Factors affecting the survival of mouse embryos cryopreserved by vitrification

Development of vitrified–thawed bovine oocytes after in vitro fertilization and somatic cell nuclear transfer

Cryopreservation could be a useful technique for providing a steady source of oocytes for nuclear transfer and in vitro embryo production. The purpose of this study was to develop a method for cryopreservation of bovine oocytes while maintaining the developmental potential following subsequent in vitro fertilization (IVF) or somatic cell nuclear transfer (SCNT). Following vitrification-thawing, the surviving oocytes were (a) used for parthenogenetic activation, (b) examined for pronuclear formation after IVF, (c) examined for embryo development after IVF, and (d) used for SCNT employing fetal fibroblasts transfected with green fluorescent protein (GFP) gene. While most of the oocytes survived vitrification when the microdrop method was used (92.50%), the cleavage and blastocyst formation rates after parthenogenetic activation were lower (46.5% and 11.1%) than that in the non-vitrified control (86.6% and 13.5%). After IVF, the pronuclear formation (2PN) of fertilized embryos was lower in the vitrified group than in the control (21.7% and 59.9%). After SCNT, fusion rates were similar in control (58.33%) and vitrified-thawed oocytes (53.19%). However, the cleavage (73.1% and 46.3%) and blastocyst formation rates (22.2%, 7.4%; p<0.05) differed between control and vitrified-thawed oocytes. In vitrified-thawed or control oocytes, all embryos reconstructed using fetal fibroblasts transfected with GFP gene showed GFP expression. To evaluate the complete developmental potential, embryos derived from vitrified-thawed and fresh control oocytes were non-surgically transferred to 27 recipients (16 for control and 11 for vitrified-thawed). In the vitrified-thawed group, two pregnancies were detected at day 60, and one of them lasted until day 222. While in the fresh group, one pregnancy maintained to term. In conclusion, vitrified-thawed bovine oocytes could support development into the subsequent stages after IVF and SCNT. In addition, this study showed the possibility of the vitrified-thawed bovine oocytes in the production of transgenic cloned animals. In addition, further studies are required to increase the efficiency of oocyte vitrification for the practical uses and production of live offspring.

Cryopreservation of human embryos by vitrification or slow freezing: a systematic review and meta-analysis

OBJECTIVE

To examine the literature systematically in order to identify prospective comparative trials answering the following question: Is vitrification of human embryos associated with a higher postthawing survival rate as compared with slow freezing?

DESIGN

Systematic review and meta-analysis.

SETTING

University-based hospital.

PATIENT(S)

Not applicable.

INTERVENTION(S)

Vitrification versus slow freezing for cryopreservation of human embryos.

MAIN OUTCOME MEASURE(S)

Postthawing survival rate.

RESULT(S)

Four eligible studies were identified, three of which were randomized controlled trials. Overall, the current review summarizes information from 8,824 cryopreserved human cleavage stage embryos/blastocysts (vitrification: n = 7,482; slow freezing: n = 1,342). Survival rate of cleavage stage embryos was significantly higher after vitrification as compared with slow freezing (odds ratio 15.57, 95% confidence interval 3.68-65.82; random effects model). Postthawing survival rate of vitrified blastocysts was significantly higher compared with that observed with slow freezing (odds ratio 2.20, 95% confidence interval 1.53-3.16; fixed effects model).

CONCLUSION(S)

Vitrification appears to be associated with a significantly higher postthawing survival rate than slow freezing. Further prospective trials are necessary to confirm the above results and, in addition, allow the evaluation of the two cryopreservation methods in terms of pregnancy achievement.

Vitrification of in vitro cultured porcine two-to-four cell embryos

The objective of this experiment was to evaluate the effect of a 5-day period of in vitro culture of two-to-four cell porcine embryos up to the blastocyst stage on their ability to survive vitrification and warming. In order to increase the cooling rate, superfine open pulled straws and Vit-Master((R)) technology were used for vitrification. Two-to-four cell embryos were collected from weaned sows (n=11) on day 2 (D0=onset of estrus). Some embryos (N=63) were vitrified within 3h after collection, warmed and cultured for 120h (Group V2). Additionally, 81 two-to-four cell embryos were cultured for 96h in order to obtain blastocysts; these were then vitrified, warmed and cultured for 24h (Group VB; N=65). The remaining two-to-four cell embryos were used as controls and thus not vitrified (control embryos; N=70) but were cultured in vitro for 120h. The V2, VB and control embryos were evaluated for their developmental progression and morphology during culture. All embryos (V2, VB and controls) were fixed on the same day of development in order to assess the total number of blastomeres. The survival and blastocyst formation rates obtained from V2 embryos were very poor (9.6+/-0.7% and 3.2+/-0.5%, respectively). The survival and hatching rates of VB embryos (75.0+/-0.69% and 33.6+/-0.13%) were lower (p<0.001) than those obtained with control embryos (89.1+/-0.8% and 47.5+/-0.12%). Hatched VB embryos had a lower (p<0.01) total cell number than hatched control embryos (70.3+/-4.5 versus 90.6+/-3.2, respectively). There was no difference between expanded VB and control blastocysts. In conclusion, blastocysts derived from in vitro culture of two-to-four cell pig embryos could be successfully vitrified using SOPS straws and Vit-Master.

Cryopreservation and in vitro maturation of germinal vesicle stage oocytes of animals for application in assisted reproductive technology

Cryopreservation, in vitro maturation, fertilization and culture can be applied to various processes across a wide range of species, that is, for the breeding and reproduction of farm animals, preservation of genetic variants in laboratory animals, and the conservation of wild species. In particular, the storage of oocytes by cryopreservation and IVM following cryopreservation, might become effective alternative assisted reproduction treatments for infertile patients. For example, in a clinical context, these techniques might be important for patients who are at risk of losing their ovarian function because of extirpative therapy, chemotherapy or radiation. Thus, it is important for assisted reproductive technology to improve IVM and cryopreservation techniques. In the present review, we introduce our recent studies on vitrification and IVM of germinal vesicle stage oocytes in animals.

Effect of vitrification method on survivability, follicular growth and ovulation of preantral follicles in mice

AIM

This study was designed to compare the survival rates, follicular growth rates, and ovulation rates of vitrified preantral follicles (PF) from ovaries with those isolated from a vitrified ovarian cortical strip.

METHODS

Mouse ovaries were divided into three groups: those not treated by vitrification of the PF (control), those treated by vitrification of the PF isolated from the ovaries (group I), and those treated by vitrification of ovarian tissue followed by PF isolation (group II). The group I samples were exposed to equilibration solution (EG-20) for 5.0 min plus vitrification solution (EFS-40) for 0.5 min, while the group II samples were exposed to EG-20 for 10.0 min plus EFS-40 for 2.0 min, before vitrification. They were subsequently placed on an electron microscope grid, and submerged immediately in liquid nitrogen. After thawing, the survival rate and the growth rate of the follicles were evaluated every 2 days.

RESULTS

In the in vitro condition, the follicles grew and developed into antral follicles in groups I and II. The survival rate of the group I samples was higher than that of the group II samples during the in vitro culture (P<0.05). The growth rates of the follicles in group I were higher than those in group II after day 6 (P<0.05). The ovulation rate of the samples in group I was higher than that of group II (P<0.05).

CONCLUSION

These results demonstrated that direct PF vitrification appeared to be better than vitrification of the PF isolated from ovarian tissue.

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.

Effect of macromolecules in solutions for vitrification of mature bovine oocytes

This study was designed to evaluate vitrification procedures for in vitro matured bovine oocytes for efficient blastocyst production after warming, IVF and culture. A second goal was to replace serum as the macromolecular component of the vitrification solution, without compromising efficacy. The first experiment compared two containers, open pulled straws (OPS) versus cryoloops, and two vitrification protocols: short equilibration (H-TCM-199+10% EG+10% DMSO+20% FCS for 30s, followed by H-TCM-199+20% EG+20% DMSO+20% FCS+0.48M galactose for 20s) versus long equilibration (H-TCM-199+3% EG+20% FCS for 10min, followed by H-TCM-199+31% EG+20% FCS+1M galactose for 20s). Subsequent experiments used only cryoloops and the short equilibration protocol to evaluate the effect of replacing FCS with defined macromolecules (BSA, Ficoll, PVP, and PVA) in vitrification solutions. Cryoloops were superior to OPS for vitrification of oocytes as determined by blastocyst production (P<0.05). The short and long vitrification protocols gave similar results. The presence of macromolecules in vitrification solutions for bovine oocytes was necessary for acceptable post-warming developmental capacity; 20% FCS, 1% and 2% BSA, 6% and 18% Ficoll, 6% and 20% PVP, 1% PVA, and the combinations of 18% Ficoll+1% BSA, and 6% PVP+1% BSA provided similar protection during vitrification of oocytes; development ranged from 14.8% to 23.0% blastocysts/oocyte, which was not different (P>0.05) from non-vitrified controls (26.9-34.0% blastocysts/oocyte). Too much (6%) and too little (0.3%) BSA, and 0.3% PVA for vitrification resulted in lower blastocyst production (P<0.05) relative to unvitrified oocytes.

Gene expression profiles and in vitro development following vitrification of pronuclear and 8-cell stage mouse embryos

The analysis of differences in gene expression, responding to cryopreservation may explain some of the observed differences in further development of the preimplantation stage embryos. The aim of this study was to create a link, for the first time, between morphological/developmental observations and gene activity changes following cryopreservation of embryos. Efficiency of two vitrification methods, solid surface and in-straw vitrifications for pronuclear-stage mouse zygotes and 8-cell stage mouse embryos was compared based on morphological survival, blastocyst formation, and changes in embryonic gene expression. Both stages of embryos were vitrified by SSV using 35% ethylene glycol (EG) for vitrification solution (VS) and in-straw vitrification using 40% EG for VS. No significant differences were found between immediate survival rates of embryos vitrified by SSV and in-straw vitrification in both stages. Blastocyst rates were significantly higher with SSV and not significantly different from that of control. These results showed that SSV was more efficient than in-straw vitrification. Treatment with cytochalasin-b did not improve cryosurvival during SSV. The quantification of selected gene transcripts from single embryo (6 embryos/treatment group) were carried out by quantitative real-time RT-PCR. It was performed by adding 1/8 of each embryo cDNA to the PCR mix containing the specific primers to amplify housekeeping gene (beta-actin), heat shock protein gene (Hsp70), genes related to oxidative stress (MnSOD and CuSOD), cold stress (CirpB, Rbm3), and cell-cycle arrest (Trp53). We found upregulation of all six stress-related genes at 3 hr post-warming in pronuclear stage embryos. Expression of these genes showed much higher level (2-33-fold) in in-straw vitrification than in in vitro control embryos. In SSV-treated embryos we could detect only slight changes (0.3-2-fold). At 10 hr post-warming, all genes were downregulated in embryos vitrified by in-straw method. In SSV-treated group expression of Hsp70 showed slight increase and Trp53 showed decrease. In contrast to pronuclear stage, there was no clear pattern of gene expression changes after vitrification in 8-cell stage embryos. Several genes were upregulated both at 3 and 10 hr post-warming. Moreover, we found upregulation of beta-actin gene which we expected to use as a reference gene in in-straw treated embryos in both 3 and 10 hr post-warming, while in pronuclear stage embryos and in SSV treatment there was no effect on beta-actin expression level. There was no difference in gene expression between blastocysts developed from fresh or vitrified embryos. In conclusion, the real-time RT-PCR method from single embryo opened new opportunities for the understranding of molecular events following cryopreservation. The upregulation of stress-related genes at 3 hr post-warming in pronuclear stage embryos might have been an early indicator of reduced viability following in-straw vitrification in good correlation with the developmental data to blastocyst stage.

Cryopreservation of Mexican fruit flies by vitrification: Stage selection and avoidance of thermal stress

This report presents details of a vitrification methodology for the cryopreservation of embryos of the Mexican fruit fly, Anastrepha ludens. The overall summary of the data indicates that selecting the correct developmental stage for cryopreservation is the most important criterion. The key aspect in selection of the correct stage is to balance depletion of the gut yolk content against development of the embryonic cuticle. Embryogenesis was divided into four stages between 90 and 120 h after incubation at 21.7 degrees C. The classification was based on the intestinal yolk content and the initial development of mandibular-maxillary complex. Stages having low mid-gut yolk content and the appearance of mouth hooks were found to be the most suitable for cryopreservation. Embryos developing at 30 degrees C had premature cuticle formation relative to gut development and significantly lower hatching after cryopreservation. Vitrification of embryos by direct quenching in liquid nitrogen was less effective than quenching after annealing the samples in liquid nitrogen vapor. Quenched samples of vitrification solutions containing 1,2-ethanediol as the major component exhibited fractures. Fracturing occurred less frequently when the solutions were annealed and when containing polyethylene glycol. Hatching of vitrified embryos stored in liquid nitrogen for over 12 months was not statistically different from those held for only 15 min. Our protocol yielded normalized hatching rates that ranged as high as 61%. Selecting the exact stage for cryopreservation from a population of embryos obtained by collection from ovipositing females during a span of just 30 min resulted in nearly 80% of the embryos hatching into larvae.

Vitrification of Boer Goat Morulae and Early Blastocysts by Straw and Open-Pulled Straw Method

The aim of this study was to investigate the effects of different vitrification solutions [EFS30 or EFS40 contains 30% (v/v) ethylene glycol (EG), 40% (v/v) EG; EDFS30 or EDFS40 contains 15% (v/v) EG and 15% (v/v) dimethyl sulfoxide (DMSO), 20% (v/v) EG and 20% (v/v) DMSO], equilibrium time during vitrification (0.5-2.5 min) and vitrification protocols [one-step straw, two-step straw and open-pulled straw (OPS)] on in vivo development of vitrified Boer goat morulae and blastocysts after embryo transfer. In the one-step straw method, the lambing rates of vitrified embryos in EFS30 (37.5%), EFS40 (40.5%) or EDFS30 (38.2%) group were similar to that of fresh embryos (57.5%) and conventional freezing method (46.7%) when the equilibrium time was 2 min. In the two-step straw method, the highest lambing rate was obtained when embryos were pretreated with 10% EG for 5 min and then exposed to EFS40 for 2 min (51.4%), showing similar lambing rates compared with fresh embryos (56.1%) or the embryos cryopreserved by conventional freezing method (45.2%). In the OPS method, the lambing rate in EFS40, EDFS30 or EDFS40 groups were similar to that (57.1%) of fresh embryos, or to that (46.0%) of embryos cryopreserved by conventional freezing method. The highest lambing rate (51.4%) of the group of OPS was obtained when the embryos were vitrified with EDFS30. In conclusion, either the two-step straw method in which embryos were pretreated in 10% EG for 5 min and then exposed to EFS40 for 2 min, or the OPS method in which embryos were pretreated in 10% EG + 10% DMSO for 30 s and then exposed to EDFS30 for 25 s was a simple and efficient method for the vitrification of Boer goat morulae and blastocysts.

Effects of isolation method and pre-treatment with ethylene glycol or raffinose before vitrification on in vitro viability of mouse preantral follicles

Effects of isolation and vitrification protocols on follicular survival after warming were examined. Mouse preantral follicles enzymatically or mechanically isolated from ovaries of 12-day-old mice were exposed either to 2 M ethylene glycol (EG) for 2 or 5 min, or to ascending concentrations (0.15 then 0.3 M) of raffinose for 2 or 5 min each (2-2 and 5-5 min). They were then exposed to a vitrification solution (VS) composed of 6 M EG and 0.3 M raffinose for 0.5, 1, or 2 min before vitrification. Mechanically isolated follicles showed higher survival than enzymatically isolated follicles, regardless of periods of exposure to EG or raffinose and subsequent exposure to VS. After 10 days of culture, follicular growth and maturational ability of oocytes derived from vitrified follicles exposed to 2 M EG for 5 min and to VS for 1 min were higher than those from follicles exposed to raffinose solutions for 2-2 min and to VS for 1 min. Histological evaluation revealed that exposure of preantral follicles to raffinose solutions caused cytoplasmic vacuolation in granulosa cells which could be due to cellular shrinkage during dehydration; whereas, exposure to 2 M EG induced morphological alterations in follicles only to a lesser extent.

Cryopreservation of mammalian embryos

The cryopreservation of mammalian embryos has expanded over the past 20 yr by encompassing a range of sophisticated methods to deal with different developmental stages and different sensitivities to low-temperature exposure. We have described a method for slow, controlled-rate freezing of early stage embryos based on exposure to 1,2-propanediol and sucrose, while the method for late-stage (blastocyst) embryos employs mixtures of glycerol and sucrose. Both methods have been used for animal and human embryos. A third rapid cooling or "vitrification" technique is described, which depends on brief but controlled exposure of multicellular embryos to mixtures of glycerol and 1,2-propanediol at high concentrations. This technique is used for successful animal embryo cryopreservation but is not yet widely applied in the clinic.

A new selection criterion to assess good quality ovine blastocysts after vitrification and to predict their transfer into recipients

The feasibility to accurately select viable embryos would be valuable for improving pregnancy rates and avoiding futile transfer attempts. The aim of our study was to assess if in vitro-produced embryo quality could be determined by the timing of blastocoelic cavity re-expansion after vitrification, warming, and in vitro culture using sheep as a model. Blastocysts were produced in vitro, vitrified/warmed, and cultured in TCM-199 plus 10% FCS for 72 hr. Embryos were divided into two groups: re-expanded within 8 hr (A) and from 8 to 16 hr (B) of IVC after warming. Fast re-expanded blastocysts showed higher in vitro hatching rates and total cell number calculated on the hatched blastocysts compared with slow re-expanded ones (P < 0.01). Peroxide status evaluation (P < 0.01) and TUNEL test (P < 0.05) revealed a higher number of positive cells in group B compared with group A. The quantitative analysis of protein synthesis revealed a higher synthesis in fast compared with slow re-expanded embryos (P < 0.05). Quantitative RT-PCR showed that 90-kDa Heat Shock Protein beta was more expressed in group A than in group B (P < 0.05), while the quantity of P34(cdc2), Cyclin b, Aquaporin 3, Na/K ATPase, and Actin did not differ between the two groups. Pregnancy rates after transfer to synchronized recipients were higher in fast compared to slow re-expanded blastocysts (P < 0.05). Our results evidenced that timing of blastocoelic cavity re-expansion after vitrification/warming and in vitro culture can be considered as a reliable index of in vitro produced embryo quality and developmental potential.

Highly efficient vitrification for cryopreservation of human oocytes and embryos: The Cryotop method

Vitrification is frequently referred to as a novel technology of cryopreservation in embryology, although some young embryologists were born after its first successful application. Unfortunately, in spite of the accumulated evidence regarding its enormous potential value, most domestic animal and human laboratories use exclusively the traditional slow-rate freezing with its compromised efficiency and inconsistency. The purpose of this paper is to clarify terms and conditions, to summarize arguments supporting or disapproving the use of vitrification, and to outline its role among assisted reproductive technologies. To provide evidence for the potential significance of vitrification, achievements with the Cryotop technology, an advanced version of the "minimal volume approaches" is analyzed. This technology alone has resulted in more healthy babies after cryopreservation of blastocysts than any other vitrification technique, and more successful human oocyte vitrification resulting in normal births than any other cryopreservation method. The value of this method is also demonstrated by achievements in the field of domestic animal embryology. A modification of the technique using a hermetically sealed container for storage may help to eliminate potential dangers of disease transmission and open the way for widespread application for cryopreservation at all phases of oocyte and preimplantation embryo development in mammals.

Ultrastructure of preimplantation genetic diagnosis-derived human blastocysts grown in a coculture system after vitrification

OBJECTIVE

To evaluate ultrastructural features of preimplantation genetic diagnosis (PGD) blastocysts before and after vitrification.

DESIGN

Descriptive study of both vitrified and fresh hatching blastocysts.

SETTING

PGD program at the Instituto Universitario, Instituto Valenciano de Infertilidad.

PATIENT(S)

Patients undergoing PGD donated their abnormal embryos for research (n = 26).

INTERVENTION(S)

Biopsied embryos were cultured in the presence of human endometrial cells until day 6. Sixteen blastocysts were vitrified. A total of 11 high-scored hatching blastocysts, 6 warmed and 5 fresh, were fixed for ultrastructure.

MAIN OUTCOME MEASURE(S)

The cytoskeleton structure, type of intercellular junctions, and basic intracellular organelles in trophoectoderm cells and the inner cell mass were analyzed.

RESULT(S)

Ten of 16 blastocysts (62%) survived the warming process. Six of these showed no signs of cell degeneration and light microscopy revealed similar ultrastructural characteristics to those of controls. However, in trophoectoderm cells from both fresh and cryopreserved blastocysts, a reduced number of tight junctions and the presence of degradation bodies were detected.

CONCLUSION(S)

The particular ultrastructural features observed in PGD-derived blastocysts could be related to embryo manipulation and culture conditions. Vitrification does not seem to alter blastocysts, as those that survive hatching do not display detectable cellular alterations when observed through electron microscopy.

Principe de la vitrification : cinétiques comparatives

Over the last decade, several methods have been designed to improve the survival rate of vitrificated embryos. Although some teams have succeeded, the main remaining drawback of these methods is that they do not provide a leak proof environment for cryopreserved biological samples. To respond to that demand in respect with the European reglementation, the Cryo Bio System company (CBS) designed the HSV High Security Vitrification Kit (HSV). This system is composed of three distinct parts, a High Security thermal-autogenic sealed clear straw, a capillary with its extremity in form of a gutter, and an introducer that can be mounted on the manipulation rod before introduction into the straw. In this study, we confirmed that the CBS vitrification kit is a suitable method for vitrification in association with a small amount of cryoprotector enriched viscous media such as 25 microM Ficool 400, 750 mM Sucrose, 1% Bovine albumin, 20% Dimethyl Sulfoxide and 20% Ethylene glycol in a Phosphate buffered saline solution. We also evaluated the speed of the temperature decrease during vitrification in comparison with four other commercially available non-aseptic methods and showed the protective role of the CBS system during transfer. These physical data have now been confirmed biologically by P. Vanderzwalmen who obtained easily reproductible good results with human embryo using our method. Today, the HSV represents the unique aseptic alternative device (EC and FDA approved) for embryos, oocytes, and biological samples vitrification.

Improved vitrification method allowing direct transfer of goat embryos

The aim of this study was to design a vitrification method suited to field embryo transfer experiments in goat. In a first experiment, a standard vitrification protocol, previously designed for sheep embryos was compared to slow freezing of goat embryos. No significant difference was observed on kidding rate (48% versus 69%, respectively), nor on embryo survival rate (35% versus 45%). Second experiment: all embryos were vitrified. After warming, embryos were either transferred directly (direct transfer), or after in vitro dilution of the cryoprotectants (conventional transfer). The kidding rate was not affected by the transfer method (38% versus 23%, respectively). However, embryo survival rate tended to be higher after direct transfer (26% versus 14%). Third experiment: OPS vitrification was compared to standard vitrification. The kidding rate was not affected (22% versus 39%, respectively), but the embryo survival rate was lower after OPS (14% versus 28%). Fourth experiment: 0.4M sucrose was added with cryoprotectants in vitrification. The kidding rate after direct transfer was significantly enhanced after addition of sucrose (56% versus 27%, respectively), whereas embryo survival rate was not significantly affected (32% versus 18%). Fifth experiment: vitrification with sucrose supplementation was compared to slow freezing. No significant difference was observed after direct transfer on kidding rate (52% versus 31%, respectively), but embryo survival rate tended to be higher after vitrification (34% versus 21%). In conclusion, our results indicate that addition of 0.4M sucrose in association with direct transfer improves significantly the viability of goat vitrified embryos.

Plant vitrification solution 2 lowers water content and alters freezing behavior in shoot tips during cryoprotection

Plant shoot tips do not survive exposure to liquid nitrogen temperatures without cryoprotective treatments. Some cryoprotectant solutions, such as plant vitrification solution 2 (PVS2), dehydrate cells and decrease lethal ice formation, but the extent of dehydration and the effect on water freezing properties are not known. We examined the effect of a PVS2 cryoprotection protocol on the water content and phase behavior of mint and garlic shoot tips using differential scanning calorimetry. The temperature and enthalpy of water melting transitions in unprotected and recovering shoot tips were comparable to dilute aqueous solutions. Exposure to PVS2 changed the behavior of water in shoot tips: enthalpy of melting transitions decreased to about 40 J g H2O(-1) (compared to 333 J g H2O(-1) for pure H2O), amount of unfrozen water increased to approximately 0.7 g H2O g dry mass(-1) (compared to approximately 0.4 g H2Og dry mass(-1) for unprotected shoot tips), and a glass transition (T(g)) at -115 degrees C was apparent. Evaporative drying at room temperature was slower in PVS2-treated shoot tips compared to shoot tips receiving no cryoprotection treatments. We quantified the extent that ethylene glycol and dimethyl sulfoxide components permeate into shoot tips and replace some of the water. Since T(g) in PVS2-treated shoot tips occurs at -115 degrees C, mechanisms other than glass formation prevent freezing at temperatures between 0 and -115 degrees C. Protection is likely a result of controlled dehydration or altered thermal properties of intracellular water. A comparison of thermodynamic measurements for cryoprotection solutions in diverse plant systems will identify efficacy among cryopreservation protocols.

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.

In vitro and in vivo viability of vitrified and non-vitrified embryos derived from eCG and FSH treatment in rabbit does

This study aimed to evaluate the in vitro and in vivo viability of vitrified and non-vitrified embryos derived from eCG and FSH treatments in rabbit does. Ninety-six nulliparous does were randomly subjected to consecutive superovulation treatments with eCG (20 IU/kg body weight intramuscularly (i.m.), eCG group), FSH (3 x 0.6 mg/doe at 24 h intervals i.m., FSH group), or without superovulation treatment (control group). Does were artificially inseminated 3 days later and ovulation was induced immediately by hCG (75 IU/doe intravenous). Seven experimental groups were differentiated: first FSH and eCG treatment, second FSH and eCG treatment, eCG-interchanged group (does with previous FSH treatment), FSH-interchanged group (does with previous eCG treatments) and control group. Embryos were collected in vivo by laparoscopy 76-80 h post-insemination in the first and second recovery cycles and post mortem in the third recovery cycles. The ovulation rate was significantly higher in does treated with the first-FSH than in those treated with eCG or in control does (25.2+/-2.0 versus 19.2+/-1.4 to 11.0+/-1.5, and 12.2+/-1.2, first-FSH, first-eCG to second-eCG and control groups, respectively, P < 0.05). Significant differences were observed in the total recovery influenced by ovulation rate in each group (20.3+/-2.2 to 9.4+/-1.2, first-FSH to control groups). Embryo donor rate (donor with at least one normal embryo) was similar among groups with an overall of 75.1%. The number of normal embryos recovered per doe with at least one normal embryo increased significantly in relation to ovulation rate (17.7+/-2.2 to 8.41+/-3, first-FSH and control groups). The vitrification of embryos negatively affected their in vitro development to hatched blastocyst in all groups (88.1% versus 48%, P > 0.05). However, after embryo transfer, this negative effect was only observed in superovulated vitrified embryos (16.8 and 12.8% versus 39.4% total born rate from eCG, FSH and control vitrified groups, P < 0.05). Results indicated that the primary treatments with eCG or FSH increased the number of normal embryos recovered per donor doe, but these embryos are more sensitive to vitrification protocols.

Aseptic vitrification of human germinal vesicle oocytes using dimethyl sulfoxide as a cryoprotectant

OBJECTIVE

To evaluate the viability of vitrified human germinal vesicle (GV)-oocytes to mature to metaphase II (MII) stage after "rapid" cooling directly in liquid nitrogen in comparison with "slow" cooling in a closed 0.5-mL straw (aseptic system), with or without dimethyl sulfoxide (DMSO) in vitrification solution. The possibility of avoiding parthenogenesis of the oocytes after vitrification using DMSO was investigated.

DESIGN

In vitro maturation after vitrification.

SETTING

Assisted reproduction centers.

PATIENT(S)

Patients undergoing standard superovulation treatment and having GV-oocytes after follicular puncture.

INTERVENTION(S)

The GV-oocytes were vitrified with long/short exposure to DMSO using slow or rapid cooling, then warmed and matured in vitro.

MAIN OUTCOME MEASURE(S)

Maturation after warming.

RESULT(S)

Oocyte development up to MII stage after vitrification with DMSO was 71% in the group with "rapid" cooling, and in groups with "slow" cooling, 68% and 72% for long and short exposure to DMSO, respectively. The maturation rate of GV-oocytes after slow cooling without DMSO was 51%. In the vitrification with long-term contact of oocytes with DMSO group, a high rate of parthenogenesis was observed. When vitrification with short-term contact of oocytes with DMSO at room temperature was used, no parthenogenesis was observed.

CONCLUSION(S)

Cryopreservation of human GV-oocytes in open-pulled straws OPS) using an aseptic slow cooling method gives high maturation rates but only in combination with DMSO. To avoid spontaneous parthenogenesis, the exposure to DMSO must occur for a reduced time and at room temperature.

Are programmable freezers still needed in the embryo laboratory? Review on vitrification

The predictable answer to the provocative question of whether programmable freezers are still needed in the embryo laboratory is an even more provocative 'no'. However, such a radical statement needs strong support. Based on the extensive literature of the past 5 years, the authors collected arguments either supporting or contradicting their opinion. After an overview of the causes of cryoinjuries and strategies to eliminate them, the evolution of vitrification methods is discussed. Special attention is paid to the biosafety issues. The authors did not find any circumstance in oocyte or embryo cryopreservation where slow freezing offers considerable advantages compared with vitrification. In contrast, the overwhelming majority of published data prove that the latest vitrification methods are more efficient and reliable than any version of slow freezing. Application of the proper vitrification methods increases the efficiency of long-term storage of stem cells and opens new perspectives in cryopreservation of oocytes, both for IVF and somatic cell nuclear transfer. However, lack of support from regulatory authorities, and conservative approachs regarding novel techniques can slow down the implementation of vitrification. The opinion of the authors is that vitrification is the future of cryopreservation. The public have the final say in whether they want and allow this future to arrive.

The effect of equilibration time on survival and development rates of mouse pronuclear-stage embryos vitrified in solid surface (SSV) and convential straws: In vitro and In vivo evaluations

The objective of this study was to improve the efficiency of cryopreservation of pronuclear-stage (PN) mouse embryos. A novel vitrification technique (solid surface vitrification, SSV) was compared with a convential one in straws both for cryosurvival and obtaining progeny from cryopreserved PN mouse embryos. In the SSV method, 15-20 PN embryos were exposed to vitrification solutions for approximately 20 sec after equilibration, and then they were dropped in 2 microl drops onto a pre-cooled (-150 to -180 degrees C) metal surface. In the straws method, groups of 5-10 PN embryos were loaded in a single straw after equilibration. In experiment I, it was compared the effect of the vitrification solutions alone, without vitrification. No reduction was detected in survival, cleavage and blastocysts rates and the lowest development rate was obtained from hatched blastocyst for 20 min equilibration (24.5%). In experiment II, SSV method resulted in significantly higher survival and cleavage rates than that of in-straw vitrified 15-20 min group (87% vs. 60%, 83% vs. 67%, respectively; P < 0.05). There were no statistical differences among any of the blastocyts groups. However, there was a statistical difference in hatched blastocysts between 15 to 5, 10, and 20 min (P < 0.05). In experiment III, it was found no major effect among equilibration time periods in toxicity groups according to the mean cell number of blastocysts developed from PN embryos. But, there was a significant differences between 15 min SSV and 10 min in straw vitrified according to the mean cell number of blastocysts developed from PN embryos following vitrification (P < 0.05). The good results were obtained from 15 min equilibration group for SSV and 10 min equilibration group for straw vitrification. In the last experiment, embryo transfer after vitrification and toxicity was investigated. There were significant differences between SSV and straw just on the rate of pups born (30% and 20.5% respectively; P < 0.05). In conclusion, vitrification of PN mouse embryos by SSV can result in high rates of in vitro development to expanded and hatched blastocyst stage and in vivo development to live pups.

The effects of Vitamin A administration on the development of vitrified-warmed mouse blastocyst

The purpose of this study was to evaluate the development of vitrified-warmed mouse blastocysts following a period of Vitamin A administration. Four to six weeks old BALB/c mice were given an intraperitoneal injection of either 0.1 ml paraffin oil alone (control, Con) or paraffin oil containing 250IU of Vitamin A (experiment, Exp). Ten days later the mice were given second paraffin or paraffin Vitamin A injection and an injection of 10IU equine chorionic gonadotropin (eCG) followed 48 h later by 10IU human chorionic gonadotropin (hCG). Blastocysts were collected from both groups and randomly divided into non-vitrified (Con 1, Exp 1) and vitrified (Con 2, Exp 2) subgroups. Embryos in the vitrified group were exposed sequentially to two solutions (10% ethylene glycol, 10% DMSO in holding medium (HM: DMEMF(12)+10% FBS) and 20% ethylene glycol, 20% DMSO in HM) before plunging into liquid nitrogen. After warming at 37 degrees C, cryoprotectants were diluted serially with 0.25 and 0.15M sucrose solution in HM. The vitrified-warmed and the fresh embryos of the control and the experiment groups were cultured in DMEMF(12) with 10% FBS for 72 h. Although, on the first day of culture, the rate of development to the hatched blastocyst was nearly identical between the two vitrified groups (15.8% versus 13%) but after 48 h, the rate of plated embryos was statistically higher in the vitrified Vitamin A than the vitrified control group (63.1% versus 19.6%, P<0.001). After 48 h, in the non-vitrified groups, the rate of the plated embryos was also significantly higher in the Vitamin A than the control group (70.5% versus 49.3%, P<0.01). These data provided evidence that systemic administration of Vitamin A may enhance the potential development of blastocysts in culture and is capable to reduce the adverse effects of vitrification at least during the first 2 days of cultivation.

Vitrification of mouse pronuclear embryos after polar body biopsy without direct contact with liquid nitrogen

OBJECTIVE

To evaluate the viability of vitrified mouse pronuclear embryos after polar body biopsy by cooling directly in liquid nitrogen in comparison with cooling in closed 0.5 mL straw (aseptic system).

DESIGN

In vitro culture after vitrification.

SETTING

Department of Gynecological Endocrinology and Reproductive Medicine, University of Bonn, Germany.

PATIENT(S)

Superovulated mice.

INTERVENTION(S)

Biopsied embryos were vitrified, warmed, and cultured in vitro.

MAIN OUTCOME MEASURE(S)

Development after warming.

RESULT(S)

Development rates up to expanded blastocyst stage after in vitro culture were 25% in group with "direct" vitrification and 23% in group with "straw in straw" vitrification.

CONCLUSION(S)

Cryopreservation of biopsied mouse pronuclear embryos in open-pulled straws, which are placed inside a hermetically closed container, guarantees a complete isolation of embryos from liquid nitrogen and avoids potential contamination by pathogenic microorganisms. The combination of plunging this container into liquid nitrogen and rapid warming makes this process as efficient as conventional vitrification.

Improved preservation of human red blood cells by lyophilization

The lyophilization of human red blood cells has important implications for blood transfusion in clinical medicine. In this study, sugars, human serum albumin, polyvinylpyrrolidone, and dimethyl sulfoxide were used as protective reagents for the lyophilization of red blood cells. Freezing temperature, shelf temperature, and the rehydration conditions were optimized. The results showed that extracellular disaccharides, especially trehalose, did not increase the recovery of hemoglobin. However, when the concentration of human serum albumin was higher than 25%, it had a considerable protective effect on the recovery of lyophilized red blood cells; the cellular hemoglobin recovery was over 70%, which was significantly higher than that in the group without human serum albumin (P<0.01). As the concentration of polyvinylpyrrolidone was increased, the extent of vitrification also increased. But when the concentration of polyvinylpyrrolidone was over 40%, the resulting concentration of free hemoglobin was over 1g/L, which was significantly higher than that with 40% (P<0.01). When lyophilization was carried out after freezing at different temperatures, the recovery of cells and hemoglobin was 70-80% and there were no significant differences among the five groups. When the shelf temperature was higher than -30 degrees C, the samples were partly collapsed, but when the shelf temperature was lower than -30 degrees C, the recovery of cells in the -40 and -45 degrees C groups was significantly higher than in the -30 and -35 degrees C groups (P<0.05). The recovery of cells and hemoglobin after lyophilization and rehydration in solutions containing low concentrations of polymers was over 80%, which is significantly higher than the other groups (P<0.01). In addition, when the temperature was higher than 25 degrees C, the concentration of free hemoglobin was significantly lower than it was at 4 degrees C (P<0.01). In conclusion, our study showed the lyophilization of red blood cells is feasible. Disaccharides have no protective effect on lyophilized cells when they are only extracellular and extensive vitrification may be not beneficial. Although the recovery of cells after lyophilization and rehydration by our method was over 70%, the ultrastructure of the cells may be compromised and some hemolysis does still exist. Further research is required.

Osmotic tolerance of in vitro produced porcine blastocysts assessed by their morphological integrity and cellular actin filament organization

This experiment investigated the osmotic tolerance limits of the morphology and the cellular actin filament organization of porcine blastocysts. In vitro produced Day 6 blastocysts were subjected to osmotic treatments with sucrose solutions of different osmolalities (75, 150, 210, 600, 1200, and 2400 mOsm) and one isotonic solution (NCSU-23, 285 mOsm). Blastocysts were then either fixed immediately, or cultured for 18 h and subsequently fixed with formalin. The morphology of the treated blastocysts was examined under a stereomicroscope and the integrity of the cellular actin filaments of the blastocysts was examined by confocal microscopy after staining with Alexa Fluor 488 phalloidin. The results indicated that there was a significant relationship between the osmotic levels and the probability of blastocysts exhibiting disrupted cellular actin filaments. In addition, blastocysts also collapsed in proportion to the levels of osmotic treatments. The osmotic tolerance limits which would maintain 70% of the blastocysts with their original morphology immediately after the treatment were 90 and 170%, respectively, of isotonicity. After 18 h of culture, the osmotic tolerance limits were 61 and 163%, respectively, of isotonicity. Similarly, the osmotic conditions relative to isotonicity which would maintain the integrity of cellular actin filaments in 70% of treated blastocysts had to be within the range of 87 and 147% immediately after the treatment and 87 and 169% after 18 h of culture. Collectively, these data indicate that in vitro produced porcine blastocysts are very sensitive to osmotic stress. This information can be used to optimize cryopreservation procedures for porcine embryos.

In vitro comparisons of two cryopreservation techniques for equine embryos: Slow-cooling and open pulled straw (OPS) vitrification

Vitrification using open pulled straw (OPS) has provided encouraging results with embryos from other species. The aim of this study was to compare the survival of 6.5- and 6.75-day-old equine embryos after OPS vitrification and slow-cooling. Eighteen embryos were frozen using a slow-cooling method. Embryos were placed in modified PBS with increasing glycerol concentration (2.5%, 5%, 7.5% and 10% (v/v) 5 min each). Embryos were loaded into 0.25 ml straws then placed in a programmable freezer and subsequently plunged into liquid nitrogen. After thawing, cryoprotectant was removed by five steps with decreasing glycerol and sucrose concentrations. Twenty embryos were vitrified using the OPS method. Embryos were exposed to 7.5% dimethyl-sulfoxide (DMSO)+7.5% ethylene glycol (EG) for 3 min and in 18% DMSO+18% EG+0.4M sucrose for 1 min, loaded in OPS and plunged into liquid nitrogen. After warming, embryos were placed in decreasing sucrose concentrations. All embryos were cultured in synthetic oviduct fluid (SOF) medium for 3h and evaluated using 4',6-diamidino-2-phenylindole (DAPI) staining. The percentage of cells entering in S-phase (%SC) was evaluated by incorporation of BrdU. No significant differences were observed for mean diameter, morphological grade and percentage of degenerate embryos after 3h of culture for slow-cooling and OPS methods. The percentage of dead cells per embryo was similar for the two procedures (42+/-6 versus 46+/-9). The percentage of cells entering in S-phase did not differ significantly between the two procedures (27+/-5 versus 26+/-6). OPS vitrification may be as efficient as slow-cooling for the cryopreservation of equine embryos. However, these results should be confirmed by the transfer of OPS vitrified embryos to recipient mares.

Bovine oocytes vitrified by the open pulled straw method and used for somatic cell cloning supported development to term

The objective of the present study was to determine if oocytes vitrified by the open pulled straw (OPS) method could subsequently be used to produce somatic cell cloned cattle. Post-thaw survival rates were 77.0, 79.1, 97.2 and 97.5% for oocytes vitrified with EDFS30 (15% ethylene glycol, 15% dimethyl sulfoxide, ficoll and sucrose), EDFS40 (20% ethylene glycol, 20% dimethyl sulfoxide, ficoll and sucrose), EDFSF30 (15% ethylene glycol, 15% dimethyl sulfoxide, ficoll, sucrose and FBS) and EDFSF40 (20% ethylene glycol, 20% dimethyl sulfoxide, ficoll, sucrose and FBS), respectively. The parthenogenetic blastocyst rates of the vitrified-thawed oocytes activated with 5 microM of the calcium ionophore A23187 for 5 min and 2 microM of 6-dimethylaminopurin (6-DMAP) for 4h ranged from 10.3 to 23.0%, with the highest group not significantly differing from that of the controls (33.2%). In total, 722 vitrified-thawed oocytes were used as recipients for nuclear transfer, of which 343 fused (47.6%). Fifty-six (16.3%) of the reconstructed embryos reached the blastocyst stage after 7d of in vitro culture. Twenty-four blastocysts derived from vitrified-thawed oocytes were transferred to six Luxi yellow cattle recipients. Two recipients (33%) were diagnosed pregnant; one aborted 97 d after transfer, whereas the other delivered a cloned calf after 263 d. As a control, 28 synchronous Luxi yellow cattle recipients each received a single blastocyst produced using a fresh oocyte as a nuclear recipient; 10 recipients were diagnosed pregnant, of which 6 (21.4% of the original 28) delivered cloned calves. In conclusion, bovine oocytes vitrified by the OPS method and subsequently thawed supported development (to term) of somatic cell cloned embryos.

Cryomacroscopy of vitrification, Part II: Experimental observations and analysis of fracture formation in vitrified VS55 and DP6

A new imaging device, termed a "cryomacroscope", was used to observe macrofractures in the cryoprotectant cocktails DP6 and VS55. Details of the design and construction of the cryomacroscope were presented in Part I of this report, which focused on describing the apparatus and observations of crystallization. Part I and the current paper (Part II) describe events that occur as 1 mℓ of cryoprotectant contained in a glass vial is cooled from room temperature down to cryogenic temperatures (∼ -135°C). The presence of cracking, as well as patterns in their position and orientation, are found to be dependent on the cooling rate and on the specific cryoprotectant cocktail. Cracks, if present, disappear upon rewarming, although they appear to be sites for later preferential crystallization. Computations which predict temperatures and mechanical stresses are used to explain observations of cracking. In conjunction with these reports, additional photos of cryomacroscopy of vitrification, crystallization, and fracture formation are available at http://www.me.cmu.edu/faculty1/rabin/CryomacroscopyImages01.htm.

An update on Reproductive Technologies with Potential Short-Term Application in Pig Production

Over the past decade, there has been an increase in the development and/or in the improvement of emerging reproductive technologies in pigs. Among emerging reproductive technologies with potential short-term application in pig production are: artificial insemination with low number of spermatozoa, cryopreservation of spermatozoa and embryos, sperm sexing, and non-surgical embryo transfer. The following review will give emphasis to recent advancements in these reproductive technologies that are starting to show possibilities of serious applications under field conditions.

The cell agglutination agent, phytohemagglutinin-L, improves the efficiency of somatic nuclear transfer cloning in cattle (Bos taurus)

One of the several factors that contribute to the low efficiency of mammalian somatic cloning is poor fusion between the small somatic donor cell and the large recipient oocyte. This study was designed to test phytohemagglutinin (PHA) agglutination activity on fusion rate, and subsequent developmental potential of cloned bovine embryos. The toxicity of PHA was established by examining its effects on the development of parthenogenetic bovine oocytes treated with different doses (Experiment 1), and for different durations (Experiment 2). The effective dose and duration of PHA treatment (150 microg/mL, 20 min incubation) was selected and used to compare membrane fusion efficiency and embryo development following somatic cell nuclear transfer (Experiment 3). Cloning with somatic donor fibroblasts versus cumulus cells was also compared, both with and without PHA treatment (150 microg/mL, 20 min). Fusion rate of nuclear donor fibroblasts, after phytohemagglutinin treatment, was increased from 33 to 61% (P < 0.05), and from 59 to 88% (P < 0.05) with cumulus cell nuclear donors. The nuclear transfer (NT) efficiency per oocyte used was improved following PHA treatment, for both fibroblast (13% versus 22%) as well as cumulus cells (17% versus 34%; P < 0.05). The cloned embryos, both with and without PHA treatment, were subjected to vitrification and embryo transfer testing, and resulted in similar survival (approximately 90% hatching) and pregnancy rates (17-25%). Three calves were born following vitrification and embryo transfer of these embryos; two from the PHA-treated group, and one from non-PHA control group. We concluded that PHA treatment significantly improved the fusion efficiency of somatic NT in cattle, and therefore, increased the development of cloned blastocysts. Furthermore, within a determined range of dose and duration, PHA had no detrimental effect on embryo survival post-vitrification, nor on pregnancy or calving rates following embryo transfer.

Birth of offspring after transfer of Mongolian gerbil (Meriones unguiculatus) embryos cryopreserved by vitrification

The Mongolian gerbil (Meriones unguiculatus) has been used as a laboratory species in many fields of research, including neurology, oncology, and parasitology. Although the cryopreservation of embryos has become a useful means to protect valuable genetic resources, its application to the Mongolian gerbil has not yet been reported. In this study, we investigated the in vitro and in vivo developmental competence of Mongolian gerbil embryos cryopreserved by vitrification. In vivo-fertilized embryos were vitrified on the day of collection using the ethylene glycol (EG)-based solutions EFS20 and EFS40, which contained 20% and 40% EG, respectively, in PB1 containing 30% (w/v) Ficoll 70 and 0.5 M sucrose. First, we compared one-step and two-step vitrification protocols. In the one-step method, the embryos were directly transferred into the vitrification solution (EFS40), whereas in the two-step method, the embryos were exposed serially to EFS20 and EFS40 and then vitrified. After liquefying (thawing), late two-cell embryos (collected on day 3) vitrified by the two-step method showed significantly better rates of in vitro development to the morula stage compared to those vitrified by the one-step method (65% vs. 5%, P < 0.0001). We then examined whether the same two-step method could be applied to early two-cell embryos (collected on day 2), four-cell embryos (day 4), morulae (day 5), and blastocysts (day 6). After liquefying, 87%-100% of the embryos were morphologically normal in all groups, and 23% and 96% developed to the compacted morula stage from early two- and four-cell embryos, respectively. After transfer into recipient females, 3% (4/123), 1% (1/102), 5% (4/73), and 10% (15/155) developed to full-term offspring from vitrified and liquefied early two-cell embryos, late two-cell embryos, morulae, and blastocysts, respectively. This demonstrates that Mongolian gerbil embryos can be safely cryopreserved using EG-based vitrification solutions.

Bovine oocyte vitrification before or after meiotic arrest: effects on ultrastructure and developmental ability

The nuclear stage at which oocytes are cryopreserved influences further development ability and cryopreservation affects ultrastructure of both cumulus cells and the oocyte. In this work, we analyze the effects of vitrification at different nuclear and cytoplasmic maturation stages on the oocyte ultrastructure and developmental ability. Culture in TCM199 + PVA with roscovitine 25 M during 24h led to meiotic arrest (MA) in cumulus-oocyte complexes (COCs), while permissive in vitro maturation (IVM) was performed in TCM199, 10% FCS, FSH-LH and 17beta-estradiol for 24 h. Oocytes were vitrified using the open pulled straw method (OPS) with minor modifications. Fresh and vitrified/warmed COCs were fixed as immature, after IVM, after meiotic arrest (MA) and after MA + IVM. Vitrification combined with MA followed by IVM produced the highest rates of degeneration, regardless of the vitrification time. As a consequence, lower proportions of embryos cleaved in these groups, although differences were eliminated at the five-eight cell stage. Development rates up to day 8 were similar in all experimental groups, being significantly lower than those in fresh controls. Only oocytes vitrified after IVM were able to give blastociysts. The morphological alterations observed can be responsible for compromised development. More research is needed to explain the low survival rates of the bovine oocyte after vitrification and warming.

Controlled-rate freezing of human ES cells

A significant obstacle to using human embryonic stem cells (hESCs) arises from extremely poor survival associated with freezing, typically in the range of 1%. This report describes a slow controlled-rate freezing technique commonly used for mammalian embryo cryopreservation. Using a combination of surviving colony number and colony diameter, survival was determined relative to untreated hESCs. Using a dimethyl sulfoxide (DMSO) cryoprotectant and either a homemade controlled-rate freezing device or a commercial freezing device, survival rates of 20%–80% were obtained. To achieve the highest levels of survival, the critical factors were an ice crystal seed (at -7° to -10°C), a freeze rate between 0.3° and 1.8°C/min, and a rapid thaw rate using room temperature water. Slow controlled-rate cooling allows a rapid, simple, and reproducible means of cryopreserving hESCs.

Feasibility of a Nylon-Mesh Holder for Vitrification of Bovine Germinal Vesicle Oocytes in Subsequent Production of Viable Blastocysts1

To improve the feasibility of nylon-mesh holder for vitrification of bovine cumulus-oocytes complexes (GV-COCs) having germinal vesicle, this study was conducted to demonstrate effects of sugars and protocol of exposure in vitrification on subsequent in vitro maturation, ultrastructural changes, and in vitro development in bovine immature oocytes after cryopreservation using nylon mesh. Before vitrification, GV-COCs were exposed to the cryoprotectant, which was composed of 40% (v/v) ethylene glycol, 18% (w/v) Ficoll-70, and 0.3 M sucrose (EFS40) or 0.3 M trehalose (EFT40), either by single step or in a stepwise way. The maturation rates in the stepwise exposure with EFS40 or EFT40 were significantly higher (P < 0.05) compared with the corresponding rates in the single step. In the stepwise exposure, few abnormalities were observed compared with the single-step exposure, where most oocytes showed a highly vacuolated cytoplasm with many ruptured mitochondria. Cleavage rates in fertilized oocytes previously exposed stepwise to EFS40 or EFT40 were significantly higher than those exposed by the single-step procedure. The cleaved embryos derived from the stepwise exposure to EFS40 developed to blastocysts. After transfer of blastocysts derived from vitrified GV oocytes, a female calf was born. These results indicate that vitrification of large numbers of bovine GV-COCs using a nylon-mesh holder accompanied with stepwise exposure minimizes structural damage in organelles, resulting in yield of viable blastocysts following in vitro embryo production.

Relation between Physical Properties of the Zona Pellucida and Viability of Bovine Embryos after Slow-freezing and Vitrification

In vitro-produced bovine morulae/blastocyst embryos (n = 119) were slow-frozen and vitrified and the physical alterations of the zona pellucida (ZP) was observed by scanning electron microscopy (SEM) to find an explanation for the loss of developmental capacity of the embryos after freezing/thawing. A control group was provided, in which embryos (n = 38) were neither frozen nor vitrified. Embryos were in vitro-cultured in a standard CO2 Heraeus incubator and their viability was assessed 24 and 48 h after the start of culture, evaluating their morphological aspect. After 24 h of culture, embryo survival rate for slow-freezing/thawed (n = 23), vitrified/thawed (n = 20) and control embryos (n = 20) was 39, 27 and 90%, and 35, 14 and 65% after 48 h of culture, respectively. For evaluation of physical changes occurring in ZP, 20 embryos were slow-frozen, 18 were vitrified and 18 were used as control. All embryos were fixed, dried and examined under an SEM. Embryo's diameter, as well as the number of pores and their diameter was measured in squares of 6.4 microm width. We observed that, on average, the diameter of the embryos (92.26 +/- 10.15 microm) did not differ significantly among all embryos. As far as the diameter of the pores in the outer surface of the ZP is concerned, the results revealed a significant difference (P < 0.05) between control (0.48 +/- 0.0025 microm), slow-frozen (0.34 +/- 0.0007 microm) and vitrified (0.27 +/- 0.0006 microm) embryos. For the number of pores, statistical differences (p < 0.05) were observed between control and vitrified embryos (45.4 +/- 7.3 vs 38.2 +/- 8.2). It is possible that ZP functions as a barrier which is positive when dealing with pathogens, but is harmful when nutrients were supplied from the outside, especially at 48 h of culture. Results indicate that the steps of cryopreservation cause alterations in ZP, with irreversible damage on the further developmental competence of bovine embryos.

Aseptic technology of vitrification of human pronuclear oocytes using open-pulled straws

BACKGROUND

The aim of this study was to compare the viability of human pronuclear oocytes subjected to vitrification using cooling by direct submerging of open-pulled straws in liquid nitrogen versus vitrification by cooling of open-pulled straws located inside a closed 0.5 ml straw (aseptic system).

METHODS

Two- and three-pronuclei stage oocytes (n=114) were cryopreserved in super-open-pulled straws by vitrification in 20% ethylene glycol +20% dimethylsulphoxide (DMSO) + osmotic active and neutral non-permeable cryoprotectants with a four-step exposure in 20, 33, 50 and 100% vitrification solution for 2, 1 and 1 min, and 30-50 s, respectively at room temperature, and plunging into liquid nitrogen. Oocytes of group 1 (n=42) were rapidly cooled at a speed of 20,000 degrees C/min by direct plunging of open-pulled straws into liquid nitrogen. Oocytes of group 2 (n=44) were first located in 0.5 ml straws, which were closed at both sides by metal balls, and then plunged into liquid nitrogen. This method resulted in a cooling speed of 200 degrees C/min. For both groups, oocytes were thawed rapidly at a speed of 20 000 degrees C/min using an identical protocol. Oocytes subsequently were expelled into a graded series of sucrose solutions (1.0, 0.75, 0.5, 0.25 and 0.12 mol/l) at 2.5 min intervals.

RESULTS

Oocyte development up to expanded blastocyst stage after in vitro culture was 15% in group 1, 14% in group 2 and 29% in an untreated control group.

CONCLUSION

The deposition of human pronuclear oocytes in open-pulled straws which are placed inside a hermetically closed container guarantees a complete isolation of oocytes from liquid nitrogen and avoids potential contamination by pathogenic microorganisms. The combination of direct plunging of this container into liquid nitrogen and rapid warming makes this process as efficient as conventional vitrification.

Lowering intracellular and extracellular calcium contents prevents cytotoxic effects of ethylene glycol-based vitrification solution in unfertilized mouse oocytes

We investigated the characteristics of the changes in intracellular calcium (Ca2+) concentration ([Ca2+](i)) and the viability of the unfertilized mouse oocytes exposed to various concentrations of ethylene glycol (EG)-containing solutions or vitrification solutions. Oocytes exposed to EG (1, 5, 10, 20, and 40% (v/v)) exhibited a rapid and dose-dependent increase in [Ca2+](i). The survival rate was 100% when oocytes were exposed to the EG concentration up to 5% through 5 min, while all oocytes were dead within 3 min when exposed to 10, 20, or 40% EG. When extracellular Ca2+ was removed, increase in [Ca2+](i) at 10 and 20% EG was less than that at the same concentrations of EG with extracellular Ca2+. The survival rates of the oocytes exposed to 10, 20, and 40% EG at 3 min were 100, 97, and 0%, respectively. In the presence of 20 microM 1,2-bis(o-aminopheoxy)ethane-N,N,N',N'-tetraacetic acid tetra acetoxymethyl ester (BAPTA-AM), a Ca2+ chelator, a small increase in [Ca2+](i) exposed to 10, 20, and 40% EG was observed until 4 min. Subsequently prolonged elevation of the [Ca2+](i) was observed in the oocytes exposed to 40% EG but not with 10 and 20% EG. The survival rate of the oocytes, in the presence of 20 microM BAPTA-AM, exposed to 10 and 20% EG was 100% throughout 5 min, while the oocytes exposed to 40% EG were alive only for 3 min. Treatment by the vitrification solution with various concentrations of EG (10, 20, and 40%) caused a smaller increase in [Ca2+](i), while the survival rates were higher compared to those without vitrification solution at the same concentrations of EG. These data suggested that the sustained [Ca2+](i) rises by EG in unfertilized mouse oocytes resulted in cell death. Therefore, the lowering of [Ca2+](i) in the oocytes exposed to the cryoprotectant may improve the viability of cryopreserved unfertilized oocytes.

Successful pregnancy following blastocyst cryopreservation using super-cooling ultra-rapid vitrification

BACKGROUND

Blastocysts were cryopreserved by a new two-step ultra-rapid cooling in super-cooled liquid nitrogen (-205 degrees C).

METHODS

There were 308 mouse blastocysts collected from fertile B6CBF1 mice and 249 human blastocysts collected from 51 couples treated with IVF. The blastocysts were super-cooled by a Vit-Master and cryoloops after treatment in 50 and 100% vitrification solution (VS) for 2 min and 30 s, respectively. The 100% VS was composed of 20% ethylene glycol, 20% dimethylsulphoxide and 0.5 mol/l sucrose in human tubular fluid medium with 20% human serum albumin. The embryos were warmed after treatment in 0.25 and 0.125 mol/l sucrose for 2 and 3 min, respectively. The survival of embryos was observed after re-swell.

RESULTS

The survival rate (SR) and hatching rate (HR) of mouse blastocysts in the super-cooled, the cryosolution-treated and control groups were not significantly different (SR, 87, 95.5 and 100%; HR, 50, 33 and 44.6%, respectively; P>0.05). After 96 super-cooled human blastocysts were warmed, 60 survival blastocysts were transferred into 13 patients. The successful SR and pregnancy rate (PR) for the super-cooled blastocyst group were 77.1% (74 out of 96) and 53.8% (seven out of 13).

CONCLUSION

The ultra-rapid vitrification of blastocysts with a successful SR and PR could be used to replace classical slow cooling.

Fundamental cryobiology of reproductive cells and tissues

During the last half of the 20th century there have been considerable advancements in mammalian reproductive technologies, including in vitro production of pre-implantation embryos and embryo sexing, and even cloning in some species. However, in most cases, management of non-cryopreserved reproductive cells (i.e., spermatozoa or oocytes) and tissues (i.e., testicular tissue or ovarian tissue) is problematic due to difficulties in donor-recipient synchronization and the potential for transmission of infectious pathogens, which cumulatively limits widespread application of these techniques. Therefore, there is an urgent need for the development of optimum cryopreservation methods for reproductive cells and tissues from many species. Today frozen-thawed spermatozoa and embryos have become an integral component of animal agriculture, laboratory animal genome banking, and human sperm banking and infertility programs. However, although widely implemented, the protocols currently used to cryopreserve bull sperm, for example, are still suboptimal, and cannot readily be extrapolated to other species' sperm. Similarly, embryo-freezing protocols successfully used for mouse and cattle have yielded little success when applied to some other species' embryos, or to a related cell type, oocytes. To date, with the exception of mouse oocytes, almost all mammalian species' oocytes studied have proven very difficult to successfully cryopreserve. Currently, there is a growing interest to understand the underlying cryobiological fundamentals responsible for these low survival rates in an effort to develop better cryopreservation methods for oocytes. Additionally, there is growing interest in developing technologies for the optimal isolation and cryopreservation of the earliest stage of male (spermatogonia, spermatids) and female (primordial follicle) germ cells, with subsequent maturation to the desired stage in vitro. Female gamete maturation, fertilization, and embryo development entirely under in vitro conditions from primordial follicles has been achieved in mice, however techniques for this and other species are still very early in their development. Furthermore, with the recent advances made in intracytoplasmic sperm injection (ICSI), and gamete isolation and maturation, close attention has been given to cryopreservation of gametes in the form of gonadal tissue (i.e., testicular tissue and ovarian tissue) containing various developmental stages of male (spermatogonia, spermatids, and spermatozoa) and female (primordial, secondary) germ lines.

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.

Comparison of different vitrification protocols on viability after transfer of ovine blastocysts in vitro produced and in vivo derived

We compare different vitrification protocols on the pregnancy and lambing rate of in vitro produced (IVP) and in vivo derived (IVD) ovine embryos. Ovine blastocysts were produced by in vitro maturation, fertilization and culture of oocytes collected from slaughtered ewes or superovulated and inseminated animals. Embryos were cryopreserved after exposure at room temperature either for 5 min in 10% glycerol (G), then for 5 min in 10% G + 20% ethylene glycol (EG), then for 30 s in 25% G + 25% EG (glycerol group), or for 3 min in 10% EG + 10% dimethyl sulphoxide (DMSO), then for 30s in 20% EG + 20% DMSO + 0.3 M sucrose (DMSO group). One group of in vitro produced embryos was cryopreserved similarly to the DMSO group, but with 0.75 M sucrose added to the vitrification solution (DMSO 0.75 group). Glycerol group embryos were then loaded into French straws or open pulled Straws (OPS) while the DMSO group embryos were all loaded into OPS and directly plunged into liquid nitrogen. Embryos were warmed with either a one step or three step process. In the one step process, embryos were placed in 0.5 M sucrose. The three-step process was a serial dilution in 0.5, 0.25 and 0.125 M sucrose. The embryos of DMSO 0.75 group were warmed directly by plunging them into tissue culture medium-199 (TCM-199) + 20% foetal bovine serum (FBS) in the absence of sucrose (direct dilution). Following these manipulations, the embryos were transferred in pairs into synchronised recipient ewes and allowed to go to term. The pregnancy and the lambing rate within each group of IVP and IVD embryos indicated that there was no statistical difference among the vitrification protocols.

Vitrification of porcine embryos at various developmental stages using different ultra-rapid cooling procedures

In this study, three different vitrification systems (open pulled straw: OPS; superfine open pulled straw: SOPS; and Vit-Master technology using SOPS: Vit-Master-SOPS) were compared in order to investigate the influence of cooling rate on in vitro development of vitrified/warmed porcine morulae, early blastocysts, or expanded blastocysts. Embryos were obtained surgically on Day 6 of the estrous cycle (D0 = onset of estrus) from weaned crossbred sows, classified and pooled according their developmental stage. A subset of embryos from each developmental stage was cultured to evaluate the in vitro development of fresh embryos; the remaining embryos were randomly allocated to each vitrification system. After vitrification and warming, embryos were cultured in vitro for 96 h in TCM199 with 10% fetal calf serum at 39 degrees C, in 5% CO(2) in humidified air. During the culture period, embryos were morphologically evaluated for their developmental progression. The developmental stage of embryos at collection affected the survival and hatching rates of vitrified/warmed embryos (P < 0.001). The vitrification system or the interaction of vitrification system and developmental stage had no effect on these parameters (P > 0.05). Vitrified expanded blastocysts showed the best development in vitro (P < 0.001), with survival and hatching rates similar to those of fresh expanded blastocysts. The hatching rate of fresh morula or early blastocyst stage embryos was higher than their vitrified counterparts. In conclusion, under our experimental conditions, cooling rates greater than 20,000 degrees C/min, as occurs when SOPS or Vit-Master-SOPS systems are used, do not enhance the efficiency of in vitro development of vitrified porcine embryos.

Cryopreservation of caprine ovarian tissue using glycerol and ethylene glycol

Cryopreservation of ovarian tissue may be a potential alternative for the conservation of genetically superior animals, including high milk- and meat-producing goat breeds. However, until now, no information was available concerning the cryopreservation of preantral follicles (PF) enclosed in caprine ovarian tissue. The objective of the present study was to evaluate the structural and ultrastructural characteristics of caprine PF after exposure to and cryopreservation of ovarian tissue in 1.5 and 3M glycerol (GLY) and ethylene glycol (EG). At the slaughterhouse, each ovarian pair from five adult mixed breed goats was divided into nine fragments and randomly distributed into treatment groups. One fragment was immediately fixed for histological examination and ultrastructural analysis, after slaughter (control). Four of the ovarian fragments were equilibrated at 20 degrees C for 20 min in 1.8 ml of MEM containing 1.5 or 3M GLY or EG for a toxicity test and the final four fragments were slowly frozen using these cryoprotectants at the concentrations above. After toxicity testing and freezing/thawing, the ovarian fragments were fixed for histological examination. Histological analysis showed that after toxicity testing and cryopreservation of the ovarian tissue in GLY or EG at both concentrations, the percentage of normal PF was significantly lower than controls. Ultrastructural analysis of PF frozen in 1.5 and 3M GLY, as well as 3M EG demonstrated that these follicles remained morphologically normal. In conclusion, we demonstrated cryopreservation of caprine PF in ovarian tissue.

An overview of oocyte cryopreservation

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