The protective action of glycols against freezing damage of mouse and rat embryos

Abnormal Glucose Metabolism in Male Mice Offspring Conceived by in vitro Fertilization and Frozen-Thawed Embryo Transfer

Frozen and thawed embryo transfer (FET) is currently widely applied in routine assisted reproductive technology (ART) procedure. It is of great necessity to assess the safety of FET and investigate the long-term effect including glucose metabolism on FET-conceived offspring. The mouse model is a highly efficient method to figure out the relationship between the process of FET and offspring health. In this study, we obtained mouse offspring of natural conception (NC), in vitro fertilization (IVF), and FET. Glucose and insulin tolerance test (GTT/ITT) were performed on both chow fed or high fat diet (HFD) fed offspring to examine the glucose metabolism status. We detected hepatic PI3K/AKT pathway by western blotting and transcriptome status by RNA-sequencing. Impaired glucose tolerance (IGT) and decreased insulin tolerance were occurred in FET conceived male offspring. After challenged with the HFD-fed, male offspring in FET group performed earlier and severer IGT than IVF group. Furthermore, higher HOMA-IR index and higher serum insulin level post glucose injected in FET-chow group suggested the insulin resistance status. The PI3K/AKT signaling pathway, the major pathway of insulin in the liver, were also disrupted in FET group. Transcriptomics of the liver reveals significantly downregulated in glucose metabolic process and insulin resistance in the FET-chow group. In our study, FET-conceived male mouse offspring presented glucose metabolism dysfunction mainly manifesting insulin resistance. The hepatic insulin signaling pathway were in concordance with reduced glycogen synthesis, increased glycolysis and enhanced gluconeogenesis status in FET-conceived male offspring.

Ovarian tissue vitrification is more efficient than slow freezing to preserve ovarian stem cells in CF-1 mice

OBJECTIVE

The aim of this study was to investigate the efficacy of protocols for mice ovary cryopreservation to compare the differences in Mouse Vasa Homologue expression (a germline cell marker) and ovarian viability after vitrification or slow freezing.

METHODS

Female CF1 mice aged 40-45 days were randomly divided into three groups: Control, vitrification or slow freezing. Their ovaries were surgically removed, rinsed in saline solution and cryopreserved. For vitrification, we used a commercial protocol and for slow freeze, we used 1.5 M ethylene glycol (EG) as cryoprotectant. After that, the ovaries were processed for histological an immunohistochemical analysis, and counting of primordial, primary, pre-antral and antral follicles.

RESULTS

No significant difference was found in the proportion of high-quality primordial, primary and pre-antral follicles after thawing/warming in the slow freezing and vitrification groups. The immunohistochemistry for MVH antibody demonstrated that the slow freeze group had a higher number of unmarked cells (p=0.012), indicating a harmful effect on the MVH expression in the ovarian tissue, where the cell structure is complex.

CONCLUSION

Although both protocols indicated similar results in the histological analysis of follicular counts, the vitrification protocol was significantly better to preserve ovarian stem cells, an immature germ cell population. These cells are able to self-renew having regeneration potential, and may be effective for the treatment of ovarian failure and consequently infertility.

Development of a Cryopreservation Procedure Employing a Freezer Bag for Pancreatic Islets Using a Newly Developed Cryoprotectant

One of the most important requirements for success in clinical islet transplantation is the use of a large number of viable donor islets. To achieve this, the ability to cryopreserve islets and to establish an islet bank are critical. Previously, we developed a two-step cryopreservation procedure with freezing tubes utilizing low and high concentrations of dimethyl sulfoxide (DMSO) and using a fully automated cryomachine for human pancreatic islets and porcine islet-like cell clusters (ICCs). Based on these experiments, we developed a simple and efficient cryopreservation procedure of a freezer bag for isolated islets using a fully automated computer-controlled cryomachine with a newly developed cryoprotectant consisting of ethylene glycol (EG) instead of DMSO for decreasing injury of the islets by freezing. A 250 ml Cryocyte blood freezer bag and our newly developed cryoprotectant containing ethylene glycol (EG) were used in the freezing procedure. The islets were frozen by a fully automated computer-controlled cryomachine (GE 9,000) with our original program of slow cooling. Nucleation occurred at −8°C, and the frozen islets were stored at −196°C in a liquid nitrogen tank. The frozen-stored islets were subsequently rapidly thawed in a 37°C water bath and cultured before viability testing. In vitro function, the stimulation index of insulin release during the static incubation test for rat islets cryopreserved in a freezer bag vs. nonfrozen islets as control, was 2.13 ± 0.42 and 2.02 ± 0.38 (94.8% compared with control), respectively (n = 5, p = NS). The islet recovery compared with the nonfrozen control group was 85% (n = 5) in insulin content. When 1000 rat islets cryopreserved in a freezer bag were transplanted into the renal capsule of diabetic athymic mice, all the mice became normo-glycemic within 7 days from transplantation. Before nephrectomy, the intravenous glucose torelance test (IVGTT) was performed. The fractional decay constant of the glucose level (K value) of the frozen-thawed group was 0.42 ± 0.06%/min. A histological study of renal subcapsular grafts demonstrated the morphological integrity of the islets. These results demonstrate the utility of our cryopreservation procedure of a freezer bag for isolated islets using a fully automated computer-controlled cryomachine with a newly developed cryoprotectant for the maintenance of viability and function of frozen-stored islets both in culture and after transplantation. Cryopreservation using freezer bags with the new cryoprotectant is an effective and simple method for making an islet bank for clinical trials of islet transplantation.

Successful cryopreservation of mouse oocytes by using low concentrations of trehalose and dimethylsulfoxide

Sugars such as trehalose, sucrose, and glucose are effectively used by a variety of animals (e.g., brine shrimp, tardigrades, some frogs, and insects), as well as by bacteria, yeasts, and plant seeds to survive freezing and extreme drying. The objective of this study was to examine the potential application of sugars to mammalian oocyte cryopreservation. To this end, we used trehalose, a nonreducing disaccharide, and mouse metaphase II oocytes as models. Our experiments show that extracellular trehalose alone affords some protection at high subzero temperatures (e.g., -15 degrees C), which diminishes with further cooling of the oocytes to -30 degrees C and below. When present both intracellularly and extracellularly, trehalose dramatically improves the cryosurvival with increasing extracellular concentrations to 0.5 M, even after cooling to -196 degrees C. Furthermore, the combination of intracellular and extracellular trehalose with small amounts of a conventional penetrating cryoprotectant (i.e., 0.5 M dimethylsulfoxide) provide high survival, fertilization, and embryonic development rates statistically similar to untreated controls. When transferred to foster mothers, cryopreserved oocytes give rise to healthy offspring showing the proof of principle. Our experiments with differential scanning calorimetry indicate that when cooled using the same cryopreservation protocol, the mixture of 0.5 M trehalose and cryopreservation medium undergoes glass transition at high subzero temperatures, which further substantiates the use of sugars as intracellular and extracellular cryoprotectants. Taken together, our results are in agreement with the survival schemes in nature and demonstrate the successful use of sugars in cryopreservation of mammalian oocytes.

Cryopreserved Morulae can be used to Efficiently Generate Germline-transmitting Chimeras by Blastocyst Injection

The production of chimeric mice is a complex process, requiring the careful coordination of tissue culture cell growth, production of a large number (30-75) of competent blastocysts and the availability of appropriately timed pseudo pregnant female mice. Failure at any of these steps can impinge upon the rapid production of chimeras. One potential improvement for the efficient generation of chimeric mice would be the utilization of cryopreserved embryos suitable for injection. C57Bl/6 morulae were frozen using a standard 2-step protocol with ethylene glycol as the cryopreservation agent. We determined that cryopreserved morulae could thaw, culture to blastocyst stage in KSOM media and survive injection at rates equivalent to control embryos. Cryopreserved morulae were also equivalent to controls at all later stages in the process of production of chimeric mice, including birth rate, percentage chimerism of resulting animals and ability to produce germline progeny. Hence, cryopreservation of morulae for blastocyst injection is a suitable option to enhance the efficiency of chimeric mouse generation.

Permeability of mouse oocytes and embryos at various developmental stages to five cryoprotectants

To assess the permeability of mouse oocytes and embryos, matured oocytes and embryos at various stages of development were placed in five cryoprotectant solutions at 25 C for 25 min. From the cross-sectional areas of the oocytes/embryos, the relative change in volume was analyzed. In oocytes, shrinkage was least extensive and recovery was quickest in the propylene glycol solution, showing that propylene glycol permeates the oocytes most rapidly. Dimethyl sulfoxide, acetamide, and ethylene glycol permeated the oocytes slightly more slowly than propylene glycol. The oocytes in glycerol shrunk extensively and then expanded marginally, indicating slow permeation. The volume changes of 1-cell and 2-cell embryos were similar to those of oocytes, showing little change in permeability. In 8-cell embryos, the volume recovered much faster than in the earlier stages especially in glycerol and acetamide. In morulae, the volume recovery was much faster in glycerol and in ethylene glycol; in ethylene glycol, the extent of shrinkage was small and the recovery was fast, indicating an extremely rapid permeation. Although the permeability of oocytes/embryos generally increased as embryo development proceeded, the degree of increase varied greatly among the cryoprotectants. Interestingly, the volume change in propylene glycol was virtually unaffected by the stage of development. Such information will be valuable for determining a suitable protocol for the cryopreservation of oocytes/embryos at different stages of development.

Cryopreservation of embryos of farm animals

This review contains two parts. The first part is devoted to the significant steps in cryopreservation of mammalian embryos with emphasis on cattle and sheep that serve as models of reference. These steps are: (1) shortening of cooling and warming processes; (2) addition and dilution of cryoprotectant in one step; (3) introduction of plastic straw as a freezing and dilution container; (4) the choice of ethylene glycol as the quite universal cryoprotectant because of its low toxicity and high permeability; (5) vitrification, a cryopreservation method which enable passage from the liquid to the solid state by extreme elevation of viscosity due to high concentration of cryoprotectants and very rapid cooling. There are several vitrification solutions which contain dimethyl sulphoxide, glycerol, ethylene glycol, or a mixture of them, as basic cryoprotectants. The second part considers some factors affecting the efficiency of cryopreservation concerning (i) the origin of embryos and (ii) the stage of development and species. The origin of embryos (in vivo versus in vitro): in vitro embryos show a chilling and freezing sensitivity associated with their lipid content which can be modified by the culture conditions. Both conventional freezing and vitrification have been used and it seems that vitrification is more adapted to in vitro embryos when some modifications of initial protocols are carried out, particularly the rate of cooling. Thus considerable progress has been achieved by using the open pulled straw method of Vajta which enables the use of a minimum volume of freezing medium (0.5 microl) and a very high cooling rate that permits rapid traversal of the damaging temperature zone, corresponding to chilling sensitivity. The stage of development and species: not only are there differences between species at the same stage of development but in the same species all stages of development do not survive equally under the same freezing protocol. In cattle for example, oocytes and early stages of development in vivo or in vitro do not survive whereas compacted morulae and blastocysts survive very well. In the pig hatched blastocysts survive better than the other stages. Horse embryos have special characteristics that pose problems for successful freezing. In conclusion, a lot of work remains to be done to define fundamental characteristics of embryos of certain species (pig, horse) and of embryos of some stages or of oocytes.

Cryobiology of rat embryos I: determination of zygote membrane permeability coefficients for water and cryoprotectants, their activation energies, and the development of improved cryopreservation methods

New rat models are being developed at an exponential rate, making improved methods to cryopreserve rat embryos extremely important. However, cryopreservation of rat embryos has proven to be difficult and expensive. In this study, a series of experiments was performed to characterize the fundamental cryobiology of rat fertilized 1-cell embryos (zygotes) and to investigate the effects of different cryoprotective agents (CPAs) and two different plunging temperatures (T(p)) on post-thaw survival of embryos from three genetic backgrounds. In the initial experiments, information on the fundamental cryobiology of rat zygotes was determined, including 1) the hydraulic conductivity in the presence of CPAs (L(p)), 2) the cryoprotectant permeability (P(CPA)), 3) the reflection coefficient (sigma), and 4) the activation energies for these parameters. P(CPA) values were determined for the CPAs, ethylene glycol (EG), dimethyl sulfoxide (DMSO), and propylene glycol (PG). Using this information, a cryopreservation method was developed and the cryosurvival and fetal development of Sprague-Dawley zygotes cryopreserved in either EG, DMSO, or PG and plunged at either -30 or -80 degrees C, were assessed. The highest fetal developmental rates were obtained using a T(p) of -30 degrees C and EG (61.2% +/- 2.4%), which was not different (P > 0.05) from nonfrozen control zygotes (54.6% +/- 3.0%).

Effect of reduced concentrations of glycerol and various macromolecules on the cryopreservation of mouse and cattle embryos

The effect of different macromolecules [bovine serum albumin (BSA), Pluronic F-68, (ET surfactant), or sodium hyaluronate (SH)] on postthaw survival of mouse morulae and in vivo- and in vitro-derived bovine blastocysts frozen in 10, 5, or 1% glycerol solutions was investigated. Embryos were equilibrated with cryoprotectant solution at 25 degrees C for 10 min, seeded at -5 degrees C, cooled at 0.5 degrees C/min to -35 degrees C, and plunged into liquid nitrogen. Embryos were thawed in a 35 degrees C water bath, glycerol was removed with 0.6 M sucrose at 25 degrees C for 5 min, and postthaw viability was evaluated after 1, 24, and 48 h in culture. The addition of BSA supplementation improved postthaw survival of mouse morulae frozen in 5% glycerol, but not in 10% glycerol. All three macromolecular supplements were effective in increasing survival of mouse morulae in 5% glycerol but only BSA and SH were effective in increasing postthaw survival of in vivo- and in vitro-derived bovine blastocysts. None of the macromolecular supplements improved postthaw survival of embryos frozen in 1% glycerol.

Vitrification properties of solutions of ethylene glycol in saline containing PVP, Ficoll, or dextran

Vitrification solutions which are used for cells or embryos generally contain cryoprotectant, physiological saline, and one or more macromolecular solutes. The macromolecules modify the vitrification tendencies of these solutions, but there is little detailed information on the vitrification properties of ethylene glycol solutions containing the additives PVP, Ficoll, and dextran. This study therefore added ethylene glycol to 0.9% NaCl in water (saline) and used differential scanning calorimetry to determine the lowest concentration at which the solution would remain vitreous when a warming rate of 10 degrees C/min was used. In the absence of other additives 59 wt% ethylene glycol (EG) in saline formed a stable glass. When ethylene glycol was replaced by the polymers Ficoll and/or dextran on a weight for weight basis, the resulting solution vitrified less readily than an EG-saline solution even though the total solute concentration was kept constant. The total solute concentration required to form a stable vitreous solution increased as the Ficoll 70,000 and 400,000 MW or dextran 78,000 MW content increased (5, 10, and 20 wt%). Ficoll and dextran had little or no effect on the glass transition and melting points of the solutions. In the presence of PVP vitrification occurred at a total solute concentration of 59 wt% (PVP 360,000 MW) or 60 wt% (PVP 40,000 MW) for all three tested PVP concentrations (5, 10, and 20 wt%). Although this indicates that PVP and EG have comparable vitrification properties, the melting and the glass transition temperature of the solutions rose as the PVP content increased. When 1 m sucrose was added to saline and 0, 5, 10, or 20 wt% PVP 40,000 MW vitrification was achieved with 31, 26, 23, and 15% EG, respectively, indicating that the total solute concentration required for vitrification could be estimated with reasonable accuracy from the sum of the individual components. We conclude that the tested polymers differ in how they interact with ethylene glycol-based vitrification solutions.

Cryopreservation of mammalian embryos and oocytes: Recent advances

The cryopreservation of embryos of most domestic species has become a routine procedure in embryo transfer, and recently, advances have been made in the cold storage of mammalian oocytes. The ability to sustain viable oocytes and embryos from mammalian species at low temperature for prolonged periods of time has important implications to basic and applied biotechnology. Recent advances in the study of physico-chemical behaviour of different cryoprotectants, use of various macromolecule additives in cryoprotective solutions and isolation and use of proteins of plant and animal origin with antifreeze activity offers many new options for cryopreservation of oocytes and embryos of animal and human origin. At the same time rapidly developing methods of oocyte/embryo manipulation such as in vitro embryo production, embryo splitting, embryo biopsying for gene and sex determination, embryo cloning and the isolation of individual blastomers, create new challenges in cryopreservation. Very recent advances in the cryopreservation of mammalian oocytes, in vivo- and in vitro-derived embryos, and micromanipulated embryos are reviewed in this manuscript.

Effect of cryoprotectant and genetic selection for body fat content on embryonic cryosurvival in mice

Lines of mice selected for high (HF) or low (LF) 12-week epididymal fat pad weight as a percentage of body weight were used to investigate the effects of genotype, two cryoprotectants [glycerol (GLY) and propylene glycol (PG)] and genotype x cryoprotectant interaction on cryosurvival of four and eight-cell embryos. Embryos were collected from selection lines and reciprocal crosses of selection lines (HFLF and LFHF) and frozen by established slow-cool methods. Embryos were thawed for 40s at room temperature and then placed in a 37° C waterbath for 1 min. Cryoprotectant was diluted from embryos with either 0.5 M sucrose (GLY-treated) or 1.0 M sucrose (PG-treated). Post-thaw survival was measured as the percentage of embryos developing to 36 h (PTS36), 48 h (PTS48) and hatched blastocyst (PTSHB), respectively. Non-frozen controls were cultured concurrently with frozen embryos. No significant genotype or genotype x cryoprotectant interaction effects were found. Results of the embryo freezing study indicated that selection for high or low fat content did not affect the ability of embryos to survive cryopreservation. There was no indication of embryo heterosis for post-thaw survial. Embryos frozen with GLY survived the freeze-thaw stress significantly better than those frozen in PG (P < 0.05). In vitro development of non-frozen controls at 36 and 48 h did not vary significantly among lines, but in vitro development was significantly different among lines at the hatched blastocyst stage (P < 0.05). Linear contrasts showed that the embryonic genome was responsible for differential in vitro development at the hatched blastocyst stage between these selected lines (HF > LF; P < 0.05); asymmetric response also occurred in that both HF and LF exceeded the unselected control line (P < 0.05).

Cryopreservation of equine oocytes by 2-step freezing

Immature equine oocytes were frozen-thawed with ethylene glycol (EG), 1,2-propanediol (PD) or glycerol (GL) in PBS and cultured to assess the rate of in vitro maturation (Experiment 1). Compact-cumulus oocyte complexes were collected from slaughterhouse ovaries and equilibrated for 10 min in the freezing medium containing 10% (V/V) cryoprotectant and 0.1 M sucrose. The 0.25-ml straws, loaded with 10 to 30 oocytes, were seeded at -6 degrees C and cooled to -35 degrees C at 0.3 degrees C/min before being plunged into liquid nitrogen. The straws were thawed rapidly in a 37 degrees C waterbath for 20 sec. The proportions of frozen-thawed oocytes reaching Metaphase II (MII) stage after in vitro maturation of 32 h were 15.8% (EG), 5.8% (PD) and 0% (GL), while 63.3% of the nonfrozen control oocytes matured in vitro. The fertilizing ability of immature and mature oocytes after freezing in EG was tested by the insemination of zona-free oocytes with stallion spermatozoa (Experiment 2). Spermatozoa were preincubated for 3 h with 5 mM caffeine, treated with 0.1 mu M ionophore A23187, and inseminated for 20 h at the concentration of 1 to 2 x 10(7)/ml with 6 to 10 oocytes in 50 mu l of Brackett and Oliphant (BO) medium. Immature oocytes (Group 1) were matured in vitro after thawing and then their zona pellucida removed using 0.5% protease. The zona of mature oocytes were removed immediately after thawing (Group 2) or maturation (nonfrozen controls). The oocytes, which had mechanically damaged plasma membrane or lost by artifact, were not examined for insemination. Significantly more control oocytes exhibited a polar body at the time of insemination (53.5%) than either frozen-thawed immature or mature oocytes (25.8 and 27.3%, respectively). Similar proportion of frozen-thawed and control oocytes were penetrated by spermatozoa (71.8 to 79.1%) and exhibited 2 or more pronuclei (73.6 to 80.8%). The mean numbers of spermatozoa per penetrated oocyte were 1.9, 3.0 and 2.5, respectively, for Groups 1 and 2 and for the control oocytes. These results indicate that immature equine oocytes mature to the MII stage in vitro following freezing and thawing in EG or PD but not in GL. Stallion spermatozoa can penetrate zona-free immature and mature oocytes following freezing/thawing in EG and form morphologically normal pronuclei.

Analysis of cryoprotectant, cooling rate and in situ dilution using conventional freezing or vitrification for cryopreserving sheep embryos

Two studies were conducted to evaluate the influence of cryoprotectant, cooling rate, container and cryopreservation procedure on the post-thaw viability of sheep embryos. In Study 1, late morula- to blastocyst-stage embryos were exposed to 1 of 10 cryoprotectant (1.5 M, glycerol vs propylene glycol)-plunge temperature treatments. Embryos were placed in glass ampules and cooled at 1 degrees C/min to -5 degrees C, seeded and further cooled at 0.3 degrees C/min to -15, -20, -25, -30 and -35 degrees C before rapid cooling by direct placement in liquid nitrogen (LN(2)). Post-thaw embryo viability was improved (P<0.01) when embryos were cooled to at least -30 degrees C before LN(2) plunging. Although there were no overt differences in embryo viability between cryoprotectant treatments (each resulted in live offspring after embryo transfer), there was a lower (P<0.01) incidence of zona pellucida damage using propylene glycol (4%) compared to glycerol (40%). In Study 2, embryos were equilibrated in 1.5 M propylene glycol or glycerol or a vitrification solution (VS3a). Embryos treated in propylene glycol or glycerol were divided into ampule or one-step((R)) straw treatments, cooled to -6 degrees C at 1 degrees C/min, seeded, cooled at 0.5 degrees C/min to -35 degrees C, held for 15 minutes and then transferred to LN(2). Embryos vitrified in the highly concentrated VS3a (6.5 M glycerol + 6% bovine serum albumin) were transferred from room air to LN(2) vapor, and then stored in LN(2). Propylene glycol- and glycerol-treated embryos in straws experienced lower (P<0.05) degeneration rates (27%) and yielded more (P<0.05) hatched blastocysts (73 and 60%, respectively) at 48 hours of culture and more (P<0.05) trophoblastic outgrowths (67 and 53%, respectively) after 1 week than vitrified embryos (47, 40 and 20%, respectively). In vitro development rate for VS3a-treated embryos was similar (P>0.10) to that of ampule controls, which had fewer (P<0.05) expanded blastocysts compared to similar straw treatments. Live offspring were produced from embryos cryopreserved by each straw treatment (propylene glycol, 3 of 7; glycerol, 1 of 7; VS3a, 2 of 7). In summary, freeze-preservation of sheep embryos was more effective in one-step straws than glass ampules and propylene glycol tended to be the optimum cryoprotectant. Furthermore, these findings demonstrate, for the first time, the biological competence of sheep embryos cryopreserved using the simple and rapid procedure of vitrification.

Genome cryopreservation: a valuable contribution to mammalian genetic research

Mouse embryo banking has become an important asset to geneticists. Individual laboratories can now maintain a far greater diversity of stocks than by conventional breeding alone. Also, many mutations that in the past would have been discarded due to lack of space, can now be preserved for future use. Recent advances in cryopreservation techniques have simplified procedures and, in certain cases, resulted in increased rates of survival.

Factors affecting the survival of mouse embryos cryopreserved by vitrification

Preimplantation stage mouse embryos have been used to examine the response of a simple multicellular system to cryopreservation by the complete vitrification of the suspension. Successful vitrification requires the use of a solution of cryoprotectants that is sufficiently concentrated to supercool and solidify into a glass at practicable cooling rates. Factors that influence the survival of embryos include the concentration and composition of the vitrification solution, the procedure used to equilibrate embryos in this solution, the cooling and warming conditions, and the procedure used to dilute embryos from the vitrification solution. High rates of survival are obtained when embryos are dehydrated prior to vitrification in solutions composed of saline plus multimolar concentrations of either mixtures of permeating cryoprotectants (e.g. dimethyl sulphoxide-acetamide-propylene glycol) or single permeating cryoprotectants (propylene glycol or glycerol). Full permeation of cryoprotectants into the cells is not necessary and may lead to chemical toxicity and osmotic injury. Partial permeation and osmotic shrinkage concentrates the endogenous cytoplasmic macromolecules and greatly increases the likelihood of intracellular vitrification. Vitrification is a practical approach for embryo cryopreservation and offers new opportunities to examine fundamental aspects of cryoprotection and cryoinjury in the absence of freezing.

Evaluation of cryopreservation techniques for bovine embryos

A total of 228 embryos was nonsurgically collected from superovulated cows and dehydrated in dimethyl sulfoxide (DMSO) or glycerol by a three-step procedure or a (T.I.T.) timed interval titration procedure. Embryos were loaded in straws, frozen by cooling to -6.0 degrees C at 1.0 degrees C/min, and seeded, followed by cooling to -30 degrees C at 0.3 degrees C/min and to -38 degrees C at 0.1 degrees C/min. At this time the straws were plunged into liquid nitrogen at -195 degrees C. Embryos were thawed in a 27 degrees C or 37 degrees C water bath and rehydrated by a six-step, three-step (sucrose) or one-step (sucrose) procedure. This yielded a 2 x 2 x 2 x 3 factorial treatment structure. Survival was based on development after 12 h in in vitro culture. The only significant single factor affecting survival was the initial quality grade of the embryo. Grades 1 and 2 embryos survived more often than Grade 3 embryos (P < 0.05). Using DMSO as the cryoprotectant resulted in better scores for the post dehydration to post thawing interval (P = 0.02). For both intervals, post dehydration to post thawing and post thawing to post rehydration, the previous quality grade was significant in determining the subsequent quality grade (P < 0.01). At each step of the freeze-thaw process, the embryos became progressively less morphologically intact.

The effects of time of equilibration with cryoprotectants at 0 degree C prior to freezing on the survival of mouse embryos frozen by the two-step method

Mouse embryos were frozen by the two-step method after equilibration for 0.1-60 min with cryoprotectants at 0 degree C. No survival or a very low survival was obtained after equilibration for only 0.1 min. The morulae showed the highest survival rates when equilibration time was 5-30 min with 2 M DMSO, 20-30 min with 2 M glycerol, 5-10 min with 2 M ethylene glycol and 20-30 min with 2 M propylene glycol, respectively.

Factors affecting the survival of mouse embryos during freezing and thawing

This paper reports the survival of mouse embryos after freezing when glycol derivatives or erythritol is used as the cryoprotectant and also describes the two-step preservation of mouse embryos (rapid cooling to solid CO2 or liquid nitrogen vapor before transfer to liquid nitrogen). Ethylene glycol was the most effective cryoprotectant of glycols tested and considerable protection against freezing injury was also afforded by propylene glycol. When embryos were frozen in glycerol by a solid CO2 procedure or liquid nitrogen vapor, a relatively high survival was obtained but the survival was lower than that of embryos frozen slowly. Sucrose dilution of glycerol from the embryos frozen-thawed rapidly improved the survival rates. Survival of embryos frozen by the present two-step method was high on rapid thawing but poor on slow thawing, suggesting that the method of rapid freezing permits the formation of some intracellular ice.

Cryobiology: preservation of mammalian embryos

The preservation of mammalian embryos has become a routine procedure. Thousands of live offspring have been produced from frozen-thawed embryos transferred into recipient foster mothers. Species whose embryos have been successfully preserved include mouse, rat, rabbit, sheep, goat, cattle, horse, antelope, baboon, and human. During the past few years, novel procedures have been introduced that permit embryos to be frozen and thawed rapidly, and to be transferred into recipients under field conditions almost immediately upon thawing. Thus, the transfer of frozen-thawed embryos of domestic animals is becoming almost as efficient as is artificial insemination using frozen-thawed semen. Because of both the inherent fundamental interest and the practical applications of embryo freezing, a substantial understanding of the mechanisms responsible for freezing damage of embryos has been achieved. To survive freezing, embryos must be exposed to protective compounds; to function after thawing, embryos must be washed free of these compounds. Based on fundamental physiology, efficient methods to accomplish such washing have been developed. Furthermore, to survive freezing, embryos must be cooled under conditions in which intracellular ice does not form. This can be accomplished either by pretreating the embryo or by cooling it in such a way as to cause it to dehydrate during freezing. Maximum survival of embryos appears to be achieved when intracellular water does not crystallize during cooling or during warming. As a result of the growing efficiency of embryo preservation, this method is being applied to a variety of practical situations. For example, large banks of frozen embryos of laboratory animals are being established to preserve valuable research resources. The freezing of cattle embryos is being used with increasing frequency as an adjunct to commercial embryo transfer. Preservation of endangered species by embryo preservation is beginning. And finally, the preservation of human embryos is finding application in the field of in vitro fertilization.

High survival of mouse embryos after rapid freezing and thawing inside plastic straws with 1-2 propanediol as cryoprotectant

A method for obtaining a high survival rate of frozen-thawed mouse embryos is presented. Eight-cell mouse embryos were frozen inside small plastic straws in the presence of 1-2 propanediol and stored at -196 C. After thawing, the embryos were diluted for only 5 min in a 1.0 M sucrose solution to remove the 1-2 propanediol from the cells. At high rate of thawing (is equivalent to 2500 C/min) more than 88% of the embryos survived in vitro to the blastocyst stage provided that the dilution of propanediol was performed rapidly during thawing. At a lower rate of thawing (is equivalent to 300 C/min), survival tended to be higher (94.7%) when dilution was done 5 min after thawing. When the frozen-thawed embryos were transferred to the oviducts of day 1 pseudopregnant recipients either directly after the dilution of 1-2 propanediol or after 24 or 48 hr of culture, a high proportion of them (65.9%) develop normally to viable fetuses.

Survival of mouse embryos after freezing and thawing in the presence of erythritol

Eight-cell mouse embryos were frozen by using erythritol as the cryoprotective agent. The samples were cooled slowly (1 degree C/min) to temperatures between -15 and -75 degrees C before direct transfer into liquid nitrogen (-196 degrees C). The most effective concentration of erythritol for freezing of embryos was 0.6 M, and the optimal exposure time of embryos to 0.6 M erythritol at 0 degrees C prior to freezing appeared to be 60 min under the conditions used. The embryos in erythritol survived slow thawing (approximately 20 degrees C/min), only when cooled slowly to temperatures between -30 and -60 degrees C before transfer into liquid nitrogen, and survived rapid thawing (approximately 500 degrees C/min), only after transfer from -25 to -40 degrees C. The highest survival rates of slowly thawed embryos were obtained after transfer to -196 degrees C from -35 (63%) and -40 degrees C (64%), and the highest survival rates of rapidly thawed embryos were obtained after transfer from -30 degrees C (54%). Mouse embryos that survived freezing and thawing with erythritol as the cryoprotective agent were capable of developing to full-term fetuses.