A simple and rapid method for cryopreservation of mouse 2-cell embryos by vitrification: Beneficial effect of sucrose and raffinose on their cryosurvival rate

Sucrose affecting successful transplantation of vitrified-thawed mouse ovarian tissues

PURPOSE

The aim of this experiment is to detect effects of varying levels of sucrose on vitrified ovarian tissues.

METHODS

Ovarian tissues of mice were vitrified-thawed. Mice were randomly assigned to the fresh control group and experimental groups. According to different concentration of sucrose in vitrification solution, the experimental groups were randomly divided into Group I (0.2 M sucrose), Group II (0.4 M sucrose), Group III (0.8 M sucrose) and Group IV (1.6 M sucrose). Cytology was followed throughout the oophorectomy and transplantation period. Hormone levels and density of follicle were measured 1 month after transplantation.

RESULTS

The number of days before the resumption of estrous cycles in control group was significantly smaller than those in all of experimental groups. The serum estradiol levels of mice and the follicular density of ovarian grafts in control group were significantly higher than those in all of experimental groups. In addition, the number of days before the resumption of estrous cycles in Group II and Group III were smaller than those in Group I and Group IV. The serum estradiol levels of mice and the follicular density of ovarian grafts in Group II and Group III were significantly higher than those in Group I and Group IV. However, no difference was observed in the number of days before the resumption of estrous cycles and the serum estradiol levels between Group II and Group III. A similar follicular density was also observed in Group II and Group III.

CONCLUSION

Sucrose concentration of 0.4 M or 0.8 M in cryoprotective media is suitable for vitrifying mouse ovarian tissues.

Effect of sugars on maturation rate of vitrified-thawed immature porcine oocytes

This study examined the effects of monosaccharide (glucose), disaccharide (sucrose) and polysaccharides (Ficoll and Lycium barbarum polysaccharide (LBP)) at different concentrations, using ethylene glycol (EG) as membrane-permeating cryoprotectant, on in vitro maturation of vitrified-thawed immature (GV) porcine oocytes. A total of 1145 oocytes were obtained by follicle aspiration from 496 ovaries of pigs slaughtered at a local abattoir and vitrified using a five-step method. After thawing and removal of cryoprotectant, oocytes were cultured for 44 h at 39 degrees C in a humidified atmosphere of 5% CO(2) in air. Oocytes were stained with DAPI and nuclear maturation was examined. The highest maturation rates were obtained in 1.5M glucose (8.62%), 0.75 M sucrose (20.0%), 3.0 g/ml Ficoll (13.79%) and 0.10 g/ml LBP (20.69%), respectively. The maturation rate using 0.75 M sucrose or 0.10 g/ml LBP was significantly higher compared to 1.5M glucose (P<0.05), but there was no significant difference from using 3.0 g/ml Ficoll (P>0.05). The percentage of oocytes reaching metaphase II (MII) stage in the cryopreserved groups was significantly lower than control (P<0.05). These results suggest that LBP is an effective non-permeating membrane cryoprotectant and 0.75 M sucrose or 0.10 g/ml LBP can be used as the vitrification solution for immature porcine oocytes.

Effect of the polyvinylpyrrolidone concentration of cryoprotectant on mouse embryo development and production of pups: 7.5% of PVP is beneficial for in vitro and in vivo development of frozen-thawed mouse embryos

In this study, we investigated the effect of polyvinylpyrrolidone (PVP) concentration on in vitro and in vivo development of 2 cell stage, vitrified ICR mouse embryos using a cryoprotectant consisting of ethylene glycol (EG) and sucrose. M2 was selected as the basic medium for vitrification and thawing. After equilibration with 4% (v/v) EG at 37 C for 15 min, the embryos were vitrified with 35% EG, 5, 6 or 7.5% (w/v) PVP and 0.4 M sucrose at 37 C for 30 sec. One week later, the cryotubes of cryopreserved embryos in liquid nitrogen were directly immersed into a 37 C water bath for 1 min and transferred serially into 300 microl of 0.5 or 0.3 M sucrose at room temperature for 5 min and M2 medium at 37 C for 10 min. The surviving embryos were cultured in KSOM (potassium simplex optimized medium) for 96-120 h in an atmosphere of 5% CO(2) in humidified air. Survival was evaluated by morphological appearance, including membrane integrity and presence of apoptotic blastomeres after thawing. For in vivo evaluation, blastocysts were transferred to the uteri of pseudopregnant mice. The survival rates of the 5 and 7.5% PVP concentration groups showed a significantly higher difference compared with that of the 6% PVP group (85.5 and 86.5 vs. 71.2%), respectively. Each pup in the of 5 and 6% groups was cannibalized immediately after parturition. A litter of live pups was obtained from only the 7.5% PVP groups. Our study indicated that supplementation of EG and sucrose cryoprotectant solution with 7.5% PVP is optimal for successful vitrification of 2-cell stage ICR mouse embryos.

Vitrification as a prospect for cryopreservation of tissue-engineered constructs

Cryopreservation plays a significant function in tissue banking and will presume yet larger value when more and more tissue-engineered products will routinely enter the clinical arena. The most common concept underlying tissue engineering is to combine a scaffold (cellular solids) or matrix (hydrogels) with living cells to form a tissue-engineered construct (TEC) to promote the repair and regeneration of tissues. The scaffold and matrix are expected to support cell colonization, migration, growth and differentiation, and to guide the development of the required tissue. The promises of tissue engineering, however, depend on the ability to physically distribute the products to patients in need. For this reason, the ability to cryogenically preserve not only cells, but also TECs, and one day even whole laboratory-produced organs, may be indispensable. Cryopreservation can be achieved by conventional freezing and vitrification (ice-free cryopreservation). In this publication we try to define the needs versus the desires of vitrifying TECs, with particular emphasis on the cryoprotectant properties, suitable materials and morphology. It is concluded that the formation of ice, through both direct and indirect effects, is probably fundamental to these difficulties, and this is why vitrification seems to be the most promising modality of cryopreservation.

Strain difference in tolerance to low-temperature treatment of fertilized mouse oocytes

Background and Aims:  The aim of this study was to determine which mouse strains exhibit tolerance to cooling when fertilized oocytes have been stored at 4°C. Methods: In-vitro-fertilization-derived oocytes of eight mouse strains were incubated at 4°C in 20 mmol/L Hepes-potassium modified simplex optimized medium (KSOM) medium for 0, 24, 48, 60 or 72 h, and then returned to normal culture conditions at 37°C in KSOM medium. The rates of development of cultured oocytes into blastocysts and cell numbers of blastocysts were examined. In some cases, a Comet assay was carried out to evaluate DNA damage. In addition, the effects of β-mercaptoethanol on the development of the 4°C-treated oocytes were assessed. Results:  Of the eight strains tested, BDF1, B6C3F1 and FVB/N strains exhibited relatively higher degrees of tolerance to 4°C treatment and approximately 90%, 83% and 78% of oocytes treated at 4°C for 48 h developed to morphologically normal blastocysts, respectively. Comet assay revealed no clear DNA damage in oocytes treated at 4°C. Treatment with β-mercaptoethanol failed to improve the in vitro survival rate of low-temperature-treated oocytes. Conclusion:  Strain differences were observed in tolerance to cooling treatment when fertilized oocytes were temporarily treated with 4°C, although the reasons for this remain unclear. (Reprod Med Biol 2006; 5: 43-50).

In vitro growth and maturation as well as fertilization of mouse preantral oocytes from vitrified ovaries

OBJECTIVE

To examine the capacity for fertilization and development of preantral oocytes in oocyte-granulosa cell complexes (OGC) originating from vitrified ovaries.

DESIGN

Experimental animal study.

SETTING

University-based research laboratory.

ANIMAL(S)

Normal (C57BL/6xDBA2) F1 mice in a laboratory environment.

INTERVENTION(S)

Vitrification of mouse ovaries using polyester sheets as a storage device; collection of OGC by enzymatic treatment; in vitro growth (IVG), in vitro maturation (IVM), and in vitro fertilization (IVF).

MAIN OUTCOME MEASURE(S)

We performed histologic analysis of vitrified and warmed ovaries, and measured the successful rate in IVG, IVM, and IVF of oocytes in the OGC collected from the ovaries.

RESULT(S)

The cortical region of ovaries maintained good morphologic structure after vitrification and warming. Upon IVG and IVM, 75.9% of oocytes in OGC matured to the metaphase II (MII) stage. The fertilization rate of these oocytes was 57.5% as compared with 69.5% for fresh ovaries.

CONCLUSION(S)

The vitrification method used was effective for storage of ovaries. The oocytes enclosed in preantral follicles from the ovaries preserved capacity for fertilization and development to preimplantation embryos.

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 can be more favorable than slow cooling

OBJECTIVE

Cryopreservation of embryos and oocytes has become an essential service for infertility treatment. The clinical application of this technology should ensure optimal survival of the embryos and oocytes that are stored and subsequently thawed for transfer. The aim of this review is to compare the widely employed slow cooling procedures with vitrification to evaluate and recommend the more effective and safer procedure.

DESIGN

The review is mainly based on a comparison of the principles, procedures, and results reported in the literature. A historical description of vitrification and personal experiences with this technology are also included.

SETTING

University-based hospitals and private clinics that treat infertility and have published information on cryopreservation.

PATIENT(S)

Women being treated for infertility and reproductive technology clinics.

INTERVENTION(S)

The application of slow cooling involving a range of cooling rates is compared with vitrification using rapid and ultrarapid cooling in simple containers. The purpose of both techniques is the induction of a glasslike state in cells to protect them from damage by ice crystals. The early development of vitrification involved the use of long pre-equilibration procedures. Improved methods resulted from the use of mixtures of penetrating and nonpenetrating solutes that are not toxic and a range of cooling rates.

MAIN OUTCOME MEASURE(S)

Reported number of pregnancies established after transfer of embryos that were cryopreserved by vitrification, or transfer of embryos derived from vitrified oocytes.

RESULT(S)

Both slow cooling and vitrification procedures have resulted in the successful cryopreservation of human embryos and oocytes. Both procedures have resulted in healthy births, although the slow cooling of oocytes gives very low success rates. Vitrification is a promising novel technique in assisted reproductive technology, but comparative success rates are yet to be established.

CONCLUSION(S)

Vitrification is a simple procedure that requires less time and is likely to become safer and more cost effective than slow cooling.

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.

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.

Sugars exert a major influence on the vitrification properties of ethylene glycol-based solutions and have low toxicity to embryos and oocytes

A systematic approach was taken to assess the vitrification properties of ethylene glycol-based solutions supplemented with carbohydrates. Solutions were prepared by weight (gravimetrically) using ethylene glycol as the cryoprotectant, 0.9% NaCl in water, and six different sugars: d-glucose, d(-)-fructose, d-sorbitol, sucrose, d(+)-trehalose, and raffinose. Sugars were added on a molal basis (0. 1, 0.5, and 1 m). Characteristics of the solutions were measured during warming by differential scanning calorimetry using a cooling rate of 100 degrees C/min and a warming rate of 10 degrees C/min. In the absence of carbohydrates a 59 wt% EG-saline solution formed a stable glass. When EG was replaced by an equimolal concentration of glucose, fructose, or sorbitol (monosaccharides) at 0.1, 0.5, or 1.0 m there was no change in the total solute concentration at which vitrification occurred, but the glass transition (Tg) occurred at a higher temperature than in EG-saline alone. When EG was replaced by an equimolal concentration of sucrose or trehalose (disaccharides) both the Tg and the lowest total solute concentration required for vitrification became progressively higher as the molecular weight, or the ratio of sugar to EG in the solutions, increased. At the highest tested disaccharide concentration (1 m) vitrification was achieved at a total solute concentration of 65 wt% (sucrose) and 67 wt% (trehalose). The polysaccharide raffinose significantly modified the vitrification properties of ethylene glycol solutions. When 0.5 or 0.1 m raffinose replaced EG on an equimolal basis the glass transition point was raised more than with either the monosaccharides or the disaccharides. Raffinose allowed vitrification at a total solute concentration of 67 wt% (0.5 m) and 63 wt% (0.1 m). The maturation of immature mouse oocytes, and the development of embryos in media containing 5-7 mM of any sugar was comparable to controls, indicating that they are not toxic. Exposure of freshly collected GV or MII oocytes to sugar concentrations between 0.5 and 1.0 M, for up to 10 min had no significant effect on the proportion which subsequently formed two cells. We conclude that added sugars do contribute to a solutions overall vitrification properties, and their properties should be taken into consideration when vitrification solutions are being designed or modified.

Production of transgenic mice by microinjection of DNA into vitrified pronucleate stage eggs

Vitrification is a technique for cryopreserving cells without crystallization due to elevation of the viscosity during the cooling process. We have developed a rapid and convenient mean of cryopreserving mouse preimplantation embryos by vitrification using a solution (hereafter named DPS) consisting of 2.75 M dimethylsulfoxide, 2.75 M propylene glycol and 1.0 M sucrose. In vitro fertilized pronucleate stage eggs were used because a large number of stage-matched eggs can be obtained at once. Only successfully fertilized eggs were collected and vitrified in DPS. After warming, two DNA constructs were injected into a total of 257 cryopreserved eggs, of which 175 (68%) survived the injection and were transferred into six recipients. All recipients became pregnant and gave birth to a total of 20 pups. When these DNA constructs were concomitantly injected into fresh eggs, 18% of eggs that were transferred developed into live pups, which was the same as the 18% figure for the cryopreserved eggs. With respect to transgenesis, 40% of the pups (8/20) developed from vitrified eggs were transgenic. In terms of the injected eggs that had been transferred, 4.5% of the 213 fresh eggs and 3.1% of the 112 vitrified eggs developed into transgenic mice. These results indicate that the efficiency of production of transgenic mice from vitrified eggs is comparable to that from fresh eggs.