Cytochalasin B efficiency in the cryopreservation of immature bovine oocytes by Cryotop and solid surface vitrification methods

The present study was undertaken to compare the efficacies of Cryotop (CT), solid surface vitrification (SSV) methods and cytochalasin B (CB) treatment for the cryopreservation of immature bovine oocytes, in terms of survival, nuclear maturation, and in vitro development. Solution exposed oocytes were in vitro maturated and fertilized. No difference was found in the rates of survival, nuclear maturation and blastocyst among solution exposed groups and fresh control group, except blastocysts rates in oocytes exposed to CB, cryoprotectant (CPA) and fluorescein diacetate (FDA) group (CB–CPA–FDA) (23%) significantly lower than that of control group (32%). CB pretreated ((+)CB) or non-pretreated ((−)CB) COCs were vitrified either by SSV or CT. Among four vitrified groups the nuclear maturation rates (CT(−)CB: 58%, CT(+)CB: 57%, SSV(−)CB: 60%, SSV(+)CB: 63%), cleavage (CT(−)CB: 36%, CT(+)CB: 24%, SSV(−)CB: 34%, SSV(+)CB: 26%) and blastocysts rates (CT(−)CB: 6%, CT(+)CB: 7%, SSV(−)CB: 4%, SSV(+)CB: 6%) did not differ, but the rates of the four vitrified groups were significantly lower than those of non-vitrified group (81%, 71% and 26%, respectively). We thus conclude that CT and SSV perform equally in vitrification of bovine immature oocytes, and CB did not increase the viability, nuclear maturation, or in vitro development of vitrified oocytes.     

Vitrification of bovine oocytes and its application to intergeneric somatic cell nucleus transfer

We determined the efficacy of a microdrop vitrification procedure for cryopreservation of bovine oocytes, using vitrified oocytes as cytoplasts for intraspecies and intergeneric somatic cell nucleus transfer (NT). In vitro matured bovine MII oocytes were vitrified in microdrops with a vitrification solution containing 35% ethylene glycol, 5% polyvinyl pyrrolidone, and 0.4 M trehalose. After warming, approximately 80% of the vitrified oocytes were morphologically normal, and their enucleation rate was similar to that of fresh oocytes. The NT embryos constructed with bovine cumulus cells and the vitrified oocytes developed similar to blastocysts constructed with fresh oocytes, although the cell number of NT blastocysts originating from vitrified oocytes was lower than that of the fresh control. In a second experiment, we examined the development of NT embryos constructed with vitrified bovine oocytes and bovine fibroblasts (intraspecies NT embryos) or swamp buffalo fibroblasts (intergeneric NT embryos). There were no differences between the intraspecies and intergeneric NT embryos in fusion, cleavage and development to blastocysts, except for lower cell numbers in the intergeneric NT blastocysts. In conclusion, the efficacy of this microdrop vitrification procedure and the production of swamp buffalo NT blastocysts using vitrified bovine oocytes was demonstrated.     

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.     

Cryopreservation of Cattle Oocytes: Effects of Meiotic Stage, Cycloheximide Treatment, and Vitrification Procedure

Different parameters likely to influence the survival of bovine oocytes after a vitrification procedure were evaluated: oocyte meiotic stage, cycloheximide treatment at the beginning or the end of maturation, and three vitrification procedures using conventional straws, open pulled straws (OPS), or microdrops. For each procedure a mixture of cryoprotectants (25% ethylene glycol and 25% glycerol) was used. After the oocytes were warmed and subjected to in vitro maturation and fertilization, the number that developed into blastocysts was determined. Results show that cryoprotectant exposure reduced embryo development and that cycloheximide treatment had no beneficial effect on oocytes vitrified in conventional straws. Among the three vitrification procedures, only the OPS method yielded blastocysts (approximately 3% of vitrified oocytes) irrespective of their initial meiotic stage. This result highlights the major influence of the cooling rate in an oocyte vitrification protocol.     

Factors affecting nuclear maturation, cleavage and embryo development of vitrified bovine cumulus-oocyte complexes

The objective was to investigate the effects of cryodevice, vitrification solutions, and equilibration time on in vitro maturation, cleavage, and embryo development of vitrified bovine oocytes. In Experiment 1, the nuclear maturation (MII) rate of immature bovine COCs vitrified was compared between two equilibration times (0 vs 10 min) in vitrification solution 1 (VS1) and two cryodevices (cryotop vs 0.25 mL straw). The MII rate was higher in the non-vitrified control group than in vitrified groups (61 vs 16%, P < 0.0001). Equilibration time did not affect MII rate (P = 0.964); however, the MII rate was higher for COCs vitrified on cryotops than in straws (23 vs 9%, P = 0.007). In Experiment 2, bovine COCs were vitrified on cryotops using two equilibration times (0 vs 5 min) in VS1 and two kinds of vitrification solutions (freshly prepared vs frozen). Cleavage and blastocyst rates were higher (P < 0.0001) in the non-vitrified control group than vitrified groups (cleavage rate 93 vs 42% and blastocysts rate 31 vs 0.4%). Cleavage rate of COCs vitrified using frozen solutions with 5 min equilibration was higher (P = 0.05) than other treatment groups. However, blastocyst rate did not differ (P = 0.993) among treatment groups. In conclusion, cryotop was a better cryodevice than 0.25 mL straw for vitrification of bovine COCs. Furthermore, 5 min equilibration in VS1 improved cleavage. Compared with control, the vitrification procedure per se damaged bovine COCs, resulting in poor nuclear maturation and embryo development. However, vitrification did not immediately kill oocytes, as the cleavage rate was acceptable.     

Quality analysis of buffalo blastocysts derived from oocytes vitrified before or after enucleation and reconstructed with somatic cell nuclei

We investigated the potential of vitrified-warmed buffalo oocytes to develop to blastocysts after parthenogenetic activation (PA) and somatic cell nuclear transfer (SCNT). In vitro-matured oocytes before and after enucleation (M-II oocytes and enucleated oocytes, respectively) were put in 7.5% DMSO and 7.5% ethylene glycol (EG) for 4, 7 and 10 min, and then vitrified (Cryotop device) after 1-min equilibration in 15% DMSO, 15% EG and 0.5M sucrose. Following 4-, 7- and 10-min exposure, proportions of the post-warm oocytes with a normal vitelline membrane were similar (66-71% in M-II oocytes and 69-71% in enucleated oocytes). However, 18-20% of the normal M-II oocytes had no detectable first polar body in their perivitelline space (no potential for subsequent enucleation). When the post-warm M-II oocytes were treated for PA by 7% ethanol, 10 microg/mL cycloheximide and 1.25 microg/mL cytochalasin-D, parthenogenetic development into Day-7 blastocysts occurred in 10-13% of cultured oocytes, lower (P<0.05) than fresh (control) oocytes (24%). In the absence of the cooling and warming, blastocyst rates in the 4-min exposure group (22%), but not in the 7-min and 10-min exposure groups (14-15%), were similar to that in the fresh group (23%). The total cell number (group average 117-132 cells) and the ICM ratio (22-24%) of the PA blastocysts derived from vitrified M-II oocytes were comparable with fresh oocytes (127 cells and 25%). After SCNT (with fibroblast cells and vitrified-warmed oocytes), blastocyst rates were similar for the three exposure periods for M-II oocytes (8-10%) and enucleated oocytes (7-9%), but were lower (P<0.05) than in the fresh group (15%). The total cell number of the SCNT blastocysts derived from vitrified M-II and enucleated oocytes (80-90 and 82-101 cells) was smaller (P<0.05) than from fresh oocytes (135 cells); the ICM ratio of blastocysts derived from the M-II and enucleated oocytes after vitrification in 7- or 10-min exposure groups (20-22%) was not different (P>0.05) from fresh control oocytes (24%) or those in 4-min exposure group (M-II 23%, enucleated 24%). Thus, SCNT of swamp buffalo oocytes following vitrification before or after enucleation resulted in blastocysts with a slightly decreased cell number.     

Effect of nuclear stages during IVM on the survival of vitrified-warmed bovine oocytes

The effect of nuclear stages during IVM on the survival of vitrified-warmed bovine oocytes was investigated. Oocytes with compact cumulus cells were cultured for 0, 6, 12 and 24 h in TCM199 supplemented with 5% fetal bovine serum (FBS) in 3% CO2 in air. The oocytes were first exposed to 20% ethylene glycol solution and were subjected to vitrification in a solution containing 40% ethylene glycol, 18% Ficoll-70 and 0.3 M sucrose. After warming in 20 degrees C water, oocytes which had been vitrified at less than 24-h of IVM were again cultured to complete the 24-h of IVM period. Oocytes were then incubated with frozen-thawed spermatozoa in Brackett and Oliphant (BO) medium containing 60 micrograms/ml heparin and 0.25% BSA for 20 h. In vitro fertilization rates of oocytes vitrified-warmed at 0, 6, 12 and 24-h IVM were 75.2, 68.0, 82.0 and 72.4%, respectively, comparable to the rates for unvitrified control oocytes (80.6%). A higher incidence of polyspermic fertilization was observed in oocytes vitrified at 24-h IVM (44.9 vs 22.6% in the control group, P < 0.05). Vitrification of oocytes at 12-h IVM seemed to be better than that of other IVM groups, since the normal fertilization rate of all treated oocytes was the highest (36.0%) among the vitrification groups. Developmental competence of the oocytes following vitrification and in vitro fertilization (12-h IVM group) was examined by cell-free culture of presumptive zygotes up to 9 d in modified synthetic oviduct fluid (mSOF) in 5% CO2, 5% O2 and 90% N2. The cleavage rate of zygotes from vitrified oocytes 48 h after insemination was 29.8%, which was lower than that of the control group (57.0%, P < 0.05). Development to blastocysts from the vitrified oocytes (4.8%) was much lower than that of the control group (27.0%, P < 0.05). These results indicate that cryopreservation of bovine oocytes by vitrification may be affected by their maturation stage in vitro, and that developmental competence to blastocysts of cleaved oocytes following vitrification may be impaired compared with unvitrified control oocytes.     

Developmental capacity of Antarctic minke whale ( Balaenoptera bonaerensis ) vitrified oocytes following in vitro maturation, and parthenogenetic activation or intracytoplasmic sperm injection

The present study investigated the effects of the sexual maturity of oocyte donors on in vitro maturation (IVM) and the parthenogenetic developmental capacity of fresh minke whale oocytes. The effects of cytochalasin B (CB) pretreatment and two types of cryoprotectant solutions (ethylene glycol (EG) or ethylene glycol and dimethylsulfoxide (EG + DMSO)) on the in vitro maturation of vitrified immature whale oocytes were compared, and the developmental capacity of vitrified immature whale oocytes following IVM and intracytoplasmic sperm injection examined (ICSI). The maturation rate did not differ significantly with sexual maturity (adult, 60.9%; prepubertal, 53.1%), but the parthenogenetic activation rate of oocytes from adult donors (76.7%) was significantly higher (p < 0.05) than that of oocytes from prepubertal donors (46.4%). The maturation rates after vitrification and warming were not significantly different between the EG (22.2%) and EG + DMSO groups (30.2%), or between the CB-treated (30.4%) and non-CB-treated groups (27.3%). These results indicate that parthenogenetic activation of in vitro matured oocytes from adult minke whales was superior to that from prepubertal whales, but that the developmental capacity of the whale oocytes after parthenogenetic activation or ICSI was still low. The present study also showed that CB treatment before vitrification and two kinds of cryoprotectants did not improve the IVM rate following the vitrification of immature whale oocytes.     

Vitrification of immature and in vitro matured pig oocytes: study of distribution of chromosomes, microtubules, and actin microfilaments

Studies were conducted to compare viability of immature and mature porcine oocytes vitrified in ethylene glycol (EG) using open-pulled straws (OPS). Oocytes that had been allowed to mature for 12 h (germinal vesicle group; GV) and 40 h (metaphase II group; MII) were divided into three treatments: (1) control; (2) treated with cytochalasin B and exposed to EG; and (3) treated with cytochalasin B and vitrified by stepwise exposure to EG in OPS. After warming, a sample of oocytes was fixed and evaluated by specific fluorescent probes before visualization using confocal microscopy. The remaining oocytes were fertilized and cleavage rate was recorded. Exposure of GV oocytes to EG or vitrification had a dramatic effect on spindle and chromosome configurations and no cleavage was obtained after in vitro fertilization. When MII oocytes were exposed to EG or were vitrified, 18 and 11% of oocytes, respectively, maintained the spindle structure and either EG exposure or vitrification resulted in substantial disruption in microfilament organization. The cleavage rates of mature oocytes after being exposed to EG or after vitrification were similar (14 and 13%, respectively) but were significantly less than that of control oocytes (69%). These results indicate that porcine oocytes at different meiotic stages respond differently to cryopreservation and MII porcine oocytes had better resistance to cryopreservation than GV stage oocytes.     

Vitrification of pre-pubertal ovine cumulus-oocyte complexes: effect of cytochalasin B pre-treatment

The aim of this study was to evaluate the effect of cytochalasin B (CCB) pre-treatment before vitrification on ability of immature oocytes from lamb ovaries to progress until metaphase II (MII) stage after vitrification/warming procedure. Cumulus-oocyte complexes (COCs) were obtained from ovaries of lambs, from 80 to 90 days old, collected from a local slaughterhouse. Before vitrification, COCs were randomly distributed in two experimental groups corresponding to the incubation with or without 7.5 microg/ml CCB for 30 min. In order to study cryoprotectant and CCB pre-treatment toxicity (toxicity test), oocytes were exposed to cryoprotectants, with or without CCB pre-treatment, but without plunging into N2 liquid. Vitrification solution was composed by 4.48 M EG plus 3.50 M DMSO supplemented with 0.25 M sucrose. Two-step addition was performed. After vitrification or toxicity test, COCs were matured in bicarbonate-buffered TCM 199 containing 10% foetal calf serum and 10 ng/ml epidermal growth factor. A sample of COCs was directly in vitro matured (control group). Rates of MII oocytes of toxicity groups both, with or without CCB pre-treatment were lower than control group (41.1-50.0 versus 79.9, respectively; P<0.05). After vitrification, a lower number of oocytes progressed to MII stage in comparison with non-vitrification groups (P<0.05). In vitrified groups both with or without CCB pre-treatment 8.0 and 12.7%, respectively, of immature oocytes reached MII stage by the end of in vitro maturation culture. No effect of CCB was observed, either in the toxicity or vitrified groups. In conclusion, no effect of CCB pre-treatment before vitrification was detected in this study with immature oocytes of pre-pubertal sheep. More studies are needed in order to increase ovine oocyte survival after vitrification.     

Viability, maturation and embryo development in vitro of immature porcine and ovine oocytes vitrified in different devices

This study was designed to evaluate the effects of vitrification on immature porcine and ovine oocytes, collected at a slaughterhouse, by performing vitrification in devices with different volumes. Viability was evaluated both before and after vitrification and maturation. Immediately after warming, the percentage of viable pig oocytes was 81% regardless the type of device, while in the control (after oocyte selection) was 95%. The viability of matured pig oocytes after warming, vitrified in beveled edge open straws (BES) was 6%, in small-open-pulled-straw (SOPS) was 17% and in cryotop was 4%, while the viability of the control group was 86%. The viability and maturation results were similar with all devices. Embryo development (ED) was observed in fresh porcine oocytes with 15% 2-8 cell embryos, 7% morulae and 3% blastocysts, and non-embryo cleavage was observed in warmed oocytes. The viability of sheep oocytes immediately after warming averaged 90% in all devices, while that of the control (after oocyte selection) averaged 95%. The viability of warmed oocytes after maturation was: BES 21%, SOPS 30%, cryotop 21% and control group 86%; while maturation values were 11, 21, 34 and 70%, respectively. After vitrification, the highest ED was achieved with ovine oocytes vitrified in SOPS, with 17% morulae development and it was the only device in which blastocysts developed. A direct relationship was observed between viability and actin filament integrity in both species.     

Cryotops versus open-pulled straws (OPS) as carriers for the cryopreservation of bovine oocytes: effects on spindle and chromosome configuration and embryo development

Two experiments were designed to assess the effectiveness of cryopreserving bovine MII oocytes using cryotops as the carrier system for vitrification. In the first experiment, we examined the developmental competence of oocytes after: (i) vitrification in open-pulled straws (OPS method); or (ii) vitrification in <0.1 μl medium droplet on the surface of a specially constructed fine polypropylene strip attached to a plastic handle (Cryotop method). In the second experiment, warmed oocytes that had been vitrified in OPS or cryotops were fixed to analyze spindle and chromosome configuration. In all experiments both cow and calf oocytes were used. Significantly different fertilization rates were observed between the vitrification groups: 31.5% and 20.2% for the cow and calf oocytes vitrified in OPS, respectively, versus 46.1% and 46.4% for the oocytes vitrified using cryotops. After in vitro fertilization, 3.8% of the calf oocytes and 5.3% of the cow oocytes developed to the blastocyst stage. All blastocysts from vitrified oocytes resulted from the Cryotop method. A significantly lower percentage of the OPS-vitrified calf oocytes showed a normal spindle configuration (37.8%) compared to control fresh oocytes (69.9%), while normal spindle and chromosome configurations were observed in a significantly higher proportion of the cryotop-vitrified calf oocytes (60.2%). For the cow oocytes, 60.6% in the OPS group and 60.3% in the Cryotop group exhibited a normal morphology after warming. These findings suggest the cryotop system is a more efficient carrier for vitrification than OPS for the cryopreservation of bovine oocytes.     

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.     

The vitrification of in vitro fertilized cow blastocysts by the open pulled straw method

In 6 replicates, a total of 450 immature oocytes recovered from 144 slaughterhouse-derived bovine ovaries were matured and fertilized in vitro, then cultured for 7 to 9 d on a granulosa cell monolayer in tissue culture medium 199 (TCM-199) supplemented with fetal calf serum. Of 126 blastocysts (28% of oocytes cultured), 117 (26% of oocytes cultured) were vitrified in Hepes/bicarbonate-buffered TCM-199 medium and 20% fetal calf serum, with ethylene glycol and dimethylsulfoxid as the cryoprotectants. After thawing in 1.2 mL holding medium with 0.25-M sucrose and after 1 min in holding medium with 0.15-M sucrose, blastocysts were cultivated in vitro for 24 h. The re-expansion rate of blastocysts was 69.2% (81 blastocysts), and 39.5% (32 blastocysts) were hatched. Re-expansion and hatching rates differed between the blastocysts vitrified on 7 and 8+9 days (74.6% and 46% vs. 62% and 29%, respectively). After transfer to recipient cows, 3 out of 6 were diagnosed by ultrasonography as pregnant. Three calves were born from 18 transferred embryos (16.7%). The open pulled straw (OPS) method seems to be a convenient, simple and effective method for cryopreservation of 7 to 9 d bovine embryos.     

Effects of trehalose vitrification and artificial oocyte activation on the development competence of human immature oocytes

Sucrose and trehalose are conventional cryoprotectant additives for oocytes and embryos. Ethanol can artificially enhance activation of inseminated mature oocytes. This study aims to investigate whether artificial oocyte activation (AOA) with ethanol can promote the development competence of in vitro matured oocytes. A total of 810 human immature oocytes, obtained from 325 patients undergoing normal stimulated oocyte retrieval cycles, were in vitro maturated (IVM) either immediately after collection (Fresh group n = 291)) or after being vitrified as immature oocytes (Vitrified group n = 519). These groups were arbitrarily assigned. All fresh and vitrified oocytes which matured after a period of IVM then underwent intra-cytoplasmic sperm injection (ICSI). Half an hour following ICSI, they were either activated by 7% ethanol (AOA group) or left untreated (Non-AOA group). Fertilization, cleavage rate, blastocyst quality and aneuploidy rate were then evaluated. High-quality blastocysts were only obtained in both the fresh and vitrified groups which had undergone AOA after ICSI. Trehalose vitrification slightly, but not significantly, increased the formation rates of high-quality embryos (21.7% VS 15.4%, P > 0.05) and blastocysts (15.7% VS 7.69%, P > 0.05)) when compared with sucrose vitrification. Aneuploidy was observed in 12 of 24 (50%) of the AOA derived high quality blastocysts. High-quality blastocysts only developed from fresh or vitrified immature oocytes if the ICSI was followed by AOA. This information may be important for human immature oocytes commonly retrieved in normal stimulation cycles and may be particularly important for certain patient groups, such as cancer patients. AOA with an appropriate concentration of ethanol can enhance the developmental competence of embryos.     

Vitrification of immature and mature equine and bovine oocytes in an ethylene glycol, ficoll and sucrose solution using open-pulled straws

Studies were conducted to compare viability of immature and mature equine and bovine oocytes vitrified in ethylene glycol. Ficoll using open-pulled straws. Oocytes from slaughterhouse ovaries (N=50/group) with >2 layers of compact cumulus cells were vitrified immediately after collection (immature groups) or vitrified after 36 to 40 (equine) or 22 to 24 (bovine) h of maturation (mature groups). Immature oocytes were matured after thawing. Before vitrification, oocytes were exposed to TCM-199 + 10 FCS + 2.5 M ethylene glycol + 18% Ficoll + 0.5 M sucrose (EFS) for 30 sec and then to 5 M ethylene glycol in EFS for 25 to 30 sec at 37 degrees C. Oocytes were loaded into straws in approximately 2 microL of cryoprotectant and plunged directly into LN2. Warming straws and dilution of cryoprotectant was at 37 degrees C in TCM-199 + 10% FCS + 0.25 M sucrose for 1 min and then TCM-199 + 10% FCS + 0.15 M sucrose for 5 min. Non-vitrified oocytes undergoing the same maturation protocol for both species were used as controls. Oocytes were stained with orcein for nuclear maturation and live/dead status was determined using Hoechst 33342. Maturation of oocytes to MII after thawing was similar (P>0.05) among groups within species. All equine treatment groups had lower (P<0.01) maturation rates than bovine groups. Live/dead status did not differ among vitrification treatments within species. The percentage of oocytes that survived and reached MII did not differ (P>0.05) within treatment groups of each species. Rates of mature cortical granule distribution did not differ (P>0.05) within species; however, more bovine oocytes (P<0.05) had mature cortical granule distribution and nuclear maturation than equine oocytes. When concurrent cortical granule distribution and nuclear maturation were examined, there was no difference within species; however, only 30% of equine oocytes had nuclear and cytoplasmic maturation compared with 70% of bovine oocytes (P<0.05). In summary, both immature and mature equine and bovine oocytes survived cryopreservation using vitrification in open-pulled straws. However, survival rates were lower for equine than for bovine oocytes.     

Feasibility of a nylon-mesh holder for vitrification of bovine germinal vesicle oocytes in subsequent production of viable blastocysts

To improve the feasibility of nylon-mesh holder for vitrification of bovine cumulus-oocytes complexes (GV-COCs) having germinal vesicle, this study was conducted to demonstrate effects of sugars and protocol of exposure in vitrification on subsequent in vitro maturation, ultrastructural changes, and in vitro development in bovine immature oocytes after cryopreservation using nylon mesh. Before vitrification, GV-COCs were exposed to the cryoprotectant, which was composed of 40% (v/v) ethylene glycol, 18% (w/v) Ficoll-70, and 0.3 M sucrose (EFS40) or 0.3 M trehalose (EFT40), either by single step or in a stepwise way. The maturation rates in the stepwise exposure with EFS40 or EFT40 were significantly higher (P < 0.05) compared with the corresponding rates in the single step. In the stepwise exposure, few abnormalities were observed compared with the single-step exposure, where most oocytes showed a highly vacuolated cytoplasm with many ruptured mitochondria. Cleavage rates in fertilized oocytes previously exposed stepwise to EFS40 or EFT40 were significantly higher than those exposed by the single-step procedure. The cleaved embryos derived from the stepwise exposure to EFS40 developed to blastocysts. After transfer of blastocysts derived from vitrified GV oocytes, a female calf was born. These results indicate that vitrification of large numbers of bovine GV-COCs using a nylon-mesh holder accompanied with stepwise exposure minimizes structural damage in organelles, resulting in yield of viable blastocysts following in vitro embryo production.     

Improved development of ovine matured oocyte following solid surface vitrification (SSV): effect of cumulus cells and cytoskeleton stabilizer

The objective of the present study was to examine the effects of cumulus cells, cytochalasin B (CB), and taxol on the development of ovine matured oocyte following solid surface vitrification (SSV). In experiment 1, effects of cumulus cells during the vitrification were examined. Survival rates after warming were not different between ovine mature oocytes with cumulus cells and without cumulus cells. After in vitro fertilization, rates of embryonic cleavage and development to blastocyst were not different between these two groups. In experiment 2, the effects of cytochalasin B (CB) on vitrification of ovine matured oocytes were examined. The rates of survived ovine matured oocytes were not significantly different among the treatment with 0, 2.5, 5.0, 7.5 and 10.0 microg/mL CB. After in vitro fertilization, the rate of cleavage was not different between the five treatment groups. However, vitrified oocytes treated with 7.5 or 10.0 microg/mL CB resulted in a higher (8.1+/-4.6% and 7.8+/-2.4% respectively, P<0.05) blastocyst development rate than those of oocytes treated with lower CB concentrations. In Experiment 3, the effects of taxol on vitrification of ovine matured oocytes were examined. The rate of survived oocytes was not significantly different among the taxol treatment group with 0, 0.5, 1.0, and 5.0 microM taxol. After in vitro fertilization, the rates of embryos that reached cleavage were not different between the four treatment groups. However, vitrified oocytes treated with 0.5 microM taxol resulted in a higher blastocyst (10.1%+/-6.3, P<0.05) development rate compared to other treatment groups. In conclusion, no effect of cumulus cells on vitrification of ovine matured oocytes was detected in this study. Pretreatment of ovine matured oocytes with cytoskeletal inhibitor cytochalasin B or taxol have a positive effect and helps to reduce the damage induced by vitrification and is a potential way to improve the development of vitrified/warmed ovine matured oocytes.     

Developmental competence and gene expression of immature oocytes following liquid helium vitrification in bovine

The objective of this study was to develop an effective ultra-rapid vitrification method and evaluate its effect on maturation, developmental competence and development-related gene expression in bovine immature oocytes. Bovine cumulus oocyte complexes were randomly allocated into three groups: (1) controls, (2) liquid nitrogen vitrification, and (3) liquid helium vitrification. Oocytes were vitrified and then warmed, the percentage of morphologically normal oocytes in liquid helium group (89.0%) was significantly higher (P < 0.05) than that of the liquid nitrogen group (81.1%). When the vitrified–thawed oocytes were matured in vitro for 24 h, the maturation rate in liquid helium group (50.6%) was higher (P < 0.05) than liquid nitrogen group (42.6%). Oocytes of liquid helium vitrification had higher cleavage and blastocyst rates (41.1% and 10.0%) than that of liquid nitrogen vitrification (33.0% and 4.5%; P < 0.05) after in vitro fertilization. Moreover, the expression of GDF9 (growth/differentiation factor-9), BAX (apoptosis factor) and ZAR1 (zygote arrest 1) was analyzed by quantitative real-time polymerase chain reaction (qRT-PCR) when the vitrified–thawed oocytes were matured 24 h. The expression of these genes was altered after vitrification. Expression of GDF9 and BAX in the liquid helium vitrification group was not significantly different from that of the control, however there were significant differences between the liquid nitrogen vitrification group and control. In conclusion, it was feasible to use liquid helium for vitrifying bovine immature oocytes. There existed an association between the compromised developmental competence and the altered expression levels of these genes for the vitrified oocytes.     

Vitrification of calf oocytes: effects of maturation stage and prematuration treatment on the nuclear and cytoskeletal components of oocytes and their subsequent development

This study was designed to establish the effects of the meiotic stage of bovine oocytes and of a prematuration treatment with roscovitine (ROS) on their resistance to cryopreservation. Oocytes from prepubertal calves at the stages of germinal vesicle breakdown (GVBD) or at metaphase II (MII) were vitrified by the open pulled straw (OPS) method. In another experiment, oocytes were kept under meiotic arrest with 50 microM ROS for 24 hr and vitrified at the GVBD stage. After warming, some oocyte samples were fixed, stained using specific fluorescent probes and examined under a confocal microscope. The remaining oocytes were fertilized, and cleavage and blastocyst rates recorded. Significantly lower cleavage rates were obtained for the vitrified GVBD and MII oocytes (9.9% and 12.6%, respectively) compared to control oocytes (73.9%). Significantly worse results in terms of cleavage rates were obtained when GVBD calf oocytes were exposed to cryoprotectants (CPAs: ethylene glycol plus dimethyl sulfoxide, DMSO) (13.1%) or vitrified (1.6%) after a prematuration treatment with ROS, when compared to untreated control oocytes (68.7%) or ROS-control oocytes (56.6%). None of the vitrification procedures yielded blastocysts, irrespective of the initial meiotic stage or previous prematuration treatment. Compared to the control oocytes, significantly fewer oocytes exhibited normal spindle configuration after being exposed to CPAs or after vitrification of either GVBD or MII calf oocytes. These results indicate that the vitrification protocol has a deleterious effect on the meiotic spindle organization of calf oocytes cryopreserved at both the GVBD and MII stage, which impairs the capacity for further development of the embryos derived from these vitrified oocytes. Prematuration treatment with ROS has no beneficial effect on the outcome of vitrification by the OPS method.