there was a decrease in the hatching rate after vitrification with PVA (77 and 78 vs 51%, respectively). In Experiment 3, the influence of temperature of equilibration media prior to and rehydration media after the vitrification was investigated. When the temperature of these media was adjusted to 20 degrees C instead of the standard 35 degrees C, both the re-expansion and the hatching rates decreased markedly. However, increasing the time of equilibration with the diluted cryoprotectant solution at 20 degrees C eliminated these differences. In Experiment 4, the ethylene-glycol and dimethyl sulfoxide cryoprotectant mixture was replaced with ethylene glycol-ficoll-trehalose solution. No difference in the re-expansion (89 vs 96%, respectively) or hatching rate (79 vs 84%, respectively) was detected. In Experiment 5, the vitrified-warmed blastocysts were cultured in SOFaa medium supplemented with 5% CS or 5 mg/mL BSA. Although the re-expansion rates were identical in the 2 groups (95%), the hatching rates were lower when embryos were cultured in BSA (71 and 47%, respectively). These findings indicated the possible broader application for OPS, as they demonstrated that the physical advantages of rapid cooling and warming may be accompanied by different chemical composition (holding media, cryoprotective additives) according to the requirements of the biological structure. Our study also shows the need for serum supplementation of the medium for hatching to occur after OPS vitrification.     

Optimal developmental stage for vitrification of parthenogenetically activated porcine embryos

The objective of this experiment was to determine the optimal developmental stage to vitrify in vitro cultured porcine parthenogenetically activated (PA) embryos. Embryos were vitrified by Cryotop on Day 4, 5 or 6 after oocyte activation (Day 0), and immediately after warming they were either time-lapse monitored for 24h or analyzed by differential staining. After warming, the embryos had to be cultured for at least 8h before their survival rates were stabilized. Both the survival rate at 8h and the hatching rate at 24h of Day 4 embryos were significant higher than those vitrified on Day 5 or 6 (P<0.05), no matter if they were morulae or blastocysts. These results demonstrate that porcine PA embryos can survive successfully after vitrification/warming, that the optimal time for vitrification was Day 4 for both morulae and blastocysts, and that 8h after warming was the time needed to make an early evaluation of porcine PA embryo survival.     

Effect of biopsy and vitrification on in vitro survival of ovine embryos at different stages of development

The objective of the present study was to assess the in vitro viability of ovine embryos at different stages of development after combining cell sampling and vitrification. Precompacted morulae, compacted morulae and blastocysts were obtained from superovulated Sarda ewes at 4, 5 or 6 d following insemination. Embryo cell biopsy was carried out in a 100-microl drop of PBS + 10% fetal calf serum (FCS) with 10 micromol nocodazole and 7.5 microg/ml cytochalasin-b by aspiration (3-5 cells). Embryos were cryopreserved at room temperature after exposure of 2 solutions for 5 min, transferred into a vitrification solution, loaded into the center of 0.25-ml straws separated by air bubbles from 2 columns of sucrose 0.5 M and plunged immediately into liquid nitrogen. In Experiment 1, the in vitro viability of manipulated or vitrified embryos after in vitro co-culture in TCM 199 medium with 10% FCS and sheep oviductal epithelial cells (SOEC) in 5% CO2 humidified atmosphere in air at 39 degrees C was significantly lower (P < 0.05 and P < 0.01, respectively) at precompacted morula (60 and 30%) and compacted morula (62 and 39%) stages than intact embryos at the same stages (87 and 88%). No differences were found at the blastocyst stage. In Experiment 2, the in vitro survival rate of precompacted morulae which were manipulated and immediately vitrified was lower (P < 0.05) than in those manipulated and, after a temporary period of culture, vitrified at blastocyst stage (21 vs 48%); while no differences were found at compacted morula and blastocyst stages. The results show that 1) the stage of development influences the subsequent in vitro viability of manipulated and vitrified ovine embryos, 2) temporary culture after manipulation and before vitrification improves the in vitro viability of embryos, and 3) the hole in the zona pellucida resulting from biopsy does not affect blastocyst survival after subsequent vitrification.     

High survival of rabbit morulae after vitrification in an ethylene glycol-based solution by a simple method.

Rabbit morulae were exposed to a vitrification solution-modified PBS [PB1] medium containing 40% ethylene glycol + 18% Ficoll + 0.3 M sucrose (EFS) for 2, 5, or 10 min at 20 degrees C and were vitrified in liquid nitrogen. When morulae were rapidly warmed, 96% had an intact zona pellucida. When embryos were cultured after removal of the mucin coat, high proportions of them formed blastocoel (79-100%), but the percentage of embryos developed to fully expanded blastocysts decreased with increased exposure time 87%, 40%, and 17%). The survival rate of morulae vitrified after removal of the mucin coat was lower than that of mucin-intact embryos. To assess the development potential in vivo, 131 embryos were vitrified after 2 min of exposure to EFS solution; all the embryos were recovered and 120 were transferred to recipients without removal of the mucin coat, resulting in 78 (65%) full-term fetuses or young. This simple method, which yields high survival both in vitro and in vivo, will be of practical use for vitrifying rabbit embryos.     

Piglets born from centrifuged and vitrified early and peri-hatching blastocysts

Cryopreservation of zona-intact porcine embryos has been relatively unsuccessful to date, although some success has been obtained with lipid reduced morulae and early blastocysts. This study adapted some vitrification protocols used successfully with late blastocysts for use with early zona-intact blastocysts, using actin depolymerization, centrifugation, and open-pulled (OPS) straws. Initially, Day 6 peri-hatching blastocysts were collected, cultured for 40 min in 7.5 microg/ml cytochalasin B and vitrified in 6.5 M glycerol and 6% BSA (VS1) in either heat-sealed (HS) or open straws (OS). The post-thaw survival of those stored in HS was 15.4% after 24 and 48 h in vitro; storage in OS significantly improved survival (58.8% for both 24 and 48 h). When similar stage blastocysts were cultured in cytochalasin B and vitrified with 8 M ethylene glycol and 7% polyvinylpyrrolidone (PVP; VS2) in OS, survival was 44.4 and 33.3% for 24 and 48 h, respectively. Day 5 late morulae and early blastocysts were collected, cultured with cytochalasin B, and centrifuged or left intact (control), then vitrified with VS1 in HS or OS, or vitrified in VS2 in OS only. None of the intact control embryos survived thawing and 48 h culture in vitro. Centrifuged early blastocysts vitrified with VS1 showed good post-thaw survival in culture when stored in HS (62.8 and 60.5% for 24 and 48 h, respectively), or OS (75 and 63.6%). When vitrified with VS2 in OS, survival improved (80 and 76.7%). Peri-hatching blastocysts were vitrified in VS1, and early blastocysts were vitrified with VS1 and VS2. All blastocysts were stored in OS. The embryos were recovered and transferred to Day 4 and 5 pseudopregnant recipients (for Day 5 and 6 blastocysts, respectively). Of the five recipients receiving peri-hatching blastocysts, two became pregnant and delivered a total of eight piglets. All three recipients of early blastocysts vitrified in VS1 had a delayed return to estrus; while of the four receiving embryos vitrified with VS2, two were delayed in returning to estrus, and one was confirmed pregnant after 45 days. A litter of five piglets, one male and four female, was produced at 116 days of gestation. To our knowledge, this is the first litter of piglets produced from early blastocysts vitrified without micromanipulation to remove polarized lipid droplets.     

Equilibrium vitrification of mouse embryos at various developmental stages

Previously, we developed a new method by which 2‐cell mouse embryos can be vitrified in liquid nitrogen in a near‐equilibrium state, and then kept at ?80°C for several days. In the present study, we examined whether or not the method was effective for mouse embryos at other developmental stages. Eight‐cell embryos, morulae, and expanded blastocysts of ICR mice were vitrified with ethylene glycol‐based solutions, named EFSc because of their composition of ethylene glycol (30–40%, v/v) and FSc solution. The FSc solution was PB1 medium containing 30% (w/v) Ficoll PM‐70 plus 1.5 M sucrose. The extent of equilibrium was assessed by examining how well vitrified embryos survived after being kept at ?80°C. When 8‐cell embryos and morulae were vitrified with EFS35c or EFS40c and then kept at ?80°C, the survival rate was high even after 4 days in storage and remained high after re‐cooling in liquid nitrogen. On the other hand, the survival of vitrified‐expanded blastocysts kept at ?80°C was low. Therefore, 8‐cell embryos and morulae can be vitrified in a near‐equilibrium state using the same method as for 2‐cell embryos. A high proportion of C57BL/6J embryos at the 2‐cell, 8‐cell, and morula stages vitrified with EFS35c developed to term after transportation on dry ice, re‐cooling in liquid nitrogen, and transfer to recipients. In conclusion, the near‐equilibrium vitrification method, which is effective for 2‐cell mouse embryos, is also effective for embryos at the 8‐cell and morula stages. The method would enable handy transportation of vitrified embryos using dry ice. Mol. Reprod. Dev. 79: 785–794, 2012. © 2012 Wiley Periodicals, Inc.     

Vitrification of ICSI- and IVF-derived bovine blastocysts by minimum volume cooling procedure: effect of developmental stage and age

The objective was to investigate the effects of developmental stage (fully-expanded or expanding blastocysts) and/or age (harvested on Days 7 or 8) on post-vitrification in vitro survival of bovine blastocysts derived from intracytoplasmic sperm injection (ICSI) or in vitro fertilization (IVF). Post-warming survival (re-expansion of blastocoele within 24 h) of ICSI-derived fully-expanded blastocysts (80%) was similar to that of their IVF-derived counterparts (88%). However, the ability of ICSI-derived expanding blastocysts to survive vitrification procedures (61%) was lower than that of IVF-derived blastocysts (85%; P < 0.05), although the ICSI- and IVF-derived fresh blastocysts were of similar quality. The age of the blastocysts before vitrification did not affect cryotolerance for either ICSI-derived (73 and 59% for Days 7 and 8 embryos, respectively) or IVF-derived blastocysts (86% for both Days 7 and 8 embryos). At 24 h of post-warming culture, ICSI-derived blastocysts surviving vitrification contained a higher proportion of dead cells than their IVF-derived counterparts (5-13% vs. 2-4%; P < 0.05), but these proportions were not different from those of fresh control embryos. There was an adverse effect of vitrification on the ability of blastocysts to hatch within 72 h of culture only in IVF-derived Day 8 blastocysts (41 and 70% in vitrified and fresh control groups, respectively). In conclusion, the proportion of blastocysts that survived vitrification procedures was similar for ICSI- and IVF-derived bovine blastocysts if the former were cultured to the fully-expanded stage prior to vitrification, with no significant difference between embryos harvested on Day 7 versus Day 8.     

Establishment of pregnancies after serial dilution or direct transfer by vitrified equine embryos

Experiments were conducted to determine viability of equine embryos in vivo after vitrification. In a preliminary study (Experiment 1), embryos were exposed in three steps to vitrification solutions containing increasing concentrations of ethylene glycol and glycerol (EG/G); the final vitrification solution was 3.4 M glycerol + 4.6 M ethylene glycol in a base medium of phosphate-buffered saline. Embryos were warmed in a two-step dilution and transferred into uteri of recipients. No pregnancies were observed after transfer of blastocysts >300 microm (n = 3). Transfer of morulae or blastocysts < or = 300 microm resulted in four embryonic vesicles (4/6, 67%). In a second experiment, embryo recovery per ovulation was similar for collections on Day 6(28/36, 78%) versus Days 7 and 8(30/48, 62%). Embryos < or = 300 and >300 microm were vitrified, thawed and transferred as in Experiment 1. Some embryos < or = 300 microm were also transferred using a direct-transfer procedure (DT). Embryo development rates to Day 16 were not different for embryos < or = 300 microm that were treated as in Experiment 1(10/22, 46%) or transferred by DT (16/26, 62%). Embryos > 300 microm (n = 19) did not produce embryonic vesicles.     

Double vitrification of rat embryos at different developmental stages using an identical protocol

The aim of the present investigation was to test the effectiveness of a method of vitrifying rat embryos at different stages of development (from early morula to expanding blastocyst) in a double vitrification procedure. Wistar rat embryos were vitrified and warmed in super-fine open-pulled straws (SOPS). Before being plunged into liquid nitrogen, the embryos were exposed to 40% ethylene glycol+0.75 M sucrose in TCM-199+20% fetal calf serum (FCS) for 20s at 38 degrees C. Subsequent warming and direct rehydration of the embryos was conducted in culture medium (TCM-199+20% FCS) at 38 degrees C. Early morula stage (7-10 blastomeres) embryos (n=358) were vitrified, warmed and cultured in vitro (EM group). Batches of these embryos were then cryopreserved again (revitrified) at the early blastocyst (EB group, n=87), blastocyst (B group, n=93) or expanding blastocyst stage (ExpB group, n=73). After the first (EM group) and repeated (EB, B, and ExpB groups) vitrification procedures, developmental rates of 81, 83, 34 and 76%, respectively were achieved (for EM-EB-ExpB P>0.1; for EM, EB, ExpB-B P<0.005). Our data demonstrate the possibility of using the described identical protocol for the SOPS vitrification of rat early morulae, early blastocysts and expanding blastocysts. The low survival rate of blastocysts subjected to double vitrification requires further investigation.