Factors affecting the survival of mouse embryos cryopreserved by vitrification

An overview of oocyte cryopreservation

The ability to cryopreserve human oocytes and store them indefinitely would be beneficial for cancer patients at risk of becoming sterile after therapy, allow women to delay reproduction, and alleviate religious concerns associated with embryo storage. In 1986, Chen was the first to report a pregnancy originating from a frozen-thawed human oocyte. Although over 100 babies have been born from oocyte storage since then, pregnancy rates remain unacceptably low. Adapting embryo cryopreservation techniques to oocyte storage has had limited success and new reproducible methods are needed. Problem areas other than intracellular ice formation and osmotic effects need to be identified. A broad approach of critical analysis should be conducted regarding the entire cryopreservation process from pre-equilibration and cooling, to thawing and stepout. All established facets deserve reanalysis in order to assess which aspects can be optimized or changed so that cellular demise can be avoided and cellular viability enhanced. New methods, including the use of choline-based media and vitrification have proven useful in increasing survival and pregnancy rates in some clinics. Other methods yet untested, such as injection of complex carbohydrates into the oocyte, deserve further studies. Vitrification research has led to the formulation of new ideas and has demonstrated the flexibility of cells to survive cryopreservation. Although successful, vitrification protocols are potentially harmful and technically challenging, due to elevated cryoprotectant concentrations and rapid cooling rates. Bovine embryo vitrification methods have been used to store human oocytes and embryos, particularly blastocysts with some success. Vitrification solutions containing high molecular weight polymers have also proved beneficial by reducing solution toxicity. In general, further advances are needed to improve human oocyte storage before widespread routine clinical use.

Multiple factors affecting the efficiency of multiple ovulation and embryo transfer in sheep and goats

This review offers an overview of the basic characteristics of in vivo embryo technologies, their current status, the main findings and the advances gained in recent years, and the outstanding subjects for increasing their efficiency. The use of superovulation and embryo transfer procedures remains affected by a high variability in the ovulatory response to hormonal treatment and by a low and variable number of transferable embryos and offspring obtained. This variability has been classically identified with both extrinsic (source, purity of gonadotrophins and protocol of administration) and intrinsic factors (breed, age, nutrition and reproductive status), which are reviewed in this paper. However, emerging data indicate that the main causes of variability are related to endocrine and ovarian factors, and so the number of studies and procedures addressing a better understanding and control of these factors may be increased in the future. The accomplishment of this objective, the improvement of procedures for embryo conservation and for the selection and management of recipient females, will allow further development and application of this technology.

Developmental consequences of cryopreservation of mammalian oocytes and embryos

During the last three decades, significant advances have been made in successful cryopreservation of mammalian preimplantation embryos, and more recently oocytes. The ability to cryopreserve, thaw, and establish pregnancies with supernumerary preimplantation embryos has become an important tool in fertility treatment. Human oocyte cryopreservation has practical application in preserving fertility for individuals at risk of compromised egg quality due to cancer treatments or advanced maternal age. While oocyte/embryo cryopreservation success has increased over time, there is still room for improvement. Oocytes and embryos are susceptible to cryo-damage, which collectively entails cellular damage caused by mechanical, chemical, or thermal forces during the freeze-thaw process. Basic studies focused on understanding cellular structures, their composition, and more importantly their functions, in normal cell developments will continue to be critical in assessing, understanding, and correcting oocyte/embryo cryo-damage. This review will delineate many of the oocyte/embryo intracellular and extracellular structures that are or may be compromised during cryopreservation. A global theme presented throughout this review is that many structural components of the oocyte/embryo also have essential functional roles in development. Compromising these cellular structures, and thus their cellular homeostatic functions, can deleteriously influence initial cryo-survival or compromise subsequent normal development through effects on the oocyte and/or early embryo.

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.

Cryopreservation of animal and human embryos by vitrification

Vitrification is a method in which not only cells but also the whole solution is solidified without the crystallization of ice. For embryo cryopreservation, the vitrification method has advantages over the slow freezing method. For example, injuries related to ice is less likely to occur, embryo survival is more likely if the embryo treatment is optimized, and embryos can be cryopreserved by a simple method in a short period without a programmed freezer. However, solutions for vitrification must include a high concentration of permeating cryoprotectants, which may cause injury through the toxicity of the agents. Since the development of the first vitrification solution, which contained dimethylsulphoxide, acetamide, and propylene glycol, numerous solutions have been composed and reported to be effective. However, ethylene glycol is now most widely used as the permeating component. As supplements, a macromolecule and/or a small saccharide are frequently added. Embryos of various species, including humans, can be cryopreserved by conventional vitrification using insemination straws or by ultrarapid vitrification using minute tools such as electron microscopic grids, thin capillaries, minute loops, or minute sticks, or as microdrops. In the ultrarapid method, solutions with a lower concentration of permeating cryoprotectants, thus having a lower toxicity, can be used, because ultrarapid cooling/warming helps to prevent ice formation.

Vitrification of pronuclear-stage mouse embryos on solid surface (SSV) versus in cryotube: Comparison of the effect of equilibration time and different sugars in the vitrification solution

The cryopreservation of pronuclear-stage embryos has particular importance in transgenic technology and human assisted reproductive technology (ART). The objective of this study was to improve the efficiency of cryopreservation of pronuclear-stage mouse embryos. Two vitrification methods (solid surface vitrification (SSV) vs. vitrification in cryotube) have been compared with special emphasis on the effect of the exposure of the embryos to the solutions for various times and the sugar content (trehalose, sucrose, or raffinose) of the vitrification solutions. Pronuclear-stage embryos were either exposed to 1 M dimethyl sulfoxide (DMSO) + 1 M propylene-glycol (PG) solution for 2, 5, 10, or 15 min or not exposed to this "equilibration" solution. The vitrification solutions consisted of 2.75 M DMSO and 2.75 M PG in M2 medium supplemented with 1 M trehalose (DPT), 1 M sucrose (DPS), or 1 M raffinose (DPR). In the cryotube method, groups of 15-25 embryos were transferred into a 1.8 ml cryotube containing 30 microl of DPT, DPS, or DPR. After 30 sec, the cryotubes were directly plunged into liquid nitrogen (LN(2)) and stored for 1 day to 1 month. Vitrified samples were warmed by immersing the cryotubes in a 40 degrees C water bath and then immediately diluted with 300 microl of 0.3 M trehalose, sucrose, or raffinose in M2. In the SSV method, after equilibration 15-20 embryos were exposed to DPT, DPS, or DPR solutions for around 20 sec before being dropped in 2-microl drops onto a pre-cooled (-150 to -180 degrees C) metal surface. Vitrified droplets were stored in cryovials in LN(2). Warming was performed by transferring the vitrified droplets into 0.3 M solutions of trehalose, sucrose, or raffinose at 37 degrees C, respectively. Results showed that both SSV and cryotube vitrification methods can result in high rates of in vitro blastocyst development (up to 58.3 and 68.5% with DPR, respectively), not statistically different from that of the controls (58.3 and 64.4%). Even without the equilibration step prior to vitrification, relatively high-survival rates have been achieved, except for the DPS solution. In conclusion, vitrification of pronuclear-stage mouse embryos can result in high rates of in vitro development to blastocyst, and the use of raffinose in the vitrification solution is advantageous to improve cryosurvival.

Vitrification of turbot embryos: preliminary assays

Successful fish embryo cryopreservation is still far from being achieved. Vitrification is considered the most promising option. Many factors are involved in the success of the process. The choice of a proper vitrification solution, the enzymatic permeabilization of embryos to increase cryoprotectant permeability, the adequate container for embryo loading, and the temperature for thawing, were the parameters considered at different developmental stages in the present study. After vitrification, embryo morphology was evaluated under stereoscopic microscopy, establishing the percentage of intact embryos. Two of the studied parameters yielded differences in this percentage, the volume of straw used for embryo loading (1 ml straws were significantly better than 0.5 ml straws, with regard to post-thawed embryo morphologies), and the thawing temperature, achieving 49% of embryos with intact morphology after thawing at 0 degrees C. After thawing, the intact embryos were incubated and periodically observed to detect morphological changes. Changes in the perivitelline space, shrinkage of the yolk and chorion ruptures as well as a progressive whitening of the embryo and yolk were observed. After 8 h all embryos showed clear signs of degradation and during this incubation period no embryo showed any developmental ability.

Vitrification of ECV304 cell suspensions using solutions containing propane-1,2-diol and trehalose

In this paper, we report on the suitability of solutions containing propane-1,2-diol (propylene glycol, PD), sugars, and salts for the vitrification of the human cell line, ECV304. Cooling (at 10 degrees C/min) and rewarming (at 80 degrees C/min) were at rates that are practicable for the tissues to be studied later. Under these conditions, 45% PD in phosphate-buffered saline (PBS) sometimes froze during cooling and always devitrified during rewarming but both events were avoided if the PBS salts were replaced by an osmotically equivalent concentration of sucrose or trehalose. The effect of such solutions on cells was evaluated using a cell culture assay in which the number of cells recovered after 3 days of culture was divided by the number cells plated, giving a cell multiplication factor or CMF. In the absence of PD the cells tolerated a low-salt concentration in solutions that were made isotonic with sugars, but they recovered poorly when 45% PD was also present. Trehalose gave significantly better recovery than sucrose. When 39% PD and 15% trehalose were included in a low-salt vehicle solution (LSV) that contained approximately 5% of the total salt concentration of PBS (this solution was designated LSV/39/15), the cells exhibited approximately 40% of untreated control CMF following exposure for 9min. LSV/39/15 vitrifies with a glass transition temperature of -102 degrees C, does not devitrify when warmed at 80 degrees C/min, and has suitable dielectric properties for uniform and rapid dielectric heating. An improved method for adding and removing LSV/39/15 gave a CMF of approximately 55% of untreated controls. Using this method, 1.0ml suspensions of ECV304 cells was cooled to, and stored briefly at, -120 degrees C and then rewarmed by immersion in a 37 degrees C water bath ( approximately 75 degrees C/min). The CMF of the cooled samples was similar to that of the exposure-only controls, approximately 50% of the untreated control CMF in both cases.

Successful cryopreservation of mouse ovaries by vitrification

We developed a new method of cryopreservation of whole ovaries by vitrification using DAP213 (2 M dimethyl sulfoxide, 1 M acetamide, and M propylene glycol) as a cryoprotectant. Four-week-old C57BL/6 mice that underwent partial ovariectomy were orthotopically transplanted with cryopreserved or fresh ovaries (experimental or control group) isolated from 10-day-old green fluorescent protein (GFP)-transgenic mice (+/+). GFP-positive pups were similarly obtained from both groups by natural mating or in vitro fertilization (IVF) followed by embryo transfer, indicating that the cryopreserved ovaries by vitrification retain their fecundity. However, a statistically significant difference (P < 0.05) was found between both groups with respect to the following parameters: the number of GFP-positive pups born by natural mating/grafted ovary (0.8 +/- 0.3 for the experimental group versus 2.0 +/- 0.7 for the control group, mean +/- SEM), the number of collected oocytes by superovulation per mouse (7.0 +/- 1.7 for the experimental group versus 22.7 +/- 3.2 for the control group), the percentage of two-cell embryos obtained from GFP-positive oocytes by IVF (38.5% for the experimental group versus 90.0% for the control group). Histologically, normal development of follicles and formation of corpora lutea were observed in frozen-thawed grafts. However, estimated number of follicles decreased in frozen-thawed ovaries compared with fresh ovaries. Taken together, cryopreservation of the ovary by vitrification seems a promising method to preserve ovarian function, but further studies are required to overcome the possible inhibitory effects of this method on the growth of the ovarian graft.

Detection of DNA damage in bovine metaphase II oocytes resulting from cryopreservation

Developmental competence of mammalian oocytes is compromised by currently available oocyte cryopreservation protocols. Experiments were designed to examine the effect of three cryopreservation protocols on the integrity of bovine oocyte DNA. In vitro matured bovine oocytes were cryopreserved either by slow cooling, vitrification in 0.25 ml straws, or in open pulled straws. After thawing/warming, recovered oocytes were immediately subjected to morphological evaluation. Morphologically intact oocytes underwent comet assay to detect cryoinjury at DNA level. All cryopreservation protocols resulted in significant morphological damage as well as DNA damage compared to unfrozen control. Among the morphologically intact oocytes, there was no difference among protocols in the number of oocytes displaying DNA damage. However, oocytes that had been cryopreserved by slow cooling or by vitrification in open pulled straws exhibited more damage than those vitrified in 0.25 ml straws in the extent of DNA damage. If we combine the number of oocytes with morphological damage and oocytes with DNA damage, oocytes cooled by slow cooling resulted in the most damage. This experiment demonstrated that oocyte DNA is a target of cryoinjury and different protocols result in different degrees of damage.

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.

Potential importance of vitrification in reproductive medicine

As early as 1985, ice-free cryopreservation of mouse embryos at -196 degrees C by vitrification was reported in an attempted alternative approach to cryostorage. Since then, vitrification techniques have entered more and more the mainstream of animal reproduction as an alternative cryopreservation method to traditional slow-cooling/rapid-thaw protocols. In addition, the last few years have seen a significant resurgence of interest in the potential benefits of vitrification protocols and techniques in human-assisted reproductive technologies. The radical strategy of vitrification results in the total elimination of ice crystal formation, both within the cells being vitrified (intracellular) and in the surrounding solution (extracellular). The protocols for vitrification are very simple. They allow cells and tissue to be placed directly into the cryoprotectant and then plunged directly into liquid nitrogen. To date, however, vitrification as a cryopreservation method has had very little practical impact on human-assisted reproduction, and human preimplantation embryo vitrification is still considered to be largely experimental. Besides the inconsistent survival rates that have been reported, another problem is the wide variety of different carriers and vessels that have been used for vitrification. Second, many different vitrification solutions have been formulated, which has not helped to focus efforts on perfecting a single approach. On the other hand, the reports of successfully completed pregnancies following vitrification at all preimplantation stages is encouraging for further research and clinical implementation. Clearly, however, attention needs to be paid to the inconsistent survival rates following vitrification.

Effect of polyvinyl alcohol (PVA) concentration during vitrification of in vitro matured bovine oocytes

Polyvinyl alcohol (PVA) was used as a substitute for serum in a vitrification solution for in vitro matured bovine oocytes. In vitro matured bovine oocytes were cryopreserved in various vitrification solutions (VS) supplemented with different concentrations (0.05, 0.1, 0.5, and 1%) of PVA, 20% fetal calf serum (FCS) or without macromolecule supplementation in a gel-loading tip (GL-tip). After warming, vitrified oocytes were examined for effects on survivability, fertilizability, and embryonic development in vitro. At 18 h in vitro fertilization after vitrifying and warming, the number of surviving mature oocytes vitrified in VS without macromolecule supplementation was significantly (P < 0.05) lower than those with macromolecule supplementation. For fertilizability after vitrification, there was no significant difference in the penetration rate of oocytes among fresh oocytes (98.7%); oocytes vitrified in VS supplemented with 0.1 (76.8%), 0.5 (70.2%), or 1% (80.3%) PVA; 20% (84.1%) FCS; or without supplementation (61.7%). Also, the normal fertilization rate was not significantly different in oocytes vitrified with 0.1 (56.5%), 0.5 (43.5%), or 1% (49.7%) PVA and 20% (60.6%) FCS, compared with fresh oocytes (84.0%). Subsequently, vitrified oocytes were examined for embryonic development effects in vitro. The highest proportion of cleaved oocytes after vitrification was obtained in VS supplemented with 0.1% (18.8%) PVA. Additionally, the proportion of development to morula stage (7.7%) in the oocytes vitrified in a VS supplemented with 0.1% PVA was significantly (P < 0.05) superior to that of the 0, 0.5, and 1% PVA-vitrified groups. However, the beneficial effect of PVA addition was not found in blastocyst development. Embryonic development of vitrified oocytes was significantly lower than that of fresh oocytes. In conclusion, the present results indicate that 0.1% PVA supplementation in VS results in a significantly higher rate of morula stage embryos than 0, 0.5, and 1% PVA supplementation, and could replace FCS in VS for vitrification of in vitro matured bovine oocytes.

Vitrification of in vitro produced bovine embryos: in vitro and in vivo evaluations

The efficacy of different vitrification solutions to cryopreserve in vitro produced bovine blastocysts was evaluated based upon in vitro development of embryos in culture and on in vivo development of embryos transferred into recipients. In the first experiment, ethylene glycol + glycerol (Eg + Gly) + different sucrose concentrations were evaluated. There were no significant differences in development rates among solutions. As for hatching, the Eg + Gly + 0.1 M sucrose group had a greater rate as compared with Eg + Gly + 0 M sucrose and Eg + Gly + 0.5 M sucrose groups in the evaluations of Day 6, Day 7 and Day 6 + Day 7 embryos; and, Eg + Gly + 0.3 M sucrose group had a greater rate as compared with the Eg + Gly + 0 M sucrose and Eg + Gly + 0.5 M sucrose groups in evaluations of Day 6 and Day 6 + Day 7 embryos. There were no significant differences in development and hatching rates between Day 6 and 7 in in vitro produced bovine embryos within each treatment group. There were significant differences in nuclei number after vitrification between Eg + Gly + 0.1 M and Eg + Gly + 0 M sucrose groups and the Eg + Gly + 0.5 M sucrose group. Pregnancy after 60 days of transfer and calving rates showed a difference between in vivo produced embryos freshly transferred and in vitro produced embryos vitrified with Eg + Gly + 0.3 M. There were no significant differences in gestation length and sex ratio between treatments. As for birth weight, there were significant differences between fresh in vivo produced embryos and all treatments of in vitro produced embryos. There were significant differences in dystocial parturition between in vivo produced embryos and all treatments with in vitro produced embryos. These results demonstrate that vitrification can be used successfully in the cryopreservation of in vitro produced bovine embryos, and that it might be considered for use in commercial programs.

Permeability characteristics and osmotic sensitivity of rhesus monkey (Macaca mulatta) oocytes

BACKGROUND

Permeability characteristics and sensitivity to osmotic shock are principal parameters that are important to derive procedures for the successful cryopreservation of mammalian oocytes.

METHODS AND RESULTS

The osmotically inactive volume of rhesus monkey oocytes was determined by measuring their volumes in the presence of hypertonic solutions of sucrose from 0.2 to 1.5 mol/l, compared with their volume in isotonic TALP-HEPES solution. Boyle-van't Hoff plots at infinite osmolality indicated that the non-osmotic volumes of immature and mature oocytes were 20 and 17% respectively. Osmotic responses of oocytes exposed to 1.0 mol/l solutions of glycerol, dimethylsulphoxide (DMSO) and ethylene glycol (EG) were determined. Rhesus monkey oocytes appeared to be less permeable to glycerol than to DMSO or to EG. Sensitivity of oocytes to osmotic shock was determined by exposing them to various solutions of EG (0.1 to 5.0 mol/l) and then abruptly diluting them into isotonic medium. Morphological survival, as measured by membrane integrity, of oocytes diluted out of EG depended significantly on the concentration of EG (P < 0.01).

CONCLUSION

Determination of permeability characteristics and sensitivity to osmotic shock of rhesus oocytes will aid in the derivation of procedures for their cryopreservation.

Effects of cooling and warming rate to and from -70 degrees C, and effect of further cooling from -70 to -196 degrees C on the motility of mouse spermatozoa

We have previously reported high survival in mouse sperm frozen at 21 degrees C/min to -70 degrees C in a solution containing 18% raffinose in 0.25 x PBS (400 mOsm) and then warmed rapidly at approximately 2000 degrees C/min, especially under lowered oxygen tensions induced by Oxyrase, a bacterial membrane preparation. The best survival rates were obtained in the absence of glycerol. The first concern of the present study was to determine the effects of the cooling rate on the survival of sperm suspended in this medium. The sperm were cooled to -70 degrees C at rates ranging from 0.3 to 530 degrees C/min. The survival curve was an inverted "U" shape, with the highest motility occurring between 27 and 130 degrees C/min. Survival decreased precipitously at higher cooling rates. Decreasing the warming rate, however, decreased survivals at all cooling rates. The motility depression with slow warming was especially evident in sperm cooled at the optimal rates. This fact is consistent with our current view that the frozen medium surrounding sperm cells is in a metastable state, perhaps partly vitrified as a result of the high concentrations of sugar. The decimation of sperm cooled more rapidly than optimum (>130 degrees C/min), even with rapid warming, is consistent with the induction of considerable quantities of intracellular ice at these rates. When glycerol was added to the above medium, motilities were also dependent on the cooling rate, but they tended to be substantially lower than those obtained in the absence of glycerol. The minimum temperature in the above experiments was -70 degrees C. When sperm were frozen to -70 degrees C at optimum rates, lowering the temperature to -196 degrees C had no adverse effect.

Births after vitrification at morula and blastocyst stages: effect of artificial reduction of the blastocoelic cavity before vitrification

BACKGROUND

In 1996, with the introduction of sequential media, we set up a programme of cryopreservation of supernumerary morulae (day 4) and blastocysts (day 5) using a vitrification procedure. Our results showed that the efficiency of the vitrification method was dependent on the stage of embryo development and was negatively correlated with the expansion of the blastocoele. We postulated that a large blastocoele might disturb cryopreservative potential due to ice crystal formation during the cooling step. We analysed therefore the effectiveness of reducing before vitrification the volume of the blastocoelic cavity.

METHOD

Day 4 and day 5 embryos were vitrified in 40% ethylene glycol-18% Ficoll and 0.3 mol/l sucrose before plunging the straws directly into liquid nitrogen. Artificial shrinkage of the blastocyst was achieved after pushing a needle into the blastocoele cavity until it contracted.

RESULTS

The survival rate post-thawing of day 4 and intact day 5 embryos was correlated with the volume of the blastocoele. In the control group only 20.3% blastocysts or expanded blastocysts survived as compared with 54.5 and 58.5% with morulae and early blastocyst respectively. After puncturing the blastocoelic cavity, an increase in the survival rate of up to 70.6% was noted. The pregnancy rates were improved after the artificial shrinkage procedure (20.5%) compared with the control intact blastocyst group (4.5%) (not significant). After reduction of the blastocoelic cavity, a significant increase in the implantation rate per vitrified blastocyst was observed (12.0 versus 1.4% P < 0.01).

CONCLUSIONS

Our results showed that survival rates in cryopreserved expanded blastocysts could be improved by reducing the fluid content. This was presumably because mechanical damage caused by ice crystal formation was avoided. These observations should be considered when establishing a strategy and a protocol for cryopreservation of day 5 embryos.

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.

Advancements in cryopreservation of domestic animal embryos

The development of embryo freezing technologies revolutionized cattle breeding. Since then, advancements in cryobiology, cell biology, and domestic animal embryology have enabled the development of embryo preservation methodologies for our other domestic animal species, including sheep and goats. Recently, technologies have been developed to cryopreserve pig embryos, notorious for their extreme sensitivity to cooling; horse embryo cryopreservation is in its infancy. While cryopreservation can enhance the utilization of in vitro embryo production technologies, cryosurvival of in vitro-produced (IVP) or micromanipulated embryos is less than that of in vivo-derived embryos. This review outlines recent efforts in livestock embryo cryopreservation. In the near future, use of preserved embryos could be a routine breeding alternative for all livestock producers providing 1) preservation methods for maternal germplasm, 2) global genetic transport, 3) increased selection pressure within herds, 4) breeding line regeneration or proliferation, and 5) methodology for genetic rescue.

Cryopreservation of swine embryos: a chilly past with a vitrifying future

Since the development of embryo freezing technologies for cattle in the 1980s, advances in cryobiology, cell biology and embryology of domestic animals have enabled the development of embryo preservation methodology for the pig, notorious for extreme sensitivity to cooling. This review outlines recent efforts to understand the biology of pig embryos as related to their extreme sensitivity to cooling. Cellular analyses and molecular approaches are discussed that have enabled pig embryos to survive cryopreservation and after transfer develop into live offspring with normal fecundity at maturity. In the near future, use of preserved embryos will be a routine breeding alternative for swine producers, providing: preservation methods for maternal germplasm; global genetic transport; increased selection pressure within herds; breeding line regeneration or proliferation; and methodology for genetic resource rescue. It took almost 50 years after the first successful embryo transfer to develop embryo preservation in the pig. Nonetheless, by applying novel methods described herein, rapid progress has been achieved.

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.

Interactions among water content, rapid (nonequilibrium) cooling to -196 degrees C, and survival of embryonic axes of Aesculus hippocastanum L. seeds

This study investigated the interactions among water content, rapid (nonequilibrium) cooling to -196 degrees C using isopentane or subcooled nitrogen, and survival of embryonic axes of Aesculus hippocastanum. Average cooling rates in either cryogen did not exceed 60 degrees C s(-1) for axes containing more than 1.0 g H(2)O g(-1)dw (g g(-1)). Partial dehydration below 0.5 g gg(-1) facilitated faster cooling, averaging about 200 and 580 degrees C s(-1) in subcooled nitrogen and isopentane, respectively. The combination of partial drying and rapid cooling led to increased survival and reduced cellular damage in axes. Electrolyte leakage was 10-fold higher from fully hydrated axes cooled in either cryogen than from control axes that were not cooled. Drying of axes to 0.5 g g(-1), reduced electrolyte leakage of cryopreserved axes to levels similar to those of control material. Axis survival was assayed by germination in vitro. Axes with water contents greater than 1.0 g g(-1), did not survive cryogenic cooling. Between 1.0 and 0.75 g g(-1), axes survived cryogenic exposure but developed abnormally. The proportion of axes developing normally after being cooled in isopentane increased with increasing dehydration below 0.75 g g(-1), reaching a maximum between 0.5 and 0.25 g g(-1) after being cooled at > or =300 degrees C s(-1). Cooling rates attained in subcooled nitrogen did not exceed 250 degrees C s(-1), and normal development of axes was observed only at < or =0.4 g g(-1). These results support the hypothesis that rapid cooling enhances the feasibility of cryopreservation of desiccation-sensitive embryonic axes by increasing the upper limit of allowable water contents and overall survival.

Sucrose pretreatment for enucleation: an efficient and non-damage method for removing the spindle of the mouse MII oocyte

Oocytes enucleated at metaphase II stage can support reprogramming of transferred nucleus and further developing to term. However, the first polar body in mice sometimes migrates away from the original place of expulsion, so the chromosomes of the oocyte will displace from the first polar body. Thus, it is not always possible to successfully enucleate according to the position of the first polar body. Here we use sucrose treatment to visualize metaphase spindle fibers and chromosomes with standard light microscopy. In the manipulation medium containing 3% sucrose, oocytes of poor quality become shrunken, deformed or fragmented, while oocytes of good quality in the same medium would show a swelling around the metaphase chromosomes and a transparent spindle area, shaped like "infinity" and "0". So it is easy to remove the well-distinguished spindle and chromosomes in oocytes of good quality. Re-examined by Hoechst 33342 stain under the UV light, the enucleation rate was 100%. There was no significant difference in IVF and cleavage rates between the sucrose treatment and the control group. In conclusion, this study demonstrated that 3% sucrose pretreatment can give a method for evaluating embryo quality and more importantly, it can, under a common microscope, allow the visualization of the spindle and chromosomes in oocytes of good quality and hence efficiently improve enucleation rate without any harm.

Vitrification of mouse oocytes using a nylon loop

Cryopreservation of mouse oocytes was improved by the use of ultra-rapid vitrification using a nylon loop of 0.5 mm diameter. Oocytes that were vitrified using the loop survived at high rates and were fertilized following a small hole being made in the zona pellucida (69.8%) and developed to the blastocyst stage in culture (67.4%) at similar rates to that of oocytes that were not cryopreserved. Blastocysts resulting from oocytes vitrified using the nylon loop had similar development of the inner cell mass and trophectoderm as blastocysts from non-cryopreserved oocytes. In contrast, oocytes that were cryopreserved using a slow-freezing protocol where most of the Na+ is replaced with choline had lower rates of fertilization (39.5%), reduced development to the blastocyst stage (25.7%), and blastocysts had reduced development of the inner cell mass. Blastocysts derived from oocytes that were vitrified with the nylon loop were able to implant (88.0%) and develop into fetuses (56.5%) at significantly higher rates compared to blastocysts derived from oocytes that were slow-frozen (52.4 and 26.2%, respectively). Vitrification of mouse oocytes using the nylon loop results in the retention of viability of the oocytes and subsequent embryos.

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.

The effect of prefreezing the diluent portion of the straw in a step-wise vitrification process using ethylene glycol and polyvinylpyrrolidone to preserve bovine blastocysts

A total of 678 bovine blastocysts, which had been produced by in vitro maturation, fertilization, and culture, were placed into plastic straws and were vitrified in various solutions of ethylene glycol (EG) + polyvinylpyrrolidone (PVP). Part of the straw was loaded with TCM199 medium + 0.3 M trehalose as a diluent; the diluent portions of the straw were prefrozen to either -30 or -196 degrees C. Then, the embryos suspended in the vitrification solution were pipetted into the balance of the straw and vitrified by direct immersion into liquid nitrogen. For thawing, the straws were warmed for 3 s in air and 20 s in a water bath at 39 degrees C and then agitated to mix the diluent and cryoprotectant solution for 5 min followed by culture in TCM199 + 10% FCS + 5 + microg/ml insulin + 50 microg/ml gentamycin sulfate for 72 h. Variables that were examined were the time of exposure to EG prior to vitrification, the PVP concentration, and the temperature of exposure to EG + PVP prior to vitrification. Survival and hatching rates of the blastocysts exposed to 40% EG in four steps at 4 degrees C were higher than those of embryos exposed in two steps (81.3 +/- 4.3% and 80.2 +/- 3.4% vs 67.6 +/- 4.5% and 71.5 +/- 4.7%, respectively; P < 0.05). The same indices were superior following vitrification-thawing of the blastocysts in 40% EG + 20% PVP than it was in 40% EG + 10% PVP (76.1 +/- 5.5% vs 63.7 +/- 1.8%; P < 0.05; and 61.6 +/- 6.0% vs 70.5 +/- 4.7%; P < 0.01, respectively). Exposure to the vitrification solution (40% EG + 20% PVP) at higher temperatures (37.5 degrees C vs 4 degrees C) reduced both survival and hatching rates (45.8 +/- 6.9% vs 83.9 +/- 4.4% and 41.5 +/- 1.8% vs 64.0 +/- 4.7%, respectively; P < 0.001). These results indicate that blastocysts vitrified after prefreezing the diluent portions of the straws do favor developmental competence of in vitro produced embryos.

Cryopreservation of equine embryos by open pulled straw, cryoloop, or conventional slow cooling methods

Cryopreservation of equine embryos with conventional slow-cooling procedures has proven challenging. An alternative approach is vitrification, which can minimize chilling injuries by increasing the rates of cooling and warming. The open pulled straw (OPS) and cryoloop have been used for very rapid cooling and warming rates. The objective of this experiment was to compare efficacy of vitrification of embryos in OPS and the cryoloop to conventional slow cool procedures using 0.25 mL straws. Grade 1 or 2 morulae and early blastocysts (< or = 300 microm in diameter) were recovered from mares on Day 6 or 7 post ovulation. Twenty-seven embryos were assigned to three cryopreservation treatments: (1) conventional slow cooling (0.5 degrees C/min) with 1.8 M ethylene glycol (EG) and 0.1 M sucrose, (4) vitrification in OPS in 16.5% EG, 16.5% DMSO and 0.5 M sucrose, or (3) vitrification with a cryoloop in 17.5% EG, 17.5% DMSO, 1 M sucrose and 0.25 microM ficoll. Embryos were evaluated for size and morphological quality (Grade 1 to 4) before freezing, after thawing, and after culture for 20 h. In addition, propidium iodide (PI) and Hoechst 33342 staining were used to assess percent live cells after culture. There were no differences (P > 0.1) in morphological grade or percent live cells among methods. Mean grades for embryos after culture were 2.9 +/- 0.2, 3.1 +/- 0.1, and 3.3 +/- 0.2 for conventional slow cooling, OPS and cryoloop methods, respectively. Embryo grade and percent live cells were correlated, r = 0.66 (P < 0.004). Thus OPS and the cryoloop were similarly effective to conventional slow-cooling procedures for cryopreserving small equine embryos.

Piglets born after vitrification of embryos using the open pulled straw method

Morulae and unhatched blastocysts from Large White hyperprolific (LWh) and Meishan (MS) gilts were selected to test an ultrarapid open pulled straw (OPS) vitrification method with two media. The viability of vitrified/warmed embryos was estimated by the percentage of embryos that developed to the hatched blastocyst stage in vitro or by birth after transfer. In Experiment 1, two cryoprotectant dilution media were compared for cryopreservation of MS and LWh blastocysts: TCM was a standard Hepes-buffered TCM199 + 20% NBCS medium and PBS was a PBS + 20% NBCS medium. After a two-step equilibration in ethylene glycol, dimethyl sulfoxide, and sucrose, 2-5 blastocysts were loaded into OPS and plunged into liquid nitrogen. Embryos were warmed; a four-step dilution with decreasing concentrations of sucrose was applied. In PBS, LWh blastocysts (27%) had a lower viability in vitro than MS blastocysts (67%; P = 0.001). In TCM, no significant difference was observed between genotypes (41% for LWh and 43% for MS blastocysts) and both viability rates were lower than that of the control groups. In Experiment 2, morula-stage LWh and MS embryos were vitrified and warmed using PBS. The viability rate was low and did not differ between LWh (11%) and MS (14%). In Experiment 3, 200 MS and 200 LWh blastocysts were vitrified/warmed as described in Experiment 1 (PBS). In each of 20 MS recipients, 20 embryos were transferred. The farrowing rate was 55% and recipients farrowed four and five piglets (median) for MS and LWh blastocysts, respectively. The OPS method is therefore appropriate for cryopreservation of unhatched porcine blastocysts.

Cryopreservation of Musca domestica (Diptera: Muscidae) embryos

Prior studies on cryopreserving embryos of several non-drosophilid flies established that two Drosophila melanogaster embryo cryopreservation protocols were not directly suitable for use with these species. This paper describes our work on developing a protocol for cryopreservation of embryos of the housefly, Musca domestica. Significant progress was made when permeabilization of the vitelline membrane was optimized, a vitrification solution containing ethylene glycol, polyethylene glycol, and trehalose was formulated, and when cooling and recovery of the cryopreservation protocol included a step which passed the embryos through liquid nitrogen vapor. More than 70% of housefly embryos withstand treatments of dechorionation, permeabilization, loading with cryoprotectant, and dehydration in vitrification solution, but the cooling, warming, and poststorage rearing steps still cause a considerable reduction in survival. About 53% of the vitrified M. domestica embryos hatched into larvae. Relative to the percentage of the control adult emergence, about 13% of the embryos stored in liquid nitrogen developed into fertile adults. Hatching of the F(1) progeny of adults having been cryopreserved as embryos was similar to control levels.

Osmotic behavior of in vitro produced bovine blastocysts in cryoprotectant solutions as a potential predictive test of survival

The osmotic behavior of bovine blastocysts produced in vitro was filmed during exposure to and dilution of cryoprotectant solutions used for vitrification. The relationship between the changes in the diameter of embryos and their subsequent survival was assessed. Embryos collected on Day 6 and Day 7 postinsemination were exposed to 10% glycerol (GLY) for 5 min, 10% GLY + 20% ethylene glycol (EG) for 5 min, and 25% Gly + 25% EG for 30 s, before dilution in 0.85 M galactose and finally in embryo transfer freezing medium (ETF). Embryos that had a higher probability of survival behaved as perfect osmometers, shrinking, reexpanding, or swelling according to an identical pattern, whereas embryos that deviated from this standard usually did not survive. The initial embryo diameter, duration of shrinkage and expansion in 10% glycerol, duration of reexpansion in ETF, and final embryo diameter were clearly predictive of the ability to hatch after culture in vitro. On a given day postinsemination, larger blastocysts were more likely than smaller blastocysts to survive and hatch after exposure to cryoprotectants with or without vitrification.

Overcoming a permeability barrier by microinjecting cryoprotectants into zebrafish embryos (Brachydanio rerio)

The goal of this research was to examine the developmental effects on zebrafish embryos (Brachydanio rerio) when cryoprotectants were directly microinjected into the yolk. Our objectives were to: (i) determine the final concentration of propylene glycol (PG) and dimethyl sulfoxide (Me(2)SO) that the embryos could tolerate without causing teratogenic effects; (ii) determine if the toxicity of Me(2)SO could be reduced by the simultaneous presence of various proportions of amides; and (iii) examine whether this intracellular cryoprotectant incorporation could reduce the cryodamage to the yolk syncytial layer (YSL) after vitrification trials. The rationale for conducting these microinjection experiments was to overcome the permeability barrier of the YSL. Intracellular PG produced better survival than Me(2)SO (P < 0.05). Embryos tolerated both 10- and 30-nl microinjections of PG, yielding final concentrations of 2.3 and 5.0 M within the yolk, resulting in 70 +/- 3 and 35 +/- 4% survival at day 5, respectively. In similar experiments with Me(2)SO, survival was lower than PG at 60 +/- 4 and 14 +/- 4% at 2.4 and 5.2 M. Unlike other cellular systems, the presence of amides, specifically acetamide or formamide, did not reduce the toxicity of Me(2)SO in zebrafish embryos (P > 0.05). During vitrification trials, we estimated a 25% dehydration of the yolk, yielding an effective PG concentration of 5.9 M. However, the incorporation of this vitrifiable concentration of PG was not sufficient to improve the postthaw morphology of the YSL (P > 0.05). Clearly, other factors need to be examined in establishing a successful vitrification protocol for zebrafish embryos.

Vitrification of the oocytes and embryos of domestic animals

After the first successful application of vitrification for embryo cryopreservation 15 years ago, a rapid application of the method in domestic animal embryology was presumed. However, although the advantages of vitrification (simplicity, cost efficiency, speed of the procedure) were widely acknowledged, its use has been mainly restricted to experimental studies. For commercial embryo transfer purposes, the traditional slow-rate or equilibrium freezing has been used. This review attempts to explain the reasons for this phenomenon and discusses the theoretical and practical differences between the two technologies as well as their commercial prospects. Recent developments that improve the efficiency of vitrification and applications to other reproductive technologies are also summarized. These advances may result in considerable advantage and could lead to widespread application of vitrification in certain areas of domestic animal embryology.

Vitrification of buffalo (Bubalus bubalis) oocytes

The objective of the present study was to develop a method for the cryopreservation of buffalo oocytes by vitrification. Cumulus-oocyte complexes (COCs) were obtained from slaughterhouse ovaries. Prior to vitrification of COCs in the vitrification solution (VS) consisting of 4.5 M ethylene glycol, 3.4 M dimethyl sulfoxide, 5.56 mM glucose, 0.33 mM sodium pyruvate and 0.4% w/v bovine serum albumin in Dulbecco's phosphate buffered saline (DPBS), the COCs were exposed to the equilibration solution (50% VS v/v in DPBS) for 1 or 3 min at room temperature (25 to 30 degrees C). The COCs were then placed in 15-microL of VS and immediately loaded into 0.25-mL French straws, each containing 150 microL of 0.5 M sucrose in DPBS. The straws were placed in liquid nitrogen (LN2) vapor for 2 min, plunged and stored in LN2 for at least 7 d. The straws were thawed in warm water at 28 degrees C for 20 sec. For dilution, the COCs were equilibrated in 0.5 M sucrose in DPBS for 5 min and then washed 4 to 5 times in the washing medium (TCM-199+10% estrus buffalo serum). The proportion of oocytes recovered in a morphologically normal form was significantly higher (98 and 88%, respectively; P<0.05), and the proportion of oocytes recovered in a damaged form was significantly lower (2 and 12%, respectively; P<0.05) for the 3-min equilibration than for 1 min. For examining the in vitro developmental potential of vitrified-warmed oocytes, the oocytes were placed in 50-microL droplets (10 to 15 oocytes per droplet) of maturation medium (TCM-199+15% FBS+5 microg/mL FSH-P), covered with paraffin oil in a 35-mm Petri dish and cultured for 26 h in a CO2 incubator (5% CO2 in air) at 38.5 degrees C. Although the nuclear maturation rate did not differ between the 1- and 3-min equilibration periods (21.5+/-10.7 and 31.5+/-1.5%, respectively), the between-trial variation was very high for the 1-min period. This method of vitrification is simple and rapid, and can be useful for cryopreservation of buffalo oocytes.

Endothelial and smooth muscle changes of the thoracic and abdominal aorta with various types of cryopreservation

BACKGROUND

There is a need for cryopreserved arterial allografts in vascular surgery. Vitrification was examined as an alternative to slow cooling. Function of endothelial and adjacent cells was evaluated in the thoracic and abdominal regions of the porcine aorta.

MATERIAL AND METHODS

Aortas from young pigs were harvested and cryopreserved with several treatments: slow cooling at 1 degrees C/min with 10% dimethyl sulfoxide (DMSO) and vitrification with a vitrification solution (VS), performed either in the presence (medium) or in the absence (air) of the cryoprotective medium surrounding the sample. Tetrazolium salt reduction and oxygen consumption were used to assess the mitochondrial activity of the endothelial cells and smooth muscle cells from the aorta.

RESULTS

Fresh aorta showed an increased function from below the aortic arch to the iliac branch. Exposure to cryoprotective solutions reduced significantly the oxygen consumption of the abdominal sections. Samples from the thoracic region had a better response to cryopreservation than those from the abdominal region. There was a significant reduction in tetrazolium salt reduction and oxygen consumption when the samples were cryopreserved immersed in the medium. Significant flaking of the endothelium was observed after vitrification and contributes generally to lower the function.

CONCLUSION

The thoracic region of the aortic wall was more tolerant to the preservation injury, and freezing with DMSO in air offered a better choice of preservation.

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.

Birth of piglets after transfer of embryos cryopreserved by cytoskeletal stabilization and vitrification

Pig embryos suffer severe sensitivity to hypothermic conditions, which limits their ability to withstand conventional cryopreservation. Research has focused on high lipid content of pig embryos and its role in hypothermic sensitivity, while little research has been conducted on structural damage. Documenting cytoskeletal disruption provides information on embryonic sensitivity and cellular response to cryopreservation. The objectives of this study were to document microfilament (MF) alterations during swine embryo vitrification, to utilize an MF inhibitor during cryopreservation to stabilize MF, and to determine the developmental competence of cytoskeletal-stabilized and vitrified pig embryos. Vitrified morulae/early blastocysts displayed MF disruptions and lacked developmental competence after cryopreservation; hatched blastocysts displayed variable MF disruption and developmental competence. Cytochalasin-b did not improve morula/early blastocyst viability after vitrification; however, it significantly (P < 0.05) improved survival and development of expanded and hatched blastocysts. After embryo transfer, we achieved pregnancy rates of almost 60%, and litter sizes improved from 5 to 7.25 piglets per litter. This study shows that the pig embryo cytoskeleton can be affected by vitrification and that MF depolymerization prior to vitrification improves blastocyst developmental competence after cryopreservation. After transfer, vitrified embryos can produce live, healthy piglets that grow normally and when mature are of excellent fecundity.

Effect of osmotic stress on the developmental competence of germinal vesicle and metaphase II stage bovine cumulus oocyte complexes and its relevance to cryopreservation

The effects of osmotic stress on germinal vesicle (GV) and metaphase II (MII) stage bovine cumulus oocyte complexes (COCs) were evaluated by first exposing them to various anisotonic NaCl solutions (75, 150, 600, 1200, 2400, and 4800 +/- 5 mOsm/kg) for 10 min and then returning them to isotonic TL-Hepes solution (270 +/- 5 mOsm/kg) at 20 +/- 2 degrees C. Percentages of oocyte maturation, fertilization, polyspermy, cleavage, and blastocyst formation were measured as endpoints. Exposure to anisotonic conditions had a significant (P < 0.05) effect on the developmental competence of both GV and bovine MII COCs. Oocytes at the GV stage were more sensitive to anisotonic stress than MII oocytes (P < 0.05). None of the GV oocytes developed to the blastocyst stage after exposure to hypertonic conditions (2400 or 4800 mOsm solutions), while exposure to hypotonic conditions (75 or 150 mOsm solutions) resulted in significantly lower (P < 0.05) blastocyst formation (9% and 13%, respectively) compared to the isotonic control (25%). A dramatic decrease to 4% development to blastocyst was observed for MII oocytes following exposure to a 4800 mOsm solution. Blastocyst formation of MII oocytes which were exposed to 75, 150, 600, 1200, or 2400 mOsm solutions were similar (15%, 20%, 18%, 14%, and 13%, respectively; P > 0.05), but lower (P < 0.05) than those in the control group (29%). Exposing GV oocytes to anisotonic conditions increased polyspermic fertilization (P < 0.05), although MII oocytes were not similarly affected (P > 0.05). These data support the hypothesis that osmotic stress is detrimental to bovine oocytes and must be considered when developing optimized cryopreservation procedures for these cells. Mol. Reprod. Dev. 55:212-219, 2000.

Vitrification of mouse and human blastocysts using a novel cryoloop container-less technique

OBJECTIVE

To vitrify mouse and human blastocysts with use of the cryoloop procedure and to assess subsequent development.

DESIGN

Controlled study of vitrification of mouse and human blastocysts.

SETTING

Research department of a private assisted reproductive technology unit.

PATIENT(S)

Blastocysts that were not suitable to be frozen were donated from patients.

INTERVENTION(S)

Culture of pronucleate embryos in sequential media to the blastocyst stage.

MAIN OUTCOME MEASURE(S)

Survival of the vitrification procedure was assessed by reexpansion, hatching, and outgrowth in culture. In addition, the viability of mouse blastocysts was assessed after transfer to pseudopregnant recipients.

RESULT(S)

Vitrification of mouse blastocysts did not affect the ability to reexpand, hatch, or outgrow in culture. Furthermore, implantation rates and fetal development were equivalent for nonfrozen and vitrified blastocysts. Vitrified human blastocysts were able to hatch and outgrow in culture at rates similar to nonfrozen controls.

CONCLUSION(S)

Cryoloop vitrification was able to cryopreserve mouse and human blastocysts without any reduction in the ability to reexpand and hatch in culture. Furthermore, viability was not reduced by the cryoloop vitrification of mouse blastocysts.

A method for differentiating nonunique estimates of membrane transport properties: mature mouse oocytes exposed to glycerol

Measurement of the osmotic response of a cell in the presence of cryoprotectant facilitates the determination of permeability coefficients which, in turn, can be used to design cryopreservation protocols which minimize osmotic stress. One problem encountered in determining permeability coefficients, using the Kedem-Katchalsky (K-K) model of membrane permeability, is that several combinations of the three passive coupled transport coefficients, namely, hydraulic permeability (L(p), microm min(-1) atm(-1)), solute permeability (P(gly), microm s(-1)), and the reflection coefficient (sigma), can give a similar fit to the measured data. A method for determining the "correct" set of coefficients is suggested. The osmotic response of 10 metaphase II mouse oocytes was measured on perfusion with 1.5 mol L(-1) glycerol at 24 degrees C. For 8 of 10 oocytes perfused, two combinations of L(p), P(gly), and sigma gave a predicted response which closely matched the measured osmotic response, depending upon the initial estimates supplied to the software for these parameters. For the remaining two oocytes, similar values for the permeability coefficients were generated regardless of the initial estimates. To determine the correct set of parameters, the K-K equations were used to predict experimental conditions for which volumetric histories would be distinctly different for the two sets of "best-fit parameters," and then additional experimental data were compared to these predictions. Thus a further three oocytes were perfused with 0.2 or 0.5 mol L(-1) glycerol in the absence of nonpermeating solute. In the presence of both 0.2 and 0.5 mol L(-1) glycerol, L(p) = 2.11 +/- 0.69, P(gly) = 0.0016 +/- 0.0015, and sigma = 0.44 +/- 0.11 yielded a very poor fit to the measured response while L(p) = 0.98 +/- 0.70, P(gly) = 0. 0031 +/- 0.0021, and sigma = 0.91 +/- 0.15 yielded a close fit to the measured response. Thus the latter combination of coefficients was taken to be correct.

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

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

Vitrification of mouse embryos in two cryoprotectant solutions

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

In vitro evaluation and pregnancy rates after vitrification of in vitro produced bovine embryos

The efficacy of different vitrification solutions to cryopreserve in vitro-produced bovine blastocysts was evaluated based on in vitro development of embryos in culture and on in vivo development of embryos transferred into recipients. In the first experiment, 2 vitrification solutions were compared: propylene glycol + glycerol (Pg + Gly) and ethylene glycol + Ficoll + sucrose (EFS). Differences in the overall development and hatching rates in favor of EFS were found (56.4 vs 33.3% and 35.4 vs 13.3%; P < 0.05). In the second experiment, 3 vitrification solutions were compared: EFS, modified EFS (EFSm) and ethylene glycol + glycerol (Eg + Gly). The vitrification solutions EFSm and Eg + Gly yield higher hatching rates than did EFS (57.7 vs 59.6 vs 35.7%; P < 0.05). The last experiment was designed to compare in vivo 2 vitrification solutions: EFSm and Eg + Gly. There were no differences between them based on the results obtained after transfer (35.2 vs 43.7%). The vitrification solutions EFSm and Eg + Gly have resulted in good pregnancy rates. These results demonstrated that vitrification can be used successfully in the cryopreservation of in-vitro produced bovine embryos, and it might be considered for use in commercial programs.

Vitrification of in vitro produced bovine blastocysts: methodological studies and developmental capacity

Methodological studies were undertaken to test the validity of a three-step vitrification procedure for bovine in vitro produced embryos using glycerol and ethylene glycol as cryoprotectants. Embryos were produced in a low-phosphate culture system (medium VT1 + 10% foetal calf serum) and vitrified at day 7 post-insemination either in a mixture of 25% glycerol--25% ethylene glycol or a mixture of 10% glycerol--40% ethylene glycol. In the first mixture 67% (n = 283) of blastocysts were re-expanded after 72 h of culture and 53% were hatched while in the second one (n = 65) only 5% survived. The mean number of cells of the surviving blastocysts was correlated with the rate of survival (R2 = 0.47; P = 0.0024). Embryo size (diameter < or > to 180 microm) did not influence blastocyst survival or cell number, but hatching rate was higher for embryos > 180 microm. Embryo survival, hatching rate and cell number 72 h post-warming were not affected by the mode of vitrification (direct plunging into nitrogen liquid or vitrification into nitrogen liquid vapour), the mode of preparation of the vitrification solutions (molar or molal basis) or by the concentration of galactose used as a diluent (0 to 0.85 M). Only one calf was born after transfer of 22 vitrified blastocysts. These results confirm the apparent lack of correlation for cryopreserved embryos between in vitro survival or hatching and viability after transfer.

Cryopreservation of mature bovine oocytes by vitrification in straws

Experiments were conducted to determine optimal conditions for vitrification of in vitro matured bovine oocytes in straws. In the first series of experiments, the effects of stepwise addition before exposure of oocytes to vitrification solution consisting of 30% (v/v) ethylene glycol (EG) with 0.35 M sucrose was tested. The rates of morphological survival and cleavage of oocytes vitrified by the three-step addition procedure were higher than those vitrified by the one-step addition procedure. In the second series, the effect of the concentration of the vitrification solution was tested (20, 30, 40, and 50% EG, all with 0.35 M sucrose). The survival rates of oocytes vitrified in 20 and 30% EG were lower than those in 40 and 50% EG. The rates of cleavage and development to blastocysts of oocytes vitrified in 40% EG were the highest among the four groups. In the third series, the effect of duration of exposure of oocytes to 0.5 M sucrose (1, 5, and 10 min) at the first step during the three-step dilution was tested. Although there were no significant differences among the groups with respect to developmental competence of oocytes vitrified in 40% EG, the highest development rate (10%) to blastocysts was observed when oocytes were exposed to sucrose for 5 min. These data demonstrate that improvements to the concentration of cryoprotectant and addition procedures have critical effects on the developmental competence of oocytes vitrified in straws.

Transfer of fresh and cryopreserved IVP bovine embryos: normal calving, birth weight and gestation lengths

In vitro and in vivo developmental competence of fresh and cryopreserved in vitro produced (IVP) bovine embryos was evaluated up to birth. Three experiments were done. The objective in the first experiment was to develop an optimal vitrification procedure for IVP bovine embryos by determining effects of exposure time (2, 5, 10, 20 min) and temperature (4, 22, 27 degrees C) in cryoprotective agents prior to vitrification on their post-thaw viability. The best combination was used in Experiments 2 and 3. In the second experiment, the importance of post-thaw morphologic selection on pregnancy rates was determined by transferring either selected or unselected single embryos. In the third experiment, pregnancy initiation, maintenance and calving results of vitrified embryos were compared with fresh and conventionally frozen embryos. Fetal losses, birth weights, gestation lengths and frequency of dystocia in the third experiment were monitored. The interaction of exposure time and temperature on both post-thaw re-expansion and hatching rates was significant (P < 0.01). Five minute exposure at 27 degrees C was optimal. In the second experiment, post-thaw selected vitrified embryos had higher pregnancy rates than unselected embryos (P < 0.05). In the third experiment, the pregnancy rate of vitrified embryos did not differ from that of fresh embryos (P > 0.05). However, pregnancy rate of conventionally frozen embryos was lower than that of fresh or vitrified embryos (P < 0.05). Of 92 calves born, 53 were male and 39 were female. Birth weights and dystocia scores of single-born calves did not differ between sexes (P > 0.05). Twin-born calves were lighter than single-born calves (P < 0.05). Overall, the data demonstrate that the transfer of vitrified IVP bovine embryos can result in healthy, apparently normal calves similar to those derived from transfer of fresh and conventionally frozen IVP bovine embryos.

Preliminary experiments on the cryopreservation of penaeid shrimp (Penaeus japonicus) embryos, nauplii and zoea

To improve availability of penaeid seedstock during periods of high demand, experiments were conducted to determine the feasibility of stockpiling embryos by freezing them. Embryos were screened for developmental stage; cryoprotectants, chilling effects, and freezing regimens were likewise evaluated. Juvenile forms (embryos, nauplii and zoea) of Penaeus japonicus were exposed to various cryoprotectants, including dimethyl sulfoxide, glycerol, methanol, ethylene glycerol and polyethylene glycol 300 under ambient temperature (25 degrees C). Following this bioassay, maximum safe concentrations of each cryoprotectant were tested on the juveniles under chilling to 0 degree C and with 42 freezing regimens. Methanol was found to be relatively nontoxic. Early developmental stages were the most sensitive to chilling. Initial attempts to freeze P. japonicus juveniles were reported. The survival rate of nauplii and zoea treated with 10% methanol in natural sea water (35 ppt salinity) and frozen to -15 degrees C was 85%, and some nauplii and zoea survived freezing to -25 and -196 degrees C. However, no treatment yielded normal nauplii or zoea after freezing.

Piglets produced by transfer of vitrified porcine embryos after stepwise dilution of cryoprotectants

A total of 498 porcine embryos at various stages of development collected from superovulated gilts was used to investigate cryopreservation. First, blastocysts (BL), expanded blastocysts (ExB), and hatched blastocysts (HB) were used to determine the effect of exposure to concentrated solutions of ethylene glycol as cryoprotective additives (CPAs) on embryo survival. Then, survival of other embryos after vitrification by rapid cooling was determined. Based on their development after 48 h in culture, embryos were not injured by being exposed to 2.0 M ethylene glycol (EG) for 15 min or to 2.0 M EG for 5 min and then to a solution of 8.0 M EG in 7% polyvinylpyrrolidone (PVP) for 1 min. The CPAs were removed from the embryos by diluting them with 1.7 M galactose. To vitrify the embryos, they were exposed to 2.0 M EG for 5 min and then were pipetted directly into short columns of 8.0 M EG-PVP contained within (1.25-ml plastic straws and separated from long columns of 1.7 M galactose by an air bubble. The straws were plunged directly into LN2. After the straws were warmed rapidly in a 25 degrees C water bath, the embryos were immediately mixed with galactose within the straws by shaking them vigorously to mix the contents. In sequential experiments, three methods were used to dilute the CPA solutions. Method 1: Embryos in the EG-PVP-galactose mixture were expelled from the straws and rinsed and cultured in modified CZB medium (mCZB). Method II: Embryos in the mixture were placed briefly into 1.5 M EG and then rinsed and cultured in mCZB. Method III: Embryos in the mixture were rinsed in 1.0 M EG and then in 0.5 M EG and finally rinsed with mCZB and cultured. After 48 h in culture, the respective percentages of survival of embryos vitrified as BL, ExB, or HB were: Method I, 21, 32, and 13%; Method II, 9, 40, and 24%; Method III, 35, 85, and 71%. Of 20 additional ExB vitrified embryos diluted by Method III and transferred into a recipient, four developed into live piglets; two other recipients failed to litter although one had been pregnant for 65 days. These results demonstrate that porcine embryos can be successfully cryopreserved by rapid cooling in EG-PVP and by careful dilution of the CPA after warming.

Ultrastructure of bovine in vitro-produced blastocysts cryopreserved by vitrification

The objective of this study was to examine ultrastructural aspects of bovine in vitro-produced blastocysts associated with cryopreservation by vitrification. Morphologically good embryos were used and treated with ethylene-glycol-based vitrification solution (VS). The untreated embryos had conventional fine structure. The post-warming embryos treated with direct exposure to VS (one-step procedure) showed cellular damage structurally by cryopreservation, which included loss of microvilli, disruption of the plasma membrane, mitochondrial changes and swelling of the endoplasmic reticulum. However, nuclei and junctional regions seemed to be resistant to cryoinjury. In contrast, the post-warming embryos pre-equilibrated with 10% ethylene glycol for 5 min and subsequent exposure to VS (two-step procedure) showed less damage than those treated by the one-step procedure. Post-warming embryos treated by the two-step procedure were cultured in vitro for 18 h. Some embryos survived and their structures re-formed to the former state, while other embryos showed serious injuries and could not reconstitute the blastocoele. Three post-warming embryos treated by the two-step procedure that survived after in vitro culture were transferred to three recipients and one of these resulted in pregnancy. These results indicate that cryopreservation by vitrification can damage membranous structures of the cells of bovine embryos, the extent and nature of this damage being dependent on the vitrification procedure.