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.     

Generation of Live Offspring from Vitrified Mouse Oocytes of C57BL/6J Strain

In mammals, unfertilized oocytes are one of the most available stages for cryopreservation because the cryopreserved oocytes can be used for assisted reproductive technologies, including in vitro fertilization (IVF) and intracytoplasmic sperm injection. However, it has generally been reported that the fertility and developmental ability of the oocytes are reduced by cryopreservation. C57BL/6J mice, an inbred strain, are used extensively for the production of transgenic and knockout mice. If the oocytes from C57BL/6J mice can be successfully cryopreserved, the cryopreservation protocol used will contribute to the high-speed production of not only gene-modified mice but also hybrid mice. Very recently, we succeeded in the vitrification of mouse oocytes derived from ICR (outbred) mice. However, our protocol can be applied to the vitrification of oocytes from an inbred strain. The aim of the present study was to establish the vitrification of oocytes from C57BL/6J mice. First, the effect of cumulus cells on the ability of C57BL/6J mouse oocytes to fertilize and develop in vitro was examined. The fertility and developmental ability of oocyte-removed cumulus cells (i.e., denuded oocytes, or DOs) after IVF were reduced compared to cumulus oocyte complexes (COCs) in both fresh and cryopreserved groups. Vitrified COCs showed significantly (P<0.05) higher fertility and ability to develop into the 2-cell and blastocyst stages compared to the vitrified DOs with cumulus cells and vitrified DOs alone. The vitrified COCs developed to term at a high success rate, equivalent to the rate obtained with IVF using fresh COCs. Taken together, our results demonstrate that we succeeded for the first time in the vitrification of mouse oocytes from C57BL/6J mice. Our findings will also contribute to the improvement of oocyte vitrification not only in animals but also in clinical applications for human infertility.     

Effect of different cryopreservation protocols on cytoskeleton and gap junction mediated communication integrity in feline germinal vesicle stage oocytes

Oocyte cryopreservation in carnivores can significantly improve assisted reproductive technologies in animal breeding and preservation programs for endangered species. However, the cooling process severely affects the integrity and the survival of the oocyte after thawing and may irreversibly compromise its subsequent developmental capability.In the present study, two different methods of oocyte cryopreservation, slow freezing and vitrification, were evaluated in order to assess which of them proved more suitable for preserving the functional coupling with cumulus cells as well as nuclear and cytoplasmic competence after warming of immature feline oocytes.From a total of 422 cumulus enclosed oocytes (COCs) obtained from queens after ovariectomy, 137 were stored by vitrification in open pulled straws, 147 by slow freezing and 138 untreated oocytes were used as controls. Immediately after collection and then after warming, functional coupling was assessed by lucifer yellow injection and groups of fresh and cryopreserved oocytes were fixed to analyze tubulin and actin distribution, and chromatin organization. Finally, COCs cryopreserved with both treatments were matured in vitro after warming. In most cases, oocytes cryopreserved by slow freezing showed a cytoskeletal distribution similar to control oocytes, while the process of vitrification induced a loss of organization of cytoskeletal elements. The slow freezing protocol ensured a significantly higher percentage of COCs with functionally open and partially open communications (37.2 vs. 19.0) and higher maturational capability (32.5 vs. 14.1) compared to vitrified oocytes. We conclude that although both protocols impaired intercellular junctions, slow freezing represents a suitable method of GV stage cat oocytes banking since it more efficiently preserves the functional coupling with cumulus cells after thawing as well as nuclear and cytoplasmic competence. Further studies are needed to technically overcome the damage induced by the cryopreservation procedures on immature mammalian oocytes.     

Microtubulin configuration and mitochondrial distribution after ultra-rapid cooling of bovine oocytes

Considerable attention has been focused on the cryopreservation of mammalian oocytes, as a consequence of poor development of cryopreserved bovine oocytes in vitro, in order to enhance the application of genetic engineering. Experiments were carried out to evaluate the viability and ultra-structural changes of bovine oocytes cryopreserved by ultra rapid cooling methods. Oocytes that had been allowed to mature for 22 hr were exposed to a mixture of cryoprotectants (3.2 M ethylene glycol, 2.36 M dimethyl sulfoxide (DMSO), 0.6 M sucrose), and were cryopreserved by very rapid cooling either within glass capillaries or as droplets on copper electron microscope grids. After being warmed, the oocytes were cultured in in vitro maturation (IVM) medium for an additional 2 hr. Viability was assessed by determining the development rate after fertilization with frozen-thawed semen from which motile sperm had been recovered using a Percoll density gradient, and by immunochemical evaluation of microtubule and mitochondrial morphology. Cleavage and development rates were significantly (P < 0.05) lower in oocytes cryopreserved by vitrification than in in vitro fertilization (IVF) control group, but did not differ in the open-pulled glass (OPG) or copper grid (CG) groups. In most oocytes cryopreserved by vitrification, the microtubules were partially or completely broken. Similarly mitochondria appeared to be abnormal compared to that of unfrozen oocytes. Oocytes cultured in IVM medium supplemented with both cytochalasin B (a protein synthesis inhibitor) and 2-mercaptoethanol (an antioxidant) showed less damage to microtubules, but not to mitochondria after cryopreservation. In conclusion, this study showed that bovine oocytes can be cryopreserved by vitrification within small droplets using CGs. While damage to microtubules and mitochondria may be involved in reduced viability, supplementation of IVM medium with cytochalasin B appears to enhance stabilization of microtubules during oocyte cryopreservation.     

Cryopreservation of human failed maturation oocytes shows that vitrification gives superior outcomes to slow cooling

This study investigated whether failed maturation oocytes could be used to evaluate different cryopreservation procedures. A total of 289 failed maturation oocytes (GV and MI stages), obtained from 169 patients undergoing IVF treatment (mean age 33.84 ± 5.0) were divided into two different slow-cooling groups (1.5 mol/l 1,2-propanediol + 0.2 mol/l sucrose in either NaCl (group A) or choline chloride (ChCl) (group B) based cryopreservation solutions) and one vitrification group (15% ethylene glycol + 15% dimethyl sulphoxide). Survival rate, in vitro maturation (IVM) rate, fertilization and developmental rate of cryopreserved oocytes were assessed. Regardless of the stage at which cryopreservation was performed (GV + MI), the slow cooling with ChCl based medium always gave significantly lower survival rate than the slow cooling in NaCl based medium (p = 0.01) and vitrification (p < 0.001). An extended study also showed statistically reduced survival rate between slow-cooling NaCl based medium and vitrification (p < 0.05). Global results of in vitro maturation and fertilization showed worse results between both slow-cooling NaCl and ChCl based media versus vitrification. In conclusion, for oocytes that had failed to mature, vitrification gave better survival, maturation, fertilization and also cleavage rates than the slow-cooling protocols. Four cells embryos were obtained only from vitrified in vitro matured MI oocytes.     

Cryopreservation of bovine oocytes: is cryoloop vitrification the future to preserving the female gamete?

The cryoloop is a technique where a thin nylon loop is used to suspend a film of cryoprotectant containing the oocytes and directly immersing them in liquid nitrogen. 508 bovine oocytes were collected, of these 351 were cryopreserved by slow freezing using standard straws or a new vitrification method using our self-constructed cryoloops and the remainder were controls. After thawing, the oocytes were inseminated by ICSI or standard IVF. The cryoloop vitrification method yielded a survival rate of 90.5% and the slow freezing technique a rate of 54.4% (p < 0.0001). When ICSI was performed, cryopreservation by the cryoloop vitrification method resulted in very similar cleavage rate to controls (16.0% vs. 17.3%) but slow freezing produced a slightly lower rate (9.4%). Cleavage rates after IVF in fresh oocytes was higher than the cryopreservation groups (49.5% vs. 15.4% and 25.8%), whereas after ICSI the rates were similar in all groups (17.3% vs. 9.4% and 16%). It is concluded that the new cryoloop vitrification technique followed by ICSI produce good embryo formation results and they could hold the future for effective oocyte cryopreservation.     

Effects of reproductive aging and postovulatory aging on the maintenance of biological competence after oocyte vitrification: insights from the mouse model

Cryopreservation of female reproductive cells allows preservation of fertility and provides materials for research. Although freezing protocols have been optimized, and there is a high survival rate after thawing, the in vitro fertilization (IVF) pregnancy rate is still lower in cycles with cryopreserved oocytes, thus highlighting the importance of identifying intrinsic limiting factors characterizing the cells at time of freezing. The aim of the present study is to investigate in the mouse model the impact of reproductive aging and postovulatory aging on oocyte biological competence after vitrification. Metaphase II oocytes were vitrified soon after retrieval from young and reproductively old mice. Part of the oocytes from young animals was vitrified after 6 h incubation (in vitro aged oocytes). All classes of oocytes showed similar survival rate after vitrification. Moreover, vitrification did not alter chromosomal organization in young cells, whereas in vitro aged and old oocytes presented an increase of slightly aberrant metaphase configurations. Compared to fresh young oocytes, in vitro aged and old oocytes showed increased ROS levels which remained unchanged after vitrification. By contrast, cryopreservation significantly increased ROS production in young oocytes. Both the aging processes negatively impacted oocyte ability to undergo pronucleus formation and first cleavage after vitrification by stimulating cellular fragmentation. These results could be helpful for establishing the correct time table for cryopreservation in the laboratory routine and improving its application in reproductively old females. Moreover, our observations highlight the importance of oxidative stress protection during vitrification procedures.     

Effectiveness of slow freezing and vitrification for long-term preservation of mouse ovarian tissue

This study was conducted to evaluate the interaction between cryo-damage and ART outcome after cryopreservation of mouse ovarian tissues with different methods. Either a vitrification or a slow freezing was employed for the cryopreservation of B6CBAF1 mouse ovaries and follicle growth and the preimplantation development of intrafollicular oocytes following parthenogenesis or IVF were monitored. Both cryopreservation protocols caused significant damage to follicle components, including vacuole formation and mitochondrial deformities. Regardless of the cryopreservation protocols employed, a sharp (P < 0.0001) decrease in follicle viability and post-thaw growth was detected. When IVF program was employed, significant (P < 0.05) decrease in cleavage and blastocyst formation was notable in both modes of cryopreservation. However, such retardation was not found when oocytes were parthenogenetically activated. In the IVF oocytes, slow freezing led to better development than vitrification. In conclusion, a close relationship between cryopreservation and ART methods should be considered for the selection of cryopreservation program.     

Cryopreservation of porcine embryos derived from in vitro-matured oocytes

This study describes a cryopreservation method for porcine in vitro-produced (IVP) embryos using as a model parthenogenetic embryos derived from in vitro-matured (IVM) oocytes. IVP embryos at the expanded blastocyst stage were cryopreserved by vitrification using the minimum volume cooling (MVC) method and exhibited an embryo survival rate of 41.2%. Survival was then significantly improved (83.3%, P < 0.05) by decreasing the amount of cytoplasmic lipid droplets (delipation) prior to vitrification. IVP embryos at the 4-cell stage also survived cryopreservation when vitrified after delipation (survival rate, 36.0%), whereas post-thaw survival of nondelipated embryos was quite low (9.7%). Furthermore, it was demonstrated that porcine IVP morulae can be cryopreserved by vitrification following delipation by a noninvasive method (survival rate, 82.5%). These results clearly confirm that porcine embryos derived from IVM oocytes can be effectively cryopreserved with high embryo survival using the MVC method in conjunction with delipation.     

Cryopreservation of human failed maturation oocytes shows that vitrification gives superior outcomes to slow cooling

This study investigated whether failed maturation oocytes could be used to evaluate different cryopreservation procedures. A total of 289 failed maturation oocytes (GV and MI stages), obtained from 169 patients undergoing IVF treatment (mean age 33.84 ± 5.0) were divided into two different slow-cooling groups (1.5 mol/l 1,2-propanediol + 0.2 mol/l sucrose in either NaCl (group A) or choline chloride (ChCl) (group B) based cryopreservation solutions) and one vitrification group (15% ethylene glycol + 15% dimethyl sulphoxide). Survival rate, in vitro maturation (IVM) rate, fertilization and developmental rate of cryopreserved oocytes were assessed. Regardless of the stage at which cryopreservation was performed (GV + MI), the slow cooling with ChCl based medium always gave significantly lower survival rate than the slow cooling in NaCl based medium (p = 0.01) and vitrification (p < 0.001). An extended study also showed statistically reduced survival rate between slow-cooling NaCl based medium and vitrification (p < 0.05). Global results of in vitro maturation and fertilization showed worse results between both slow-cooling NaCl and ChCl based media versus vitrification. In conclusion, for oocytes that had failed to mature, vitrification gave better survival, maturation, fertilization and also cleavage rates than the slow-cooling protocols. Four cells embryos were obtained only from vitrified in vitro matured MI oocytes.     

Live piglets derived from in vitro-produced zygotes vitrified at the pronuclear stage

We report the successful cryopreservation of in vitro-produced porcine zygotes. Follicular oocytes from prepubertal gilts were matured (IVM), fertilized (IVF), and cultured (IVC) in vitro. At 10 or 23 h after IVF, the oocytes were centrifuged to visualize pronuclei. Zygotes with two or three pronuclei were used for solid surface vitrification (SSV). Survival of vitrified-warmed zygotes was determined by their morphology. To assess their developmental competence, vitrified (SSV), cryoprotectant-treated (CPA), and untreated (control) zygotes were subjected to IVC for 6 days. Survival and developmental competence did not differ between control and CPA zygotes. The proportion of live zygotes after SSV and warming (93.4%) was similar to that in the controls (100%). Cleavage and blastocyst formation rates of SSV zygotes after vitrification (71.7% and 15.8%, respectively) were significantly lower than those of controls (86.3% and 24.5%, respectively; ANOVA P<0.05). Blastocyst cell numbers of SSV and control embryos were similar (41.2+/-3.4 and 41.6+/-3.3, respectively). There was no difference in developmental ability between zygotes cryopreserved at an early (10 h after IVF) or late (23 h after IVF) pronuclear stage. Storage in liquid nitrogen had no effect on the in vitro developmental competence of vitrified zygotes beyond the reduction induced by the vitrification itself. When the embryo culture medium was supplemented with 1 muM glutathione, the rate of development of cryopreserved zygotes to the blastocyst stage did not differ significantly from that of control glutathione-treated zygotes (18.6% and 22.1%, respectively). To test their ability to develop to term, vitrified zygotes were transferred to five recipients, resulting in three pregnancies and the production of a total of 17 piglets. These data demonstrate that IVM-IVF porcine zygotes can be cryopreserved at the pronuclear stage effectively without micromanipulation-derived delipation, preserving their full developmental competence to term.     

Development of vitrified mouse oocytes after in vitro fertilization

Mouse oocytes were cryopreserved by the vitrification method using vitrification solution (VSI) and the effects of dilution methods were examined on the rate of in vitro and in vivo development. Eighty-three percent and 75% of vitrified oocytes exhibited normal morphology when diluted in glycerol + sucrose and sucrose alone, respectively. In contrast, only 35% of the oocytes diluted by a stepwise method exhibited a normal appearance. A high proportion of vitrified oocytes was fertilized in vitro (84-94%), 80 to 87% of which were normal. Of the later embryos, 69 to 78% developed to blastocysts after 4 days of culture. Thirty-six live young (51%) were obtained when vitrified oocytes were transferred to recipient females. The overall rate of development to live young was 25% when vitrified oocytes were diluted with glycerol + sucrose solution. These results indicate that the simple and rapid procedure of vitrification and glycerol + sucrose dilution is suitable for the cryopreservation of mouse oocytes.     

Effect of meiotic stages and maturation protocols on bovine oocyte's resistance to cryopreservation

We investigated the effect of meiotic stages and two maturation protocols on bovine oocyte's resistance to cryopreservation. Oocytes at germinal vesicle breakdown (GVBD) and metaphase II (MII) stage as well as oocytes matured for 22 h in media supplemented with FSH or LH were vitrified by the open pulled straw method. After warming, oocytes underwent additional 16 h (GVBD group) or 2 h (MII group) maturation. Then they were subjected to in vitro fertilization and culture. Some oocytes that matured in the medium supplemented with LH were subjected to parthenogenetic activation after vitrification to determine their developmental potential in absence of fertilization. Survival of oocytes after vitrifying/warming was determined after 22 h in fertilization medium. Cleavage and blastocyst formation rates were used to assess their developmental competence. In both experiments, a portion of unvitrified MII oocytes were subjected to in vitro fertilization and culture as control groups. In Experiment 1, similar cleavage rates were obtained for both GVBD and MII oocytes (53.56 versus 58.01%, P > 0.05). However, significantly higher proportion of cleaved embryos from vitrified MII oocytes developed into blastocysts than those from vitrified GVBD oocytes (1.06 versus 8.37%, respectively, P < 0.01). In Experiment 2, vitrified MII oocytes matured in medium supplemented with LH were superior to vitrified MII oocytes matured in FSH supplementation not only in cleavage rates (61.13 versus 50.33%), but in blastocyst formation rates (11.79 versus 5.19%, P < 0.01) as well. Cleavage and blastocyst formation rates of parthenogenetically activated oocytes were similar to those that were fertilized. Nevertheless, the vitrifying/ warming process significantly compromised the oocytes' developmental capacity since the vitrified oocytes showed significant reduction in both cleavage and blastocyst rates compared to those of not vitrified controls in both experiments (P < 0.01). We showed that oocytes at different maturation stages respond to cryopreservation differently and MII stage oocytes have better resistance to cryopreservation than GVBD stage oocytes. The maturation protocols also influence oocyte's ability to survive cryopreservation. Poor developmental potential after vitrification seem to have resulted from the cryodamage to the oocyte itself. These results suggested the importance of maturation on the developmental competence of cryopreserved oocytes.     

Effects of cooling and warming rates during vitrification on fertilization of in vitro-matured bovine oocytes

The purpose of this study was to clarify the relationship of cooling rates (CR) and warming rates (WR) during vitrification with postwarming viability of in vitro-matured bovine oocytes. In Experiment 1, oocytes were vitrified in a solution containing 7.2 M ethylene glycol and 1.0 M sucrose by use of open-pulled glass capillaries with five different outer diameters and were warmed by placement of the capillaries into 0.25 M sucrose solution. The capillaries of 2000-, 1400-, 1000-, 630-, and 440-mm diameters provided CR of 2000, 3000, 5000, 8000, and 12,000 degrees C/min and WR of 5000, 8000, 17,000, 33,000, and 62,000 degrees C/min, respectively. In oocytes vitrified in capillaries of 1400-mm diameter (CR, 3000 degrees C/min; WR, 8000 degrees C/min), the morphological survival rate (86% of vitrified), penetration rate (79% of inseminated), and normal fertilization rate (69% of penetrated) were higher or tended to be higher than those in the other vitrification groups. In Experiment 2, oocytes cooled at 2000, 3000, or 12,000 degrees C/min were warmed at 8000 degrees C/min, and oocytes cooled at 3000 degrees C/min were warmed at 5000, 8000, or 33,000 degrees C/min. Among these CR-WR combinations, cooling of oocytes at 3000 degrees C/min regardless of the WR resulted in higher postwarming survival. These results indicate that survival of in vitro-matured bovine oocytes after vitrification and subsequent warming is improved by a slightly rapid cooling rate in open-pulled glass capillaries compared to that obtained in conventional straws.     

Vitrification of mouse oocytes results in aneuploid zygotes and malformed fetuses

Vitrification of mouse oocytes adversely affected the subsequent developmental potential of embryos and fetuses derived from the fertilization of such oocytes after thawing. Only 5% of oocytes vitrified formed viable fetuses on the 15th day of gestation as compared to 47% in the controls. The incidence of chromosomally aneuploid zygotes, derived from cryopreserved oocytes, was approximately threefold higher than the controls irrespective of whether the oocytes were cryopreserved by vitrification or DMSO slow-freezing. Malformed fetuses were obtained from oocytes that had been vitrified as well as those that had been exposed to vitrification solutions only, whereas no malformed fetuses were obtained in oocytes slow-frozen by DMSO or fresh controls--thus demonstrating that the exposure of oocytes to the vitrification chemicals was responsible for the fetal malformations. The data in this study suggest that the vitrification technique should be cautiously applied to human oocyte cryopreservation. Furthermore, the data also demonstrate that the exposure of female gametes to carcinogenic and/or teratogenic chemicals may result in malformed embryos when such oocytes are subsequently fertilized.     

Cryoprotectant-free cryopreservation of human spermatozoa by vitrification and freezing in vapor: effect on motility, DNA integrity, and fertilization ability

Human spermatozoa can be successfully cryopreserved avoiding the use of cryoprotectants through vitrification at very high cooling rates (up to 7.2 x 10(5) degrees C/min). This is achieved by directly plunging a copper cryoloop loaded with a sperm suspension into liquid nitrogen. After storage, vitrified spermatozoa are instantly thawed by melting in an agitated, warm medium. The goal of the present study was to compare the quality of spermatozoa cryopreserved using this rapid vitrification method with that of spermatozoa cooled relatively slowly by preexposure of the loaded cryoloop to liquid nitrogen vapor (-160 degrees C) with speed in the range 150-250 degrees C/min) before immersion into liquid nitrogen. Both cooling modes led to comparable results in terms of the motility, fertilization ability, and DNA integrity of the warmed spermatozoa. In both cases, instant thawing by melting in a warm medium was essential for successful cryopreservation. Our findings suggest that optimal regimes for the cryoprotectant-free cryopreservation of spermatozoa need not be restricted to very fast cooling before storage in liquid nitrogen, a wide range of cooling rates being acceptable. Herein, we discuss the implications of this finding in the light of the physics of extra- and intracellular vitrification.     

Parasite cryopreservation by vitrification

Parasitic protozoa and helminths and parasitic/vector insects each have distinct requirements for cryopreservation. Most parasitic protozoa respond to cryopreservation stresses similarly to other single cell suspensions, but few species are currently routinely cryopreserved by protocols specifically designed for vitrification. With slow equilibrium cooling, some protozoa osmotically dehydrated by solutes concentrated in the residual unfrozen fraction will survive by vitrifying. Several species of helminths, together with insect embryos cannot be cryopreserved by slow cooling protocols and have an absolute requirement for vitrification. Studies incorporating slow cooling and stepped cooling of both protozoa and helminths, particularly the intraerythrocytic stages of malaria and the schistosomula larvae of Schistosoma mansoni have aided in the design of vitrification protocols for parasites. For helminths, the most widely used cryopreservation protocol, originally successful for cryopreserving S. mansoni schistosomula, consists of the addition of ethanediol in two steps, followed by rapid cooling (approximately 5100 degrees C min(-1)) to -196 degrees C. This technique exploits the temperature-dependent differential in permeability of the cryoprotectant additive (CPA) to first permeate into the organism at 37 degrees C followed by a dehydration-mediated internal CPA increase in concentration resulting from incubation in a second higher CPA concentration at 0 degree C. Samples are rapidly warmed/diluted (approximately 14,000 degrees C min(-1)) to recover the organisms from liquid nitrogen storage. Variations on this technique have also been successful in cryopreserving the larvae and adult worms of filariae, muscle stage larvae of Trichinella spp., the infective stages of gastro-intestinal nematode parasites and insect embryos. Other protocols where the dehydration step precedes CPA addition have been used to cryopreserve entomogenous nematode larvae by vitrification. Techniques that utilize high concentrations of CPA cocktails and slower cooling, developed for the vitrification of mammalian embryos, have been applied to the cryopreservation of parasitic protozoa, but with limited success to date. Where cryopreservation by classical slow cooling methods is possible, vitrification has enhanced the levels of survival obtained. And vitrification has enabled the successful cryopreservation of those parasitic species not able to be cryopreserved by traditional methods. Since a limited number of parasitic organisms has been cryopreserved using vitrification protocols, there is considerable scope for further improvement in the cryopreservation techniques used for many parasitic species.     

Development of mouse embryos cryopreserved by vitrification

Eight-cell mouse embryos were cryopreserved by vitrification in a concentrated solution of dimethylsulphoxide, acetamide, propylene glycol and polyethylene glycol. This solution (designated VS1) does not crystallize when cooled to subzero temperatures but instead forms a glassy transparent solid. Embryos were exposed in three steps to a stock VS1 solution or a saline solution containing 90% of the cryoprotectants in the stock VS1 (90% VS1) and then the suspensions were vitrified by rapid cooling in liquid nitrogen. Of 568 embryos vitrified in 90% VS1, 80% developed in vitro and 98 normal fetuses or young (17% of the total) were produced after transfer to pseudopregnant recipients. By contrast, 22% of 153 embryos vitrified in the stock VS1 developed in vitro, but only one normal fetus was obtained after transfer. These results demonstrate that normal fetuses and young can be produced from embryos cryopreserved by the simple and rapid method of vitrification.     

Cryopreservation of cartilage cell and tissue for biobanking

Preservation of cell and tissue samples from endangered species is a part of biodiversity conservation strategy. Therefore, setting up proper cell and tissue cryopreservation methods is very important as these tissue samples and cells could be used to reintroduce the lost genes into the breeding pool by nuclear transfer. In this study, we investigated the effect of vitrification and slow freezing on cartilage cell and tissue viability for biobanking. Firstly, primary adult cartilage cells (ACCs) and fetal cartilage cells (FCC) were cryopreserved by vitrification and slow freezing. Cells were vitrified after a two-step equilibration in a solution composed of ethylene glycol (EG), Ficoll and sucrose. For slow freezing three different cooling rates (0.5, 1 and 2 °C/min) were tested in straws. Secondly, the tissues taken from articular cartilage were cryopreserved by vitrification and slow freezing (1 °C/min). The results revealed no significant difference between the viability ratios, proliferative activity and GAG synthesis of cartilage cells which were cryopreserved by using vitrification or slow freezing methods. Despite the significant decrease in the viability ratio of freeze–thawed cartilage tissues, cryopreservation did not prevent the establishment of primary cell cultures from cartilage tissues. The results revealed that the vitrification method could be recommended to cryopreserve cartilage tissue and cells from bovine to be used as alternative cell donor sources in nuclear transfer studies for biobanking as a part of biodiversity conservation strategy. Moreover, cartilage cell suspensions were successfully cryopreserved in straws by using a controlled-rate freezing machine in the present study.     

Applications of cryopreserved unfertilized mouse oocytes for in vitro fertilization

Since the first successful reports into oocyte freezing, many papers concerning the cryopreservation of mouse oocytes have been published. However, a simple and practical cryopreservation method for unfertilized C57BL/6 mouse oocytes, and an IVF system using these cryopreserved oocytes have yet to be established, in spite of the fact that C57BL/6 is the prevalent inbred strain and is used for large-scale knockout programs. In this study, unfertilized C57BL/6 mouse oocytes were cryopreserved via a simple vitrification method. After warming, IVF was performed using cryopreserved unfertilized oocytes and fresh sperm, cryopreserved unfertilized oocytes and cold-stored sperm, cryopreserved unfertilized oocytes and frozen sperm (C57BL/6 strain sperm), and cryopreserved unfertilized oocytes and frozen sperm derived from GEM strains (C57BL/6 background GEM strains). Nearly all of the cryopreserved oocytes were recovered, of which over 90% were morphologically normal. Those oocytes were then used for in vitro fertilization, resulting in 72–97% of oocytes developing into 2-cell embryos. A portion of the 2-cell embryos were transferred to recipients, resulting in live young being produced from 32–49% of the embryos. In summary, we established the simple and practical method of mouse oocyte vitrification with high survivability and developmental ability and the IVF using the vitrified-warmed oocytes with fresh, cold-stored or cryopreserved sperm with high fertility.