Successful ultrarapid freezing of unfertilized oocytes

Oocytes cryopreservation: state of art

In the present review article we sought to analyze, on the basis of a systematic review, the indications, rationale of oocytes cryopreservation, as well as the techniques that improved the aforementioned procedure in order to higher the pregnancy rate in women undergoing that procedure. Moreover, we pointed out the importance of oocytes cryopreservation in the research field as oocyte banking may be of utmost importance to increase the availability of oocytes for research applications such as genetic engineering or embryo cloning. Oocyte freezing has 25 year of history alternating successes and setbacks. Human oocytes have a delicate architecture but are freezable. Clinical efficiency remains low, but healthy children have been born, indicating that chromosomally normal embryos can originate from frozen oocytes. Freezing protocols are not yet optimal and it is now desirable to combine empirical and theoretical knowledge.

Effect of low temperatures on in-vitro matured bovine oocytes

This research concerned effects of cooling in vitro matured bovine oocytes on subsequent fertilization and development in vitro. Oocytes were maintained at 39 degrees C (control), 20 degrees C, 10 degrees C or 0 degree C for 5, 10, or 20 min, then fertilized and cultured in vitro for 7 d. The proportion of fertilized oocytes that cleaved and developed to the morula/blastocyst stage was compared between different treatments. Duration of exposure had no effect on the results. Fertilization rate was higher (P < 0.05) for oocytes maintained at 39 degrees C (73.2%) than for oocytes cooled at 20 degrees C (58.6%), 10 degrees C (47.3%), or 0 degree C (36.9%). Cleavage rates were 58.3, 45.3, 15.7 and 7.0% for 39 degrees C, 20 degrees C, 10 degrees C and 0 degree C, respectively (P < 0.05). The lowest development rate to the blastocyst stage was obtained with oocytes cooled to 10 degrees C (0.0%) or 0 degree C (0.9%), followed by 20 degrees C (7.1%) and 39 degrees C (16.5%; P < 0.05). In a second experiment, the zona pellucida was removed after cooling but prior to fertilization (zona-free) from a portion of the in vitro- matured bovine oocytes in each treatment. When sperm penetration rates of zona-free oocytes were compared (percentage of oocytes exhibiting > or = 2 pronuclei), there was no difference (P > 0.05) between oocytes cooled at 0 degree C (59.7%) or 10 degrees C (67.9%). However, penetration rates in these 2 groups were lower (P < 0.05) when compared to zona-free oocytes cooled at 20 degrees C (83.1%) or those maintained at 39 degrees C (83.1%). Zona-free oocytes had higher penetration rates (P < 0.05) when cooled at 0 degree C (59.7%) or 10 degrees C (67.9%) than zona-intact oocytes cooled at 0 degree C (37.3%) or 10 degrees C (47.2%). However, there was no difference in the penetration rate when zona-free and zona-intact oocytes were cooled at 20 degrees C or maintained at 39 degrees C. These data demonstrate that cooling in vitro-matured bovine oocytes decreases the percentage of oocytes that undergo fertilization and subsequently develop in vitro. Moreover, at least part of the decrease in fertilization following oocyte cooling is due to effects on the zona pellucida.

Cryopreservation of kunming mouse oocytes using slow cooling, ultrarapid cooling and vitrification protocols

The cryopreservation of oocytes has been only marginally successful with any of the current protocols, including slow cooling, rapid cooling and vitrification. We wished to test the hypothesis that oocytes from a single mouse strain would freeze successfully by 1 of the 3 mentioned protocols. Unfertilized Kunming mouse oocytes obtained 14 h after PMSG/hCG administration were randomly assigned to be cryopreserved after slow cooling, ultra rapid cooling and vitrification. Oocytes were thawed by straws being placed into 37 degrees C water, and their morphological appearance and in vitro fertilization capability were compared with that of oocytes that had not undergone cryopreservation. Survival of oocytes was indicated by the absence of darkened ooplasm or by broken membranes or zona pellucida. Functional integrity was evaluated by the formation of a 2-cell embryo after IVF. Survival rate of slow cooled oocytes did not differ from that seen in vitrified oocytes (55.1 vs 65.9%) but was significantly lower in the rapidly cooled oocytes (24.2%; P < 0.01). The results of IVF of slow cooled and vitrified oocytes were similar to those of the control group (72 and 73 vs 77%; P > 0.05). It appears that Kunming mouse oocytes can be successfully cryopreserved using the slow cooling method with 1,2-propanediol and vitrification, which contains both permeating and nonpermeating cryoprotectants.

Successful freezing of unfertilized mouse oocytes and effect of cocultures in oviducts on development of in vitro fertilized embryos after thawing

PURPOSE

To establish a freeze-thawing method for unfertilized oocytes with a high success rate, we examined several conditions for freeze-thawing. The effects of EDTA and cocultures in oviducts on the development of embryos fertilized in vitro after thawing were also studied.

RESULTS

In the first experiment, unfertilized oocytes that were frozen in 1.5 M dimethylsulfoxide (DMSO) supplemented with 0.2 M sucrose by a slow freeze-thawing method showed the best results (fertilization rate, 71.9%; blastocyst rate per frozen oocyte, 18.8%). The proportion of embryos that developed to blastocysts was significantly higher when DMSO was added at 4 degrees C than at room temperature (39.4 vs 19.4%; P < 0.01). The addition of EDTA (10 microM) to the culture medium did not promote embryo development after fertilization in vitro. However, the rate of development of in vitro fertilized embryos to blastocysts after thawing was significantly higher when the embryos were cultured in oviducts in vitro than the rates in control cultures and those cultured with EDTA (blastocyst rate from fertilized oocytes, 71.4 vs 51.0 and 52.8%, respectively; P < 0.01).

CONCLUSION

Unfertilized mouse oocytes can be cryopreserved successfully by a slow freeze-thawing method with the addition of 1.5 M DMSO and 0.2 M sucrose at low temperatures, and coculture with oviducts enhances the development of embryos that are fertilized in vitro after thawing.

Effect of cryoprotectant concentration, equilibration time and thawing procedure on survival and development of rapid frozen-thawed mature mouse oocytes

Experiments were conducted to develop a simple rapid-freezing protocol for mature mouse oocytes that would yield a high proportion of oocytes with developmental potential. The effects of concentration (3.5, 4.5 and 6.0 M dimethyl sulfoxide (DMSO) all with 0.5 M sucrose) and the duration of exposure (2.5 min vs 45 sec) of oocytes to the cryoprotectant and its extraction after thawing in 2, 3 or 4 steps of descending sucrose concentration were studied. The most effective of the rapid-freezing and thawing protocols (4.5 M DMSO; 45 sec exposure and 3-step thawing) was compared to slow freezing protocols using 1.5 M DMSO and 1.0 M 1,2 propanediol as cryoprotectants. The DMSO concentrations had an effect on survival, fertilization and embryo development using short (45 sec) but not long (2.5 min) exposure. The rate of morphological oocyte survival was significantly higher using 4.5 M DMSO than 3.5 or 6.0 M (92% vs 82 and 73%, respectively). The development of fertilized embryos to blastocysts was also significantly higher at 4.5 M than at 3.5 or 6.0 M (68% vs 42 and 53%, respectively). The extraction of cryoprotectant in 3 or 4 steps of descending sucrose concentration resulted in higher survival (P < 0.01) and fertilization than in 2 steps. The best survival, fertilization and development was achieved with the 3-step procedure. Optimal combinations of conditions were 4.5 M DMSO at 45 sec prefreeze exposure and 3-step extraction of the cryoprotectant. Oocytes frozen by conventional methods had a survival, fertilization and development to blastocyst rate significantly lower than those frozen under the optimal rapid conditions. Thus rapid freezing of mature mouse oocytes with 4.5 M DMSO + 0.5 M sucrose and short prefreeze exposure is effective and has the additional advantage of being less time-consuming than slow freezing methods.

Slow and ultrarapid freezing of fully grown germinal vesicle-stage mouse oocytes: optimization of survival rate outweighed by defective blastocyst formation

PURPOSE

The cryopreservation of mature metaphase II-stage mouse oocytes is associated with decreased fertilizability, spindle damage, and increased polyploidy. Therefore, we investigated the outcome of cryopreservation of immature germinal vesicle-stage mouse oocytes.

METHODS

Oocytes were punctured from Graafian follicles in primed F1 hybrid mice and were then released into maturation medium containing the meiotic inhibitor dibutyryl cyclic AMP. Both slow and ultrarapid freezing protocols with dimethyl sulfoxide, 1,2-proponediol, or a mixture of both agents were tested. We recorded morphological survival rates, in vitro maturation rates, and two-cell and blastocyst formation rates. Each group of frozen oocytes was compared with both unfrozen germinal vesicle-stage oocytes and metaphase II-stage oocytes.

RESULTS

An optimal cryosurvival rate of 78% was reached after ultrarapid freezing with 3 M dimethyl sulfoxide followed by one-step dilution, but a decreased rate of two-cell formation was observed. Freezing with a combination of dimethyl sulfoxide and 1,2-propanediol did not improve this fertilization-decreasing effect. Very low cryosurvival rates after freezing with 1,2-propanediol indicated its inappropriateness for ultrarapid freezing of immature oocytes. The rates of in vitro maturation were equivalent for frozen-thawed and freshly collected germinal vesicle-stage oocytes, independent of the freezing protocol used. We report, nevertheless, as a general characteristic for both slow and ultrarapid freezing of fully grown germinal vesicle-stage oocytes, that the in vitro development up to the blastocyst stage is inhibited despite full nuclear maturation.

CONCLUSION

We report that cryopreservation of immature germinal vesicle-stage oocytes is invariably associated with a low developmental capacity after fertilization. The rate of in vitro nuclear maturation did not equate with developmental competence. This in turn suggests the importance of cytoplasmic maturation for embryonic development.

Developmental capacities of two-cell mouse embryos frozen by three methods

The following three methods were evaluated in order to obtain a most efficient freezing protocol for the preservation of two-cell mouse embryos: (a) slow cooling and slow thawing in 1.5 M dimethyl sulfoxide, (b) slow cooling and fast thawing in 1.5 M propanediol (PROH), and (c) ultrarapid freezing and fast thawing in either 3.5 M DMSO or 3.0 M PROH. In the slow-cooling procedures (a and b) ice nucleation (seeding) was induced manually or automatically. With method a, only a slight difference, 51.8% for manual and 58.9% for automatic seeding, was observed in survival rates, while the development to blastocysts was significantly affected: 35.4% with manual and less than 10% with automatic induction (P less than 0.001). Method b gave high survival (86.2%) and developmental rates (69.0%) with manual seeding compared with automatic seeding (20.7 and 9.8%, respectively; P less than 0.001). Using protocol c, higher survival and developmental rates were obtained with DMSO (84.8 and 55.9%) than with PROH (39.8 and 19.4%, P less than 0.001). These results demonstrate that inducing nucleation manually is superior to the use of a highly sophisticated autoseeding system and that method b with manual seeding is most effective in preserving the developmental capacity of two-cell mouse embryos after freezing and thawing. There is evidence that this is also true of human embryo cryopreservation.