Non-vitrified Control Research Articles

The CryoLoop facilitates re-vitrification of embryos at four successive stages of development without impairing embryo growth

Vitrification has been shown to be an effective method of cryopreservation, but little is known about re-vitrification of embryos. This study investigated the effect of re-vitrification on mouse embryo preimplantation development and viability post-transfer. Mouse embryos at the 1-cell stage were vitrified using the CryoLoop technique. Embryos were warmed and then re-vitrified successively at the 2-, 8-cell and blastocyst stages. The effects of multiple rounds of vitrification on development, differentiation and viability were assessed and compared with non-vitrified embryos. Development to the 8-cell stage on day 3 and blastocyst on day 5 were not affected by re-vitrification. However, better hatching rates were observed in the non-vitrified control group. Total cell number and the number of cells allocated to the inner cell mass (ICM) were not different between treatments. The percentage of ICM development was also not different between treatments. Implantation rate and fetal weights were the same between treatments. However, overall there were fewer fetuses per embryo transferred in the re-vitrified group. Re-vitrification of mouse embryos has minimal effect on preimplantation embryo development or implantation potential.

Vitrification of In Vitro‐produced Bovine Embryos by Addition of Ethylene Glycol in One‐step

The objective of this study was to simplify two-step addition of cryoprotectant for vitrification of bovine embryos by developing a one-step procedure. Survival was calculated as a percentage of non-vitrified controls developed from the same batch of oocytes. In experiment 1, bovine blastocysts were vitrified following one- or two-step addition of cryoprotectant. Exposure of embryos to cryoprotectant in one-step resulted in survival rates not significantly lower (p > 0.1) than those obtained by two-step addition (85% vs 98%, respectively). Based on these results, experiments 2-4 were designed to test one-step addition of cryoprotectant more rigorously. Experiment 2 exposed day 7 blastocysts to 6, 7 or 8 M ethylene glycol for 2.5 or 3.5 min. At 24 h post-vitrification, survival of embryos was similar, irrespective of ethylene glycol concentration or exposure time (6 M 38%, 7 M 51%, 8 M 59%; 2.5 min 54%, 3.5 min 45%). In experiment 3, blastocysts were exposed to 7 M ethylene glycol for shorter times (30 or 60 s); 30 s exposure resulted in decreased survival (8% vs 31%, p < 0.05). Experiment 4 concerned one-step addition of cryoprotectant to day 6 bovine morulae, exposed to 7 M ethylene glycol for 1 or 1.5 min. There was no difference in survival between exposure times of 1 or 1.5 min (28% vs 45%, respectively; p > 0.1). It is unclear why many embryos survive vitrification with one-step addition of cryoprotectant, but others do not. Although, one-step addition of cryoprotectant simplifies the vitrification procedure, survival rates were inadequate for routine cryopreservation of in vitro-produced bovine embryos.

126 CRYOPRESERVATION OF PORCINE EMBRYOS DERIVED FROM IVM OOCYTES

We have reported that a combination of delipation (removal of cytoplasmic lipid droplets from blastomeres) and vitrification by means of the minimum-volume cooling (MVC) method successfully cryopreserves porcine in vitro-matured/fertilized (IVM/IVF) embryos, and that normal piglets are produced from these embryos (Hiruma et al. 2006 Reprod. Fertil. Dev. 18, 157). We have also reported that IVM-derived embryos that undergo noninvasive delipation (i.e. micromanipulation is not required) and vitrification develop into blastocysts at a high rate (Esaki et al. 2004 Biol. Reprod. 71, 432–437). In this study, we examined whether fetuses can be produced from the IVM-derived embryos that have been delipated noninvasively and vitrified. Cumulus–oocyte complexes that had been collected from slaughterhouse ovaries were in vitro-matured in NCSU23 medium. The IVM oocytes were activated to produce parthenogenetic embryos. We used the embryos at the 4- to 8-cell (67 h after activation) and morula (98 h) stages in the following experiments. Embryos were treated with 4% trypsin (in PBS) at 38�C for 1 to 4 min to expand the zona pellucida. Next, the embryos were centrifuged (12 000g, 38�C, 23 min) in TL-HEPES-PVP containing 7.5 �g mL-1 cytochalasin B to polarize cytoplasmic lipid droplets within the perivitelline space. These embryos were cultured for 1 to 3 h and then vitrified. The post-thaw viability of the embryos was assessed based on their ability to develop into blastocysts and fetuses (21 to 23 days old). The embryos were vitrified using the MVC method with 15% ethylene glycol, 15% DMSO, and 0.5 M sucrose as cryoprotective agents. PZM-5 was used for culturing the embryos. In embryo transfer experiments, after thawing, the embryos were cultured for 36 or 72 h until they developed into morulae or 4- to 8-cell blastocysts, respectively; they were then treated with 0.5% pronase to remove the zona pellucida, and transferred to the uterine horns of estrus-synchronized recipients 6 days after onset of estrus. The proportion of vitrified embryos that developed into blastocysts and the mean cell number of the blastocysts were similar to those of non-vitrified control embryos, irrespective of the embryonic stage (4- to 8-cell stage: 42.1%, 22/51, 63.0 � 7.8 vs. 64.7%, 22/34, 74.2 � 7.1, respectively; morula stage: 77.6%, 38/49, 69.6 � 7.2 vs. 83.3%, 45/54, 66.2 � 5.9, respectively). Seventeen embryos that had been vitrified at the 4- to 8-cell stage gave rise to 3 fetuses after transfer into one recipient (17.6%). Fifty-three embryos that had been vitrified at the morula stage were transferred into 3 recipients. All recipients became pregnant and produced a total of 17 fetuses (32.1%). These results suggest that porcine IVM-derived embryos that have been cryopreserved by the combination of noninvasive delipation and vitrification by the MVC method are highly viable.

116 EFFECTS OF l-GLUTAMINE ON CRYOPRESERVATION OF IMMATURE BOVINE OOCYTES

The cryopreservation of bovine oocytes remains a challenge despite significant reported progress. Immature bovine oocytes have a complex structure and the conventional cryoprotectants (penetrating cryoprotectants, sugars, and macromolecules) appear to be not sufficient to preserve them efficiently during freezing. Studies on semen and fibroblast cryopreservation indicate that amino acids, particularly l-glutamine, protect enzymes during freezing and increase the post-thaw viability. Therefore, the amino acids may optimize oocyte cryopreservation when associated with conventional cryoprotectants. This work evaluated the effect of l-glutamine on cryopreservation of immature bovine oocytes after in vitro maturation. Oocytes with homogeneous cytoplasm and several cumulus cell layers from slaughterhouse ovaries were distributed randomly in three groups: non-vitrified control, vitrified control, and vitrified with l-glutamine. Oocytes from vitrified groups were exposed for 10 min to PBS + 10% FCS + 10% ethylene glycol (EG) + 0.25 m trehalose (T), and for 30 s to PBS + 10% FCS + 25% EG + 25% dimethylsulfoxide + 0.5 m T at room temperature, adding 80 mm l-glutamine for the third group. Oocytes were loaded into OPS and plunged in liquid nitrogen. For thawing, OPS were immersed in PBS + 10% FCS + 10% EG + 1 m T for three min. Oocytes werethen placed in PBS + 10% FCS + 0.5 m T and in PBS + 10% FCS, remaining three min in each solution. For in vitro maturation, oocytes were washed three times on holding medium (TCM-HEPES + FCS + pyruvate + gentamycin), washed three times in maturation medium (TCM-bicarbonate + FCS + pyruvate + gentamycin + hCG + FSH + estradiol), and cultured in microdrops (90 μL) of maturation medium covered with mineral oil at 38.5°C under 5% CO2 in air and high humidity for 24 h. Oocytes were denuded, fixed in paraformaldehyde and triton, stained with Hoechst 33342, and evaluated under epifluorescence microscopy. Oocytes at metaphase II were considered matured. The group vitrified with l-glutamine had a significantly higher maturation rate than the group vitrified without l-glutamine; however, both had significantly lower maturation rates than the non-vitrified control group. In conclusion, l-glutamine improved the viability of vitrified oocytes. Table 1. Oocyte maturation rates of non-vitrified control, vitrified control, and vitrified with glutamine groups This work was supported by FAPESP 03/08543-1.

In vitro assessment of a direct transfer vitrification procedure for bovine embryos

We developed a simple vitrification technique for bovine embryos that could permit direct transfer. Embryos were produced in-vitro by standard procedures. The base medium for cryopreservation was a chemically defined medium similar to SOF + 25 mM Hepes and 0.25% fatty acid free bovine serum albumin (FAF-BSA) (HCDM2). In experiment 1, embryos were first exposed to 3.5 M ethylene glycol (V1) for 1, 2 or 3 min at room temperature (20–24 °C), and then moved to 7 M ethylene glycol (V2) at 4 or 20–24 °C and loaded in 0.25-mL straws. After 45 s in 7 M ethylene glycol, straws were placed in liquid nitrogen. Embryos that were loaded at 20–24 °C had higher survival rates than those loaded at 4 °C ( P < 0.05). Exposure for 1 min was best for morulae, while 3 min was best for blastocysts. In experiment 2, blastocysts were handled at 24 °C and exposed to two concentrations of ethylene glycol in V1 (3.5 or 5 M) followed by V2 as in experiment 1, two warming temperatures (20 or 37 °C) and two post-warming holding times until culture (5 or 15 min). Exposure to 5 M ethylene glycol and warming at 37 °C was the optimal combination of procedures, and embryos survived well after 15 min in straws if warmed at 37 °C. In experiment 3, ethylene glycol concentration (3, 4 or 5 M) and exposure time (0.5 or 1 min) during two-step addition of cryoprotectant were studied for bovine morulae. In experiment 4, morulae were exposed to V2 for 30 or 45 s in HCDM2 or Vigro holding medium and then held in 22–24 °C air or 37 °C water post-warming. Experiment 5 was like experiment 4 except blastocysts were used. Overall survival rates of blastocysts in experiment 5 averaged 80% of non-vitrified controls after 48 h culture. The survival rates with in vitro-produced morulae in experiments 1, 3 and 4 were unacceptable. Vitrification solutions based on Vigro tended to result in higher survival than HCDM2 for blastocysts, but not morulae. In experiment 6, the survival rate in vitro of in vivo-produced morulae and blastocysts after two-step vitrification was nearly 100%. Our vitrification technique was very effective for in vitro produced blastocysts, but not for in vitro-produced morulae.

Beneficial effects of serum supplementation during in vitro production of porcine embryos on their ability to survive cryopreservation by open pulled straw vitrification

The ability of porcine blastocysts produced in vitro, in the presence or absence of serum, to survive cryopreservation was investigated in this experiment. Porcine oocytes were matured, fertilized and cultured in vitro using serum-free culture systems. Starting at Day 4 of in vitro embryo culture (Day 0 = fertilization), the culture medium was supplemented with 10% fetal bovine serum (FBS). Embryos were cultured under these conditions until Day 6. Embryos cultured with only BSA supplementation served as serum-free controls. Day 6 blastocysts and expanded blastocysts of excellent quality were vitrified using the open pulled straw method. After warming, blastocysts were cultured in the presence of 10% FBS for an additional 18 h to recover. Portions of blastocysts from both groups, without cryopreservation, were also cultured under the same conditions to serve as non-vitrified controls. To further investigate the influence of FBS on the quality of embryos produced, the total cell numbers in Day 6 blastocysts from both groups were compared. In addition, the ratio of viable to total cells in fully recovered blastocysts at each group was examined. Blastocysts produced in the presence of FBS had an increased ability to survive cryopreservation and also had a higher cell number compared to those produced in serum-free systems ( P < 0.05). The fully recovered blastocysts had a normal viable to total cell ratio, compared to non-vitrified controls. Overall, this experiment supports the hypothesis that serum supplementation during in vitro production of porcine embryos is beneficial to the ability of a blastocyst to survive cryopreservation.

Factors affecting cryosurvival of nuclear-transferred bovine and swamp buffalo blastocysts: effects of hatching stage, linoleic acid–albumin in IVC medium and Ficoll supplementation to vitrification solution

The objective was to determine whether the hatching stage of cattle and swamp buffalo somatic cell nuclear-transferred (SCNT) blastocysts affected cryosurvival after vitrification, and whether addition of linoleic acid–albumin (LAA) to the IVC medium and Ficoll to the vitrification solution improves cryosurvival. Fused couplets were activated with ethanol and cycloheximide-cytochalasin D (day 0), and were allowed to develop in the presence of 0.3% BSA or 0.1% LAA + 0.2% BSA. Hatching blastocysts were harvested at day 7.0 (cattle) or day 6.5 (buffalo), and classified into one of three categories, according to the ratio of extruding embryonic diameter from zona to embryonic diameter inside the zona. The blastocysts were vitrified in 20% DMSO + 20% ethylene glycol + 0.5 M sucrose, with or without 10% Ficoll in TCM199 + 20% FBS, using Cryotop as a cryodevice. The post-thaw survival of the blastocysts was assessed by in vitro culture for 24 h. In cattle, when the LAA-supplemented IVC medium and the Ficoll-free vitrification solution were used, cryosurvival of the early-hatching blastocysts (77%) was not different from those of middle- and late-hatching blastocysts (74 and 80%, respectively). Inclusion of Ficoll in the vitrification solution did not improve the cryosurvival of SCNT blastocysts (54 to 68%). Early-hatching SCNT blastocysts produced in the absence of LAA were sensitive to the vitrification procedure (cryosurvival 56%; P < 0.05 versus 80% in the late-hatching blastocysts). The full-term developmental potential of SCNT blastocysts was proven only in the non-vitrified control group. In buffalo, the mean cryosurvival of hatching SCNT blastocysts produced with LAA (89%) was not different from that of those produced without LAA (87%). In conclusion, bovine SCNT blastocysts, regardless of their hatching stage, were relatively resistant to vitrification by the ultra-rapid cooling procedure when the blastocysts were produced in the presence of LAA. Furthermore, swamp buffalo SCNT blastocysts were more tolerant of vitrification than bovine SCNT blastocysts.

102 DEVELOPMENTAL COMPETENCE OF BUFFALO (BUBALUS BUBALIS) OOCYTES VITRIFIED AT DIFFERENT STAGES OF MATURATION IN VITRO

Cryopreservation of unfertilized oocytes at very low temperature (-196�C) is carried out to ensure their continuous availability during different assisted reproductive techniques. However, various problems associated with the freezing of oocytes influence their developmental competence, resulting in suboptimal embryo production. The present study was planned to assess the developmental competence of buffalo oocytes vitrified at different meiotic stages of maturation. Expression profile of developmentally important genes, viz, heat shock protein 70 (HSP 70) and glucose transporter 1 (Glut1), was verified in these vitrified warmed oocytes. Buffalo cumulus-oocyte complexes were collected from slaughterhouse ovaries and divided into six groups: control (no vitrification); 0 h group (vitrified before maturation), and 6-, 12-, 18-, and 24-h groups [vitrified respectively at 6, 12, 18, and 24 h post-in vitro maturation (IVM)]. Vitrification solution consisted of propylene glycol (40% w/v), and trehalose (0.25 mol/L) in PBS + BSA (4% w/v) and vitrification was carried out by directly plunging 0.25-mL French mini-straws into liquid nitrogen. After a minimum storage period of 7 days, the straws were thawed at 37�C for 30 sec. In all groups, the oocytes completed 24-h of maturation. After 24 h maturation, a few oocytes from each of the six groups were stained with ethidium bromide to reveal their nuclear status. The remaining oocytes were co-incubated with frozen thawed buffalo semen in fertilization TALP with 6 mg/mL fatty acid free BSA and 10 �g/mL heparin sodium salt for 18 h. Presumptive zygotes were cultured in mSOF for 8 days. Vitrified warmed oocytes were subjected to total RNA isolation and RT-PCR for detection of mRNA transcripts of HSP 70 and Glut1 genes. Data were analyzed by one-way ANOVA and F-test analysis. Differences of P &lt; 0.05 were considered significant. The percentage of oocytes recovered from all five vitrification groups varied from 89 to 92 out of which 84-91% of oocytes were morphologically normal. A higher proportion of nonvitrified control oocytes (72.8%; 40/55) reached the metaphase II stage than for the oocytes vitrified at 24 (60%; 36/60), 18 (54.4%; 31/57), 12 (42.3%; 22/52), 6 (33.3%; 20/60), and 0 (31.7%; 19/60) h of IVM. The cleavage rate of nonvitrified control oocytes was higher (36.8%) than that of oocytes vitrified at 0 (1.6%), 6 (2.0%), 12 (3.2%), 18 (5.3%), and 24 (5.2%) h of IVM. With regard to subsequent development, 0- and 6-h oocytes were blocked at 8 cells, whereas in other groups development reached the late morula (4.8%) and blastocyst (3.5%) stages, confirming that the stage of maturation at which oocytes are vitrified influenced the nuclear maturation and developmental competence. Total RNA content was 2.24 � 0.40 ng/oocyte in the control group and 2.11 � 0.22 ng/oocyte in the group vitrified after 24 h of IVM. The expression pattern of HSP 70 and Glut1 was identical in control and vitrified groups, indicating that the vitrification protocol did not alter the expression pattern of these genes.

Vitrification of goat, sheep, and cattle skin samples from whole ear extirpated after death and maintained at different storage times and temperatures

Proper tissue preservation from a wide range of animals of different species is of paramount importance, as these tissue samples could be used to reintroduce lost genes back into the breeding pool by somatic cloning. We aim to study the temporal and thermal post-mortem limits, tested in rabbits and pigs, within which there will be guarantees of obtaining living skin cells in goat, sheep, and cattle. We also intend to study the effect of vitrification on the ability of ear skin cells, stored at different times and temperatures, to attach to the substratum and grow in vitro after warming. Ears were stored either at 4 °C for 12, 252, and 348 h post-mortem (hpm), or at room temperature (22–25 °C) for 60 and 96 hpm. In all cases, skin samples from these ears were sorted into two groups: one group was in vitro cultured immediately after storage, and the other group was vitrified after storage and further in vitro cultured. In goat and sheep, no differences in attachment (100%: goat; 90–100%: sheep) or subconfluence (75–100%: goat; 70–100%: sheep) rates were observed between experimental groups. However, in days of culture to reach subconfluence, significant differences between non-vitrified and vitrified groups were observed when ears were stored at 4 °C for 12 and 252 hpm. In cattle, with respect to attachment rate, vitrified samples from ears stored at 22–25 °C for 60 hpm were different from non-vitrified control group (60 vs. 100%, respectively; P < 0.05). Also, days of culture to reach subconfluence were analysed by a non-parametric Cox Survival Analysis. In general, results from ANOVA and Survival Analysis were similar, because the proportion of censored data was quite low (9%), so the bias when using ANOVA is not too high. In spite of all the above, the lowest survival rates (75%: goat; 70%: sheep; and 40%: cattle) were sufficiently high to enable collection of skin samples from the majority of dead animals and their cryopreservation.

99MACROMOLECULES FOR VITRIFYING BOVINE OOCYTES

Vitrification of oocytes would make them available for research and clinical purposes wherever and whenever needed. However, development rates and quality of blastocysts arising from vitrified oocytes have been low. Zona hardening following exposure to vitrification solutions and cooling could contribute to low fertilization rates. Addition of fetal calf serum (FCS) to handling media and vitrification solutions can prevent zona hardening, but FCS may be detrimental to resulting embryos and spread viral diseases, and its composition varies among batches. Fetuin is the component responsible for the protective effect of FCS (Landim-Alvarenga FC et al., 2002 Anim. Reprod. Sci. 71, 181–191). Our objective was to determine whether fetuin is a suitable substitute for FCS during vitrification. Oocytes derived from slaughterhouse ovaries were matured in a chemically defined medium with hormones and with or without 1mgmL−1 fetuin at 39°C in 5% CO2 in air. At 22h after the start of maturation, oocytes were transferred to one of the following handling media: 2% BSA, 2% BSA+1mgmL−1 fetuin, or 20% FCS in TCM-199+HEPES (HTCM-199). In the same media plus 100IUmL−1 hyaluronidase, cumulus cells were partly removed by gentle pipetting. Oocytes with approximately 3 layers of cumulus were chosen for two-step vitrification. First, they were exposed to VS1 (10% ethylene glycol (EG), 10% DMSO, 6% PVP in HTCM-199) for 30s, then to VS2 (20% EG, 20% DMSO, 6% PVP, 0.48M galactose in HTCM-199) for 25s, loaded into cryoloops in groups of five, and plunged into liquid nitrogen. Rapidly warmed oocytes were moved stepwise in 0.5, 0.25, 0.125, and 0M galactose in HTCM-199+20% FCS, 3 min each. All procedures were conducted at 39°C. Warmed oocytes were placed in maturation medium for an additional hour, and then fertilized and cultured according to standard procedures (Olson SE and Seidel GE Jr 2000 J. Anim. Sci. 78, 152–157). About 2000 oocytes were used in 11 replicates with semen of 4 bulls. The experimental treatments and controls were: A: maturation BSA, handling BSA; B: maturation BSA, handling FCS; C: maturation BSA, handling BSA+fetuin; D: maturation BSA+fetuin, handling BSA+fetuin; E: non-vitrified control, maturation BSA; F: non-vitrified control, maturation BSA+fetuin (Table 1). Controls did not differ (P&amp;gt;0.1) from each other, nor were there differences among vitrification treatments. Controls resulted in greater cleavage and more 8-cell embryos and blastocysts than vitrified treatments, and also tended to have higher cell numbers. In summary, fetuin can replace FCS during handling without decreasing the success of vitrification. Table 1 Development of vitrified oocytes and controls

87ONE-STEP VERSUS TWO-STEP VITRIFICATION AND IN-STRAW DILUTION OF IN VITRO-PRODUCED BOVINE EMBRYOS

Slow-cooling techniques are widely used in cryopreservation of bovine embryos. We have previously developed a simple, two-step vitrification technique for direct transfer in the field; however, simplification to one-step vitrification would be attractive. Therefore, factorial combinations of two techniques (one-step and two-step) and two post-thaw temperatures until culture (24 and 37°C) were studied. Blastocysts (n=220) sired by two bulls were obtained in vitro in four replicates. Briefly, oocytes were aspirated from 2–8-mm follicles of ovaries obtained at a slaughterhouse, matured, fertilized and cultured in vitro with standard procedures using chemically defined media (CDM1/2 or G1/2). Two-step embryos were transferred in 1μL into 1mL of V1-CDM (5M ethylene glycol (EG) in HEPES-buffered holding medium (HCDM2)), and one-step embryos into a 7-μL droplet of V2-CDM (7M EG, 0.5M galactose and 18% w/v Ficoll 70 in HCDM2) for 3min at 24°C. Next, embryos for the two-step method were moved in 1μL into a 7μL droplet of V2-CDM at 24°C. Droplets containing embryos (one or two-step) were loaded into 0.25-mL straws preloaded with a 1-cm column of D-HCDM (0.5M galactose in HCDM2), then 0.5cm air, and then 7cm of D-HCDM followed by 0.5cm air. The column containing the embryos (0.5cm (7μL)) was followed with 0.5cm air and 1cm of D-HCDM. Straws were heat-sealed and plunged vertically, sealed end first, into liquid nitrogen just covering the embryo, and the rest of the straw was then slowly immersed. The time from loading to plunging was 40–50s. Straws were thawed in air (24°C) for 10s and then in water horizontally at 37°C until ice disappeared. Straws were gently shaken to mix the columns; then, after 5min at 24 or 37°C, embryos were expelled and cultured in CDM2+5% FCS. Re-expansion and hatching rates were evaluated 48 h post thaw. Data (Table 1) were calculated as a percentage of non-vitrified controls for respective replicates (control means: re-expansion 87%; hatching 74%) and analyzed by ANOVA. There were no main effects of post-thawing temperature (P&amp;gt;0.1), indicating that, after thawing, embryos can be kept at room or body temperature. Also, main effect means for re-expansion and hatching for one-step or two-step addition of cryoprotectant were similar (P&amp;gt;0.1), but there was a tendency for higher survival for the two-step procedure. Further refinements of the one-step technique including EG concentrations, embryological stages and equilibration times should be studied. Table 1 Main effect means (least-square means±SEM) of vitrified embryos (% of non-vitrified controls)

102VITRIFICATION OF IN VITRO-PRODUCED BOVINE AND OVINE EMBRYOS USING THE MINIMUM VOLUME COOLING CRYOTOP METHOD

Considerable progress has been achieved in the cryopreservation of mammalian embryos. The use of vitrification minimizes chilling injuries by increasing cooling and warming rates. This study assesses the effect of vitrification using the minimum volume cooling (MVC) method (Kuwayama &amp;amp; Kato 2000 J. Assist. Reprod. Genet. 17, 477) on in vitro-produced bovine and ovine embryos. A total of 1756 ovine and 753 bovine cumulus-oocyte complexes were obtained from the abattoir and matured, fertilized (Day 0) and cultured in vitro (Walker et al., 1996 Biol. Reprod. 55, 703–708, Kelly et al., 1997 Theriogenology 47, 291). Overall cleavage rates were 93.7% and 80.5% respectively. Embryos were vitrified (OPS or MVC method) on Days 5 (morula, compact morula), 6 (expanded blastocyst, blastocyst, compact morula) or 7 (hatched and hatching blastocysts, expanded blastocyst, blastocyst). Embryos were equilibrated with 7.5% ethylene glycol (EG) and 7.5% dimethyl sulfoxide (DMSO) for 3min and then exposed to 16.5% EG, 16.5% DMSO, 0.5M sucrose and 20% FCS for 30s. Embryos were loaded onto either an MVC plate (Cryotop, Kitazato Supply Co, Toyko, Japan) or open pulled straw (OPS) and plunged into liquid nitrogen. After 5 days, embryos were thawed directly into 1.25M sucrose solution at 38.5°C, followed by stepwise dilution of the cryoprotectants. Embryo survival was assessed by culture to Day 8 and compared to the development of non-vitrified control embryos (Table 1). Variables were assessed using procedure CATMOD in SAS. The Cryotop method yielded a significantly higher percentage of viable ovine embryos after thawing compared with OPS (P&amp;lt;0.0001); neither day nor treatment x day interaction was significant (P&amp;gt;0.05). A significant interaction between vitrification treatment and day (P&amp;lt;0.007) indicated that the percentage of hatched embryos peaked at Day 6 using the Cryotop method compared with Day 7 for OPS. Hatching rates for fresh and vitrified embryos were similar at Day 7 and were independent of treatment. With the Cryotop method, day of vitrification did not influence the percentage of Days 6 and 7 bovine embryos that hatched after thawing but, on each day, this figure was significantly higher (P&amp;lt;0.003 and P&amp;lt;0.0001, respectively) than that obtained with fresh embryos. To further assess embryo viability, 36 fresh, 52 OPS and 56 Cryotop vitrified Day-6 in vitro-produced ovine embryos were transferred to synchronized recipients. Survival rates to Day 13 were 29/33 (87.9%), 23/36 (63.9%) and 42/51 (82.4%), respectively (P&amp;lt;0.05). This study demonstrates that using the MVC Cryotop method, the viability of vitrified embryos, as assessed at Days 8 and 13, is similar to that obtained with fresh embryos. Table 1

Successful production of blastocysts following ultrarapid vitrification with step-wise equilibriation of germinal vesicle-stage mouse oocytes.

The purpose of this study was to evaluate the viability and subsequent developmental ability of murine germinal vesicle (GV) oocytes ultrarapidly vitrified after step-wise exposure to cryoprotectants (CPAs). Oocytes were transferred to a vitrification solution composed of 15% ethylene glycol, 15% dimethyl sulfoxide and 0.5 M sucrose in a direct manner (non-preequilibrium) or in a step-wise manner (single-, two-, or ten-step preequilibrium). After ultrarapid vitrification and storage in liquid nitrogen, the oocytes were thawed, washed by diluting the CPAs in five steps, and then subjected to in vitro maturation, fertilization and culture. In the non-preequilibrium group, the rates of post-thawed oocytes surviving, maturing to metaphase-II, developing to blastocysts and to hatching/hatched blastocysts were 91.8, 87.1, 15.9 and 2.3%, respectively. In the single- and two-step groups, the corresponding rates were 97.0-98.2%, 92.2-95.0%, 22.0-29.4% and 8.8-15.6%, whereas in the ten-step group they were 98.2, 91.8, 38.6 and 22.8%, respectively. In the non-vitrified control group, the rates of oocytes maturing to metaphase-II, developing to blastocysts and to hatching/hatched blastocysts were 90.2, 75.2 and 51.5%, respectively. The present study shows that the ultrarapid vitrification of murine GV oocytes by a step-wise manner involving 10 steps preequilibrium may have an advantage in maintaining the viability and subsequent production of blastocysts.

Vitrification of Yunnan Yellow Cattle oocytes: work in progress

The objective of this study was to provide a simple cryopreservation method for oocytes from Yunnan Yellow Cattle and facilitate preservation efforts in this native Chinese breed, which is threatened by agricultural modernization. Cumulus–oocyte complexes (COCs) were collected from slaughterhouse ovaries and matured in vitro for 22–24 h, then selected for cryopreservation. Vitrification in open pulled straws (OPS) or in microdrops on a cooled metal surface (solid surface vitrification, SSV) was compared. The OPS vitrification solution consisted of 20% ethylene glycol (EG) and 20% DMSO. The SSV solution was a mixture of 35% EG, 5% polyvinyl-pyrrolidon (PVP) and 0.4 M trehalose. Vitrified and warmed oocytes were either fertilized in vitro or parthenogenetically activated. The rates of cleavage and development to blastocysts of fertilized oocytes following OPS versus SSV were not statistically different (38.3 and 12.5% versus 35.8 and 6.0%, respectively). The corresponding rates of parthenogenetic development to blastocysts were also not different (8.2 versus 3.5%, respectively). Development to blastocysts of non-vitrified controls following fertilization was significantly higher than that of the vitrified oocytes (22.6%, P<0.05). These results demonstrate for the first time, that although both OPS and SSV procedures reduced embryonic development, Yunnan Yellow Cattle oocytes are capable of developing to blastocysts following cryopreservation.

Survival of oocytes recovered from vitrified sheep ovarian tissues

The objective of this work was to develop an effective vitrification technique for cryopreserving oocytes in sheep ovarian tissues. Ovaries were surgically recovered from 15 pubertal ewes and the ovarian cortex was cut into sections. Ovarian tissues were placed in equilibration medium consisting of 4% (v/v) ethylene glycol (EG) and 20% (v/v) FBS in TCM-199 on ice for 30 min and transferred to vitrification solution (35% EG, 5% polyvinylpyrrolidone, 0.4 M trehalose and 20% FBS in TCM-199) for 5 min. Ovarian tissues were vitrified by dropping the tissue on the surface of a steel cube cooled by liquid nitrogen. Cumulus-enclosed oocyte complexes (COC) were also collected and vitrified following the procedure used for ovarian tissues. After 2–3 weeks of storage in liquid nitrogen, ovarian tissues and COC were thawed at 37 °C in 0.3 M trehalose and COC in ovarian tissues were mechanically and enzymatically isolated. Vitrified COC and freshly collected COC were washed twice in maturation medium (TCM-199 supplemented with 0.255 mM pyruvate and 10% heat-treated estrus cow serum) and cultured in 50 μl drops of maturation medium under paraffin oil for 23–25 h at 39 °C in a humidified atmosphere of 5% CO 2 in air. After culture, cumulus cells were removed by hyaluronidase treatment and vortexing and oocytes were fixed and stained. No significant differences were observed between vitrified oocytes, oocytes recovered from vitrified ovarian tissues and non-vitrified control oocytes in the percentage of oocytes with acceptable staining per total number of oocytes fixed or with visible chromatin per total number of oocytes with acceptable staining. However, fewer ( P<0.05) oocytes obtained from vitrified ovarian tissues (70%) reached metaphase II compared to vitrified oocytes (88%) and non-vitrified control oocytes (90%). In contrast, when oocytes with at least 3–5 layers of cumulus cells were considered from each of the three groups, no differences ( P>0.05) were observed due to treatment in the percentages of oocytes developing to metaphase II. These results demonstrate that sheep oocytes can be successfully cryopreserved by vitrification of ovarian tissues and exhibit in vitro maturation rates similar to that of vitrified and non-vitrified oocytes.

Successful cryopreservation of mouse blastocysts using a new vitrification solution.

Mouse blastocysts were exposed to solutions containing four concentrations (10, 20, 30 and 40% v/v) of six permeating cryoprotectants (glycerol, ethylene glycol, propylene glycol, dimethyl sulfoxide, 1,3-butanediol and 2,3-butanediol) in phosphate-buffered saline (PBS) with calf serum (CS) at room temperature (20-22 degrees C). Blastocysts were exposed to these solutions for various periods, diluted into PBS plus CS with or without 1 mol trehalose l-1 solution and their subsequent survival in vitro was examined. Two-way anova showed a significant interaction (P < 0.01) between cryoprotectant type, concentration of cryoprotectant and method of dilution. However, no significant interaction was observed between cryoprotectant type and duration of exposure. Results suggest that cryoprotectant-induced injury to nonfrozen blastocysts is variable and depends on the cryoprotectant used. On the basis of toxicity assays, ethylene glycol was the least harmful and was combined with dimethyl sulfoxide and 1,3-butanediol to produce a new vitrification solution. Mouse blastocysts were successfully cryopreserved using a vitrification solution (designated as VSv) consisting of 20% ethylene glycol, 20% dimethyl sulfoxide and 10% 1,3-butanediol (v/v). Embryos were equilibrated in two steps, first in an equilibration solution (designated as ESv: 10% ethylene glycol, 10% dimethyl sulfoxide and 5% 1,3-butanediol; v/v) and then to VSv or one-step in VSv at different exposure times at room temperature, and then vitrified by direct plunging into liquid nitrogen. High developmental rates were obtained in vitro when the embryos were exposed to ESv and VSv for 3 and 0.5 min, respectively (96.2%) or exposed to VSv for 0.5 min (95.4%). Prolonged exposure time proved detrimental to subsequent embryo development in vitro. When vitrified warmed embryos were transferred immediately to pseudopregnant recipients, the rate of development to normal fetuses did not significantly differ from that of the nonvitrified control (two-step, 54.2 and one-step, 45.0 versus 60.0%, P > 0.05). These results suggest that the simple vitrification solution described in this study is effective for the cryopreservation of mouse blastocysts.