Effect of cryoprotectants and their concentration on post-thaw survival and development of expanded mouse blastocysts frozen by a simple rapid-freezing procedure

Stepwise in-straw dilution and direct transfer using open pulled straws (OPS) in the mouse: a potential model for field manipulation of vitrified embryos

In the present study, mouse blastocysts were employed to investigate the feasibility and efficiency of stepwise in-straw dilution and direct transfer using the open pulled straw (OPS) method. In experiment I, the effects of various vitrification solutions (VS) on embryo survival were examined. After thawing, the expanded blastocyst rates (97.59 and 95.05%) and hatching rates (80.48 and 78.95%) achieved in the EDFS30 [15% ethylene glycol (EG), 15% dimethyl sulfoxide (DMSO), Ficoll, and sucrose] and EFS40 [40% EG, Ficoll, and sucrose] groups were no different from those (96.15% and 83.33%) of the control group. However, the rates in the EFS30 [30% EG, Ficoll, and sucrose] (87.80 and 55.43%) and EDFS40 [20% EG, 20% DMSO, Ficoll, and sucrose] (95.69 and 70.97%) groups were significantly lower than those (96.15 and 83.33%) of the control group (P<0.05). In the experiment II, the effects of the volume of VS in the OPS on the survival of embryos after in-straw thawing were investigated. When the length of the VS in the column was less than 1 cm, the in vitro viability of embryos thawed by stepwise in-straw dilution was no different among the experimental and control groups. The embryos could be successfully thawed by immersing the OPS in 0.5 M sucrose for 3 min and then 0.25 M sucrose for 2 min. In experiment III, the effect of immersion time of the OPS in diluent (PBS) on the viability of vitrified embryos was investigated. After in-straw thawing, OPSs were immersed immediately in 1 ml PBS for 0 to 30 min. When the immersion time of the OPSs in PBS was less than 12 min, in vitro development of the in-straw thawed embryos was no different from that of the controls. In experiment IV, in-straw thawed blastocysts were directly transferred to pseudopregnant mice to examine their in vivo developmental viability. The pregnancy (91.67%) and birth rates (42.42%) of embryos in-straw thawed and directly transferred were no different from those of the unvitrified controls (90.90 and 40%) and embryos thawed by the conventional method (84.61 and 46.94%). These results demonstrate that mouse embryos vitrified with OPS could be successfully thawed by stepwise in-straw dilution and transferred directly to a recipient and that this method might be a model for field manipulation of vitrified embryos in farm animals.

The effects of Vitamin A administration on the development of vitrified-warmed mouse blastocyst

The purpose of this study was to evaluate the development of vitrified-warmed mouse blastocysts following a period of Vitamin A administration. Four to six weeks old BALB/c mice were given an intraperitoneal injection of either 0.1 ml paraffin oil alone (control, Con) or paraffin oil containing 250IU of Vitamin A (experiment, Exp). Ten days later the mice were given second paraffin or paraffin Vitamin A injection and an injection of 10IU equine chorionic gonadotropin (eCG) followed 48 h later by 10IU human chorionic gonadotropin (hCG). Blastocysts were collected from both groups and randomly divided into non-vitrified (Con 1, Exp 1) and vitrified (Con 2, Exp 2) subgroups. Embryos in the vitrified group were exposed sequentially to two solutions (10% ethylene glycol, 10% DMSO in holding medium (HM: DMEMF(12)+10% FBS) and 20% ethylene glycol, 20% DMSO in HM) before plunging into liquid nitrogen. After warming at 37 degrees C, cryoprotectants were diluted serially with 0.25 and 0.15M sucrose solution in HM. The vitrified-warmed and the fresh embryos of the control and the experiment groups were cultured in DMEMF(12) with 10% FBS for 72 h. Although, on the first day of culture, the rate of development to the hatched blastocyst was nearly identical between the two vitrified groups (15.8% versus 13%) but after 48 h, the rate of plated embryos was statistically higher in the vitrified Vitamin A than the vitrified control group (63.1% versus 19.6%, P<0.001). After 48 h, in the non-vitrified groups, the rate of the plated embryos was also significantly higher in the Vitamin A than the control group (70.5% versus 49.3%, P<0.01). These data provided evidence that systemic administration of Vitamin A may enhance the potential development of blastocysts in culture and is capable to reduce the adverse effects of vitrification at least during the first 2 days of cultivation.

Offspring resulting from transfer of cryopreserved embryos in camel (Camelus dromedarius)

The dromedary embryos, collected at hatched blastocyst stage, survived freezing and thawing in the presence of a high concentration of ethylene glycol (7.0 mol/L) with sucrose (0.5 mol/L) and direct plunging in liquid nitrogen. The rate of survival, as judged by the morphological appearance of the embryos after thawing, was high (92%). The transfer of frozen-thawed embryos into the recipients during the breeding (n=20) and non-breeding season (n=25) resulted in two and one pregnancy, respectively. One of the two pregnant recipients, with embryos transferred during the breeding season, delivered a normal healthy male calf at term. To our knowledge, this offspring is the first camelid produced following transfer of a frozen-thawed embryo.

Vitrification of biopsied mouse embryos

Solid surface vitrification (SSV) was compared with in-straw vitrification for cryopreservation of biopsied mouse embryos. Eight-cell stage embryos were zona drilled and one blastomere was removed. Developed morulae or blastocysts were vitrified in microdrop (35% EG + 5% PVP + 0.4 M trehalose) or in straw (7.0 M EG + 0.5 M sucrose). Following recovery, embryos were cultivated in vitro or transferred into recipients. Cryopreservation had an effect not only on the survival of biopsied embryos but also on their subsequent development in vitro. Cryosurvival of biopsied morulae vitrified in straw was significantly inferior to SSV. The post-warm development of biopsied and non-biopsied morulae was delayed on Day 3.5 and 4.5 in both vitrification groups. A delay in development was observed on Day 5.5 among vitrified non-biopsied blastocysts. The percentage of pups born from biopsied morulae or blastocysts following cryopreservation did not differ from that of the control. No significant differences could be detected between methods within and between embryonic stages in terms of birth rate. The birth rate of biopsied embryos vitrified in straw was significantly lower compared to the non-biopsied embryos. The novel cryopreservation protocol of SSV proved to be effective for cryopreservation of morula- and blastocyst-stage biopsied embryos.

Improving post-thaw survival of cryopreserved mouse blastocysts by hydrostatic pressure challenge

The purpose of the experiments was to study the effect of high hydrostatic pressure treatment prior to vitrification to the survival of expanded mouse blastocysts. High hydrostatic pressure has been reported to induce the production of "shock proteins" in bacteria, which can provide a possibility of cross-protection to other environmental stresses. The possible beneficial effects of this alleged principle was examined on embryo vitrification. First, the behaviour of blastocysts was studied at altered pressure conditions. In the second part of the study, pressure treatment was combined with a cryopreservation protocol. Our results indicate that the survival of pressurized mouse embryos depends on the magnitude and the duration of pressure applied. We demonstrated that a preceding pressure treatment strikingly increases the survival of the frozen blastocysts as well as the speed of resumption of the development, and hatching rate.

Effect of cryoprotectants and their concentration on in vitro development of vitrified-warmed immature oocytes in buffalo (Bubalus bubalis)

Experiments were conducted to study the effect of cryoprotectants, dimethyl sulfoxide (DMSO), ethylene glycol (EG), 1,2-propanediol (PROH), and glycerol at different concentrations (3.5, 4, 5, 6, and 7 M each with 0.5 M sucrose and 0.4% BSA in DPBS) on survival, in vitro maturation, in vitro fertilization, and post-fertilization development of vitrified-thawed immature buffalo oocytes. The COCs were harvested from the ovaries by aspirating the visible follicles. The recovery of post-thaw morphologically normal oocytes was lower in 3.5 and 4 M DMSO, EG, and PROH compared to 5, 6, and 7 M. In all the concentrations of glycerol, an overall lower numbers of oocytes recovered were normal compared to other cryoprotectants. Less number of oocytes reached metaphase-II (M-II) stage from the oocytes cryopreserved in any of the concentrations of DMSO, EG, PROH, and glycerol compared to fresh oocytes. Among the vitrified groups, highest maturation was obtained in 7 M solutions of all the cryoprotectants. The cleavage rates of oocytes vitrified in different concentrations of DMSO, EG, PROH, and glycerol were lower than that of the fresh oocytes. The cleavage rates were higher in oocytes cryopreserved in 6 and 7 M DMSO, EG, PROH, and glycerol compared with oocytes cryopreserved in other concentrations. However, the percentage of morula and blastocyst formation from the cleaved embryos did not vary in fresh oocytes and vitrified oocytes. In conclusion, this report describes the first successful production of buffalo blastocysts from immature oocytes cryopreserved by vitrification.

Fertility of mice following receipt of ovaries slow cooled in dimethyl sulphoxide or ethylene glycol is largely independent of cryopreservation equilibration time and temperature

Cryopreservation procedures generally depend on both the cryoprotectant used and the equilibration conditions to which the material is exposed. The aim of the present study was to examine the effect of cryoprotectants (dimethyl sulphoxide (DMSO) and ethylene glycol (EG)) and equilibration conditions (0, 30 or 120 min at 0°C or 120 min at room temperature) on the fertility of mice receiving cryopreserved mouse ovaries. The study compared the fertility of cryopreserved Day 14 mouse pup ovaries following grafting to adult recipient mice for 4 months. There was no effect of the cryoprotectant or equilibration condition used on the interval to the first plugging/mating or on the interval to the birth of the first litter, the size of litters, the number of litters produced or the total number of offspring produced. Despite this, when compared with control females (untreated, sham and fresh transplant) the cryopreservation and transplantation procedures delayed fertility. However, the size of litters was equivalent for all cryopreserved and control groups (P > 0.05). The results show that, for the equilibration conditions examined, DMSO and EG are equally efficient cryoprotective agents for mouse ovarian tissue.

Defined media for vitrification, warming, and rehydration: effects on post-thaw protein synthesis and viability of in vitro derived ovine embryos

The purpose of this study was to assess the viability (rates of re-expanding and hatching in vitro), of in vitro derived ovine blastocysts using vitrification and warming/rehydration media containing fetal calf serum (20% FCS) or polyvinyl alcohol (0.1% PVA), and the incorporation of labelled methionine in protein synthesised during the first 4h after cryopreservation. In experiment 1, after 60 h culture in TCM-199 supplemented with 10% FCS, the hatching rates of blastocysts that had been vitrified, warmed, and rehydrated in media containing only PVA (p/p) were significantly (P<0.05) lower than those vitrified in medium containing PVA with warming and rehydration in medium containing FCS (p/s). Blastocysts that were vitrified in medium containing FCS and warmed and rehydrated in medium with PVA (s/p) had hatching rates that were significantly lower (P<0.01) than those vitrified, warmed, and rehydrated in media with only FCS (s/s). After warming, the number of dead cells in the p/p group was significantly (P<0.05) lower than in all other groups. In experiment 2, the [35S]methionine uptake by embryonic cells of the s/p group was significantly (P<0.01) higher than in other groups. The incorporation of labelled methionine into newly synthesised proteins was significantly lower in the p/p group (P<0.01) than in all other groups. No differences in the newly synthesised proteins were observed between groups. In conclusion, these results suggest that it is possible to replace serum with defined macromolecules in vitrification and warming/rehydration media for in vitro derived ovine blastocysts but this leads to a decrease in viability and a reduction in protein synthesis after warming.

Production of transgenic mice from vitrified pronuclear-stage embryos

Cryopreservation of pronuclear-stage embryos would be useful for transgenic technology and genome preservation purposes. We compared a novel vitrification technique (solid surface vitrification, SSV) with another vitrification method in straws for cryosurvival and to generate transgenic progeny from cryopreserved mouse zygotes following microinjection. The SSV solution consisted of 35% ethylene glycol (EG), 5% polyvinyl-pyrrolidone (PVP), and 0.4 M trehalose in M2 supplemented with 4 mg/ml BSA; the in straw vitrification solution was 7 M EG in M2 plus BSA. In experiment I, we compared the effect of the vitrification solutions alone, without cooling. No reduction was detected in survival and cleavage rates. In experiment II, SSV yielded a significantly higher percentage of morphologically normal zygotes (96%) that also cleaved at significantly higher rates (80%) when compared to that following "in straw" vitrification (68 and 66%, respectively). Cleavage rate in the non-vitrified control group (93%) was significantly higher than that of both vitrified groups. Following embryo transfer, there was no difference in the rate of pups obtained from the SSV, "in straw" vitrified, and control groups (97/457, 21%; 15/75, 20% and 56/209, 27%, respectively). In experiment III, SSV vitrified and fresh embryos were used for pronuclear DNA injection. Survival rate of vitrified embryos after microinjection was reduced compared to nonvitrified ones (64 vs. 72%, respectively; P < 0.05); however, development to two-cell stage was not different (76 vs. 72%, respectively). Following embryo transfer of vitrified vs. fresh microinjected embryos, in both cases 10% live pups were generated, including transgenic pups. The results demonstrated that the efficiency of generating transgenic pups from SSV vitrified pronuclear zygotes is comparable to that from fresh embryos.

Effect of freezing rate and exposure time to cryoprotectant on the development of mouse pronuclear stage embryos

BACKGROUND

The effects of exposure time (20 versus 45 s) to a high concentration of cryoprotectant (7.0 mol/l ethylene glycol with 0.5 mol/l sucrose) and freezing rates (1200-10 300 degrees C/min) during rapid freezing of mouse pronuclear stage embryos on survival and development to blastocysts were investigated. Different freezing rates were achieved by directly plunging the straws (rapid freezing) and open pulled straws (OPS) in liquid nitrogen (OPS freezing) and by plunging the straws (super rapid) and OPS (super OPS) in a super cooled liquid nitrogen chamber (at -212 degrees C) before storage in liquid nitrogen.

METHODS

Morphologically intact mouse zygotes (n = 891) pre-equilibrated in 1.5 mol/l ethylene glycol for 5 min were either loaded in 0.25 ml straws containing cryoprotectant or loaded in OPS with 2 microl cryoprotectant. After 20 or 45 s of loading the straws or mixing in cryoprotectant and loading in OPS, they were plunged either directly in to liquid nitrogen or were plunged first in to liquid nitrogen in a super cooled chamber and then stored in liquid nitrogen. Zygotes were thawed and intact embryos cultured in vitro.

RESULTS

The rate of survival was higher (91%, P < 0.01) when zygotes were frozen with rapid freezing compared with super rapid, OPS and super OPS freezing rates with an exposure time of 20 s (70, 65, and 76% respectively). When zygotes were exposed to cryoprotectant for 45 s and frozen with rapid freezing rates, the survival was higher (86%, P < 0.01) compared with those frozen with OPS (62%) but was not different from those frozen with super rapid and super OPS freezing rates (81 and 75%). A higher rate of survival was observed when zygotes were exposed to cryoprotectant for 45 s and frozen with super OPS than with OPS freezing (75 versus 62%; P < 0.05). The rate of cleavage and development of intact zygotes to blastocysts was not different among the different groups.

CONCLUSION

Exposure of zygotes to a high concentration of cryoprotectant (7.0 mol/l ethylene glycol with 0.5 mol/l sucrose) for 20 or 45 s did not influence their survival and development and increasing the freezing rate from 1200-10 300 degrees C/min was of no advantage when using a rapid freezing procedure for freezing mouse pronuclear stage embryos.

Cryoloop vitrification yields superior survival of Rhesus monkey blastocysts

BACKGROUND

Vitrification using the cryoloop procedure was evaluated for preservation of non-human primate blastocysts by comparing survival results from two different cryoprotectant mixtures with prior results from controlled rate cooling.

METHODS

Rhesus monkey blastocysts were produced by intracytoplasmic sperm injection of mature oocytes from cycling females stimulated with recombinant human hormones. Morphologically well-formed blastocysts were divided between Procedure A (2.8 mol/l dimethylsulphoxide and 3.6 mol/l ethylene glycol with 0.65 mol/l sucrose and 25 micromol/l Ficoll in TALP-HEPES with 20% fetal bovine serum (TH20)) and Procedure B (3.4 mol/l glycerol and 4.5 mol/l ethylene glycol in TH20). After >48 h in liquid nitrogen, the removal of cryoprotectants was accomplished in the presence of a 3-step series of decreasing sucrose concentrations in TH20. Surviving embryos were co-cultured on buffalo rat liver cells.

RESULTS

Of 16 blastocysts vitrified via Procedure A, 38% survived with minimal lysis and only one hatched in culture; in contrast, of 33 blastocysts vitrified by Procedure B, 85% survived and 71% hatched. Of 22 blastocysts cryopreserved by conventional slow cooling, 36% survived and 6% hatched. Transfer into three recipients, each with two embryos vitrified with Procedure B, resulted in a successful twin-term pregnancy.

CONCLUSION

Modified cryoloop vitrification with a final solution of 3.4 mol/l glycerol and 4.5 mol/l ethylene glycol is a promising procedure for preserving Rhesus monkey blastocysts that is simple, rapid, and inexpensive.

Cryopreservation of mouse embryos at morula/compact stage

PURPOSE

The objective of this article was to study mouse morula/compact stage embryo postthaw survival rates and postthaw developmental potential.

METHODS

Mouse morula/compact stage embryos were classified into 3 substages. Their morphological behavior during the freezing and thawing process were examined. Postthaw survival rates and blastocyst formation rates were compared between the three substages and the pronucleate and the 2-cell stage embryos. Finally, Postthaw fully compacted and late compact embryos were transferred to foster mothers.

RESULTS

Blastomeres of early compacting embryos separated from each other during the freezing process, whereas in fully compacted and late compact stages, the blastomeres remain compacted. Fully compacted and late compact stage embryos had higher Postthaw survival rates than other stages, though those were not statistically significant (P > 0.05). These two substages had significantly higher blastocyst formation rates than Postthaw pronucleate and early compacting embryos (P < 0.01). A total of 72 Postthaw fully compacted and late compact embryos were transferred and 20 live offspring were delivered.

CONCLUSIONS

After passing early compacting stage, fully compacted and late compact stage mouse embryos have high Postthaw survival rates and significantly higher blastocyst formation rates. Successful cryopreservation of embryos at these two substages has a significant value in embryo selection. The results obtained in this study may provide useful information for human assisted reproductive technology.

Vitrification of mouse oocytes in ethylene glycol-raffinose solution: effects of preexposure to ethylene glycol or raffinose on oocyte viability

We investigated the effects of preexposure to ethylene glycol (EG) or raffinose on the viability of vitrified mouse oocytes. Ovulated oocytes at the metaphase II stage were preexposed either to 2 M EG for 0, 2, or 5 min or to ascending concentrations (0.15 followed by 0.3 M ) of raffinose solution for 2, 5, or 10 min each (here referred to as 2-2, 5-5, and 10-10 min, respectively). The oocytes were then exposed to a vitrification solution (VS), 6 M EG + 0.3 M raffinose, for 0.5, 1, 2, or 5 min and then vitrified or immediately diluted. After warming, the developmental capacity of oocytes was determined after in vitro fertilization. Volume changes in oocytes during preexposures and exposure to the VS were also investigated. The results demonstrated that preexposure to 2 M EG allowed shorter exposure times of oocytes to the VS and that predehydration in raffinose solutions for 5-5, but not 2-2 or 10-10 min, allowed a wider range of exposure times to the VS. Experiments on volume change suggested that the optimum time of exposure to the VS depends on the amount of EG permeation after preexposure to 2 M EG or to raffinose solutions. Preexposures to 2 M EG or raffinose under optimized conditions increased the viability of vitrified-warmed oocytes compared to direct exposure to VS without preexposures.

Refreezing of murine intact and biopsied embryos by rapid-freezing procedure

The in-vivo development of murine morula stage embryos frozen-thawed once or twice and embryos biopsied after one freezing cycle and refrozen was studied. Embryos (n = 860) were cryopreserved using a rapid-freezing procedure. At least 24 h after freezing, embryos were thawed and cultured in vitro for 3 h. In experiment I, morphologically intact embryos were either transferred (n = 180) into recipients or refrozen (n = 160). Unfrozen embryos (control group, n = 180) and refrozen embryos stored for at least 24 h and then thawed, were transferred into recipients. In experiment II, embryos frozen once were thawed and biopsied or sham-biopsied (n = 230 and 180 respectively) and refrozen (n = 226 and 179 respectively). They were thawed and transferred (n = 192 and 160 respectively) into recipients. Recipient mice were either killed on day 15 after embryo transfer and number of implantation sites and live fetuses recorded or pregnant recipients (n = 6, experiment II) were allowed to carry the fetuses to term. There was no difference in the survival rate of embryos at thawing between those frozen once or twice (91 versus 93%). The implantation rate and number of live fetuses in the pregnant recipients at necropsy among those transferred with unfrozen embryos (57% and 51%; 8/9), embryos frozen once (55% and 45%; 8/9) or twice (51% and 48%; 6/8) was not different. There was no difference in the survival rate of refrozen embryos biopsied or sham-biopsied after one freezing cycle (89 versus 87%). The implantation rate and number of live fetuses in pregnant animals transferred with biopsied or sham-biopsied embryos was not different (64 and 41% versus 57 and 37% respectively). All six pregnant animals allowed to carry the fetuses to term delivered normal live fetuses (n = 39). On mating 12 females with six males of the progeny born out of biopsied embryos, all became pregnant and delivered live fetuses. It may be concluded that murine biopsied and intact embryos can be successfully refrozen by rapid-freezing procedure.

The protective action of polyvinyl alcohol during rapid-freezing of mouse embryos

Biological products like serum and BSA are routinely used in embryo freezing solutions. These products are undefined and can potentially expose the embryos to infectious agents. Therefore, this experiment was designed to evaluate in vitro and in vivo survival of mouse embryos frozen in solutions supplemented with a chemically defined macromolecule, polyvinyl alcohol (PVA). Morula-stage embryos from superovulated mice were collected, frozen by a rapid freezing procedure, and cryoprotectant diluted out (after thawing) in media supplemented with either 10% fetal calf serum (FCS), 0.1 mg/mL PVA, or a combination of 10% FCS and 0.1 mg/mL PVA. Frozen-thawed (good to excellent quality) and nonfrozen (control, collected in FCS supplemented medium) embryos were cultured in medium M16 (32) supplemented with either 4 mg/mL BSA or 0.1 mg/mL PVA for 72 h. Embryos frozen in solutions supplemented with FCS or PVA and nonfrozen embryos were transferred to pseudopregnant recipients. Recipients were humanly killed on Day 15 after transfer, and the rate of implantation and percentage of live fetuses were recorded. The supplementation of collection, freezing and cryoprotectant dilution solutions with FCS, PVA or FCS plus PVA did not influence (P > 0.05) the rate of survival and in vitro development of embryos to hatched/hatching blastocyst-stage. However, a higher (P < 0.01) in vitro development rate to hatching/hatched-stage was recorded when frozen-thawed embryos were cultured in medium supplemented with BSA than with PVA. There was no difference (P > 0.05) in the rate of implantation (68 vs 72%) or percentage of live fetuses (62 vs 60%) between pregnant recipients with embryos frozen in medium with FCS or PVA. The rate of implantation and development of embryos frozen in medium supplemented with PVA or FCS was comparable (P > 0.05) to that of nonfrozen embryos. It may be concluded that PVA can be substituted for FCS in medium for freezing mouse embryos; however, it can not be completely substituted for BSA in the in vitro culture of embryos to the hatched blastocyst stage.