Cryopreservation of primate embryonic stem cells with chemically-defined solution without Me2SO

Human embryonic stem (hES) cells are expected to be useful in the fields of regenerative medicine and tissue engineering due to their pluripotency. Therefore, it is necessary to establish highly efficient and reliable methods for the cryopreservation of hES cells. We have cryopreserved cynomolgus and human ES cells by the vitrification method, using a chemically-defined dimethyl sulfoxide (Me₂SO)-free and serum-free medium composed of Euro-Collins solution as a base medium and 40% (v/v) ethylene glycol (EG) and 10% (w/v) polyethylene glycol (PEG) as cryoprotectants. When the vitrification and the cryoprotectants were combined, the recovery ratio of hES cells was 22.9 ± 7.7%, compared to 0.4 ± 0.2% when the conventional slow-freezing method was used. After the cryopreservation and thawing cycle, hES cells were easily cultured and expressed undifferentiated cell markers such as Nanog, Oct-4, SSEA-4, and alkaline phosphatase activity after several subculturing steps. We also found that the pluripotency of hES cells was maintained, as demonstrated by teratoma formation of ES cells transplanted into severe combined immunodeficient (SCID) mice. Thus, we conclude that we have successfully cryopreserved primate ES cells with high efficiency using a Me₂SO-free, chemically-defined medium.     

Cryopreservation of Bufotes viridis embryos by vitrification

Loss of biodiversity among amphibians is a current concern. Our hypothesis is that the embryos of amphibian species at risk of extinction could be cryopreserved by vitrification, using methods which have proved successful with fish oocyte. To test this hypothesis, samples of four cryoprotectants - methanol (MeOH), dimethyl sulphoxide (Me2SO), propylene glycol (PG) and polyethylene glycol (PEG), some singly, some in combination, were plunged in liquid nitrogen for 5 min to find the best solution for vitrification. To find the least toxic of these solutions, blastulae and stage G17 embryos of Bufotes Viridis, a typical amphibian, were exposed to solutions at different concentrations (0.5–10 M) for different lengths of time (15–30 min), with and without their normal protective jelly coats. In each case the number of survivors, which reached stage G25 was counted. Finally a series of embryos was vitrified in liquid nitrogen using the most efficient and least toxic cryoprotectants.Propylene glycol had the best vitrification characteristics, but MeOH vitrified at higher concentrations. The optimum regime, with the least toxic ctyoprotectants, consisted of 1M Me2SO for 15 min and a combination of 15% PEG_(w/v) + 3M PG + 2M Me2SO for 3 min, with the jelly coat intact, followed by vitrification. This gave a survival percentage of 87.6% immediately after vitrification. Methods designed for cryopreservation of fish embryos make a good starting point for cryopreservation of the embryos of amphibian.     

Drug metabolism and viability studies in cryopreserved rat hepatocytes

Rat hepatocytes were cryopreserved optimally by freezing them at 1 degrees C/min to -80 degrees C in cryoprotectant medium containing either 20% (v/v) dimethylsulfoxide (Me2SO) and 25% (v/v) fetal calf serum in Leibowitz L15 medium (Me2SO cryoprotectant) or 25% (v/v) vitrification solution (containing Me2SO, acetamide, propylene glycol and polyethylene glycol) in Leibowitz L15 medium (VS25). The VS25 solution was superior for maintaining viability during short-term storage (24-48 hr) but was slightly toxic during longer storage periods (7 days). Although thawed cells were 40-50% viable on ice after cryopreservation, their viability fell rapidly during incubation in suspension at 37 degrees C. This decline in viability occurred more rapidly after freezing in Me2SO cryoprotectant than in VS25 and was associated with extensive intracellular damage and cell swelling. The loss in viability at 37 degrees C does not appear to be due to ice-crystal damage as it occurred in cells stored at -10 degrees C (above the freezing point of the cryoprotectants) and it may be due to temperature/osmotic shock. Both cryoprotectant media were equally efficient at preserving enzyme activities in the hepatocytes over 7 days at -80 degrees C. Cytochrome P450 and reduced glutathione content and the activities of the microsomal enzymes responsible for aminopyrine N-demethylation and epoxide hydrolysis were well maintained over 7 days storage. In contrast, the cytosolic enzymes glutathione-S-transferase and glutathione reductase were markedly labile during cryopreservation. Cytosolic enzymes may be more susceptible to ice-crystal damage, whereas the microsomal membrane may protect the enzymes which are embedded in it.     

A study on cryoprotectant solution suitable for vitrification of rat two-cell stage embryos

The present study was performed to develop a suitable cryoprotectant solution for cryopreservation of rat two-cell stage embryos. First, we examined the cell permeability of several cryoprotectants; propylene glycol had the fastest permeability compared to dimethyl sulfoxide, ethylene glycol, and glycerol. Embryos were then exposed to a solution containing propylene glycol to evaluate its effects on fetal development. As the development was similar to that of fresh embryos, P10 (10% v/v propylene glycol in PB1) was used as a pretreatment solution. Next, the effects of the vitrification solution components (sucrose, propylene glycol, ethylene glycol, and Percoll) were examined by observing the vitrification status; 10% v/v propylene glycol, 30% v/v ethylene glycol, 0.3 mol sucrose, and 20% v/v Percoll in PB1 (PEPeS) was the minimum essential concentration for effective vitrification without the formation of ice crystals or freeze fractures.     

Negative air pressure treatment accelerates the penetration of permeable cryoprotectants into bovine ovarian tissue in vitrification protocol and improves cell density after vitrification

Effects of additional physical treatments during vitrification of the bovine ovarian tissue were examined for increasing of permeability of ethylene glycol (EG) and dimethyl sulfoxide (Me2SO). The concentrations of EG and Me2SO and histological changes in the ovarian tissue were evaluated. In the first equilibration step (7.5% EG and 7.5% Me2SO), all the 10-min physical treatments, i.e., negative (679 hPa) or positive (1347 hPa) air pressure applied with a disposable syringe, and shaking (60 rpm) applied with a laboratory shaker, were comparable to 25-min non-physical treatment (plain) vitrification. When effects of the negative air pressure were examined in the second equilibration step (20% EG and 20% Me2SO), its 10-min treatment was equivalent to 15-min plain vitrification (140–170 mg/g tissue). It was thus indicated that the negative air pressure treatment accelerates the penetration of permeable cryoprotectants into the ovarian tissue slices. Histological examination showed that the cell density and the amount of pan-cadherin in the tunica albuginea of the ovary was reduced by the vitrification, but was improved by the negative air pressure treatment. The amount of pan-cadherin in the tunica albuginea was recommended as a biomarker for evaluation of effectiveness of protocol for cryopreservation of bovine ovarian tissue and considered to be a candidate biomarker for human ovarian tissue cryopreservation.     

Tolerance of human embryonic stem cell derived islet progenitor cells to vitrification-relevant solutions

We have previously shown that human embryonic stem cell derived islet progenitors (hESC-IPs), encapsulated inside an immunoprotective device, mature in vivo and ameliorate diabetes in mice. The ability to cryopreserve hESC-IPs preloaded in these devices would enhance consistency and portability, but traditional ‘slow freezing’ methods did not work well for cells encapsulated in the device. Vitrification is an attractive alternative cryopreservation approach. To assess the tolerance of hESC-IPs to vitrification relevant conditions, we here are reporting cell survival following excursions in tonicity, exposure to fifteen 40% v/v combinations of 4 cryoprotectants, and varied methods for addition and elution. We find that 78% survival is achieved using a protocol in which cells are abruptly (in one step) exposed to a solution containing 10% v/v each dimethyl sulfoxide, propylene glycol, ethylene glycol, and glycerol on ice, and eluted step-wise with DPBS + 0.5 M sucrose at 37 °C. Importantly, the hESC-IPs also maintain expression of the critical islet progenitor markers PDX-1, NKX6.1, NGN3 and NEURO-D1. Thus, hESC-IPs exhibit robust tolerance to exposure to vitrification solutions in relevant conditions.     

Factors affecting the survival of mouse embryos cryopreserved by vitrification

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

Cryopreservation of a marine microalga, Nannochloropsis oculata (Eustigmatophyceae)

The cryopreservation of algae could prevent genetic drift and minimize labor costs compared to the current method of maintenance and subculturing. Clear, simple protocols for cryopreservation of marine microalga, Nannochloropsis oculata were developed and cryoprotectant choice and concentration optimized. The viability of the microalga was assessed directly after thawing, and algal concentration was measured after 2-30 days of growth. Five cryoprotectants (dimethyl sulphoxide, Me2SO; ethylene glycol, EG; glycerol, Gly; methanol, MeOH; and propylene glycol, PG) at five concentrations (10, 20, 30, 40, and 50%; v/v) were evaluated to determine the toxicity of various cryoprotectants to N. oculata. The toxicity of cryoprotectant (Me2SO, EG, MeOH, and PG) was observed only at higher concentrations of CPAs: > 20% for EG, > 30% for Me2SO and methanol, and > 40% for PG. Direct freezing of algae in liquid nitrogen resulted in a severe loss of viability and a modified cryopreservation protocol proved to be more appropriate for the preservation of N. oculata. Cryopreservation protocols developed and tested in the present study might be applied to cryopreserving other strains, or species, in this genus.     

Japanese flounder (Paralichthys olivaceus) embryos are difficult to cryopreserve by vitrification

The first successful cryopreservation of fish embryos was reported in the Japanese flounder by vitrification [Chen and Tian, Theriogenology, 63, 1207-1219, 2005]. Since very high concentrations of cryoprotectants are needed for vitrification and fish embryos have a large volume, Japanese flounder embryos must have low sensitivity to cryoprotectant toxicity and high permeability to water and cryoprotectants. So, we investigated the sensitivity and the permeability of Japanese flounder embryos. In addition, we assessed the survival of flounder embryos after vitrification with solutions containing methanol and propylene glycol, following Chen and Tian's report. The embryos were relatively insensitive to the toxicity of individual cryoprotectants at lower concentrations, especially methanol and propylene glycol as their report. Although their permeability to water and cryoprotectants could not be measured from volume changes in cryoprotectant solutions, the embryos appeared to be permeable to methanol but less permeable to DMSO, ethylene glycol, and propylene glycol. Although vitrification solutions containing methanol and propylene glycol, which were used in Chen and Tian's report, were toxic to embryos, a small proportion of embryos did survived. However, when vitrified with the vitrification solutions, no embryos survived after warming. The embryos became opaque during cooling with liquid nitrogen, indicating the formation of intracellular ice during cooling. When embryos had been kept in vitrification solutions for 60 min after being treated with the vitrification solution, some remained transparent during cooling, but became opaque during warming. This suggests that dehydration and/or permeation by cryoprotectants were insufficient for vitrification of the embryos even after they had been over-treated with the vitrification solutions. Thus, Chen and Tian's cryopreservation method lacks general application to Japanese flounder embryos.     

Gene expression analysis of human induced pluripotent stem cells cryopreserved by vitrification using StemCell Keep

In recent years, regenerative medicine research using human somatic and induced pluripotent stem cells has advanced considerably, promoting clinical applications. However, it is essential that these cells are cryopreserved safely and effectively. Most cryopreservation solution agents contain dimethyl sulfoxide (DMSO), which exhibits strong toxicity and can potentially promote cell differentiation. Hence, it is important to explore substitutes for DMSO in cryoprotectant solutions. One such alternative is StemCell Keep (SCK), a DMSO-free solution that has been reported to effectively cryopreserve human induced pluripotent stem cells (hiPS cells). To clarify the effect of cryopreservation agents on cells, DNA microarray analysis is useful, as it can identify a large number of gene expression differences in cryopreserved cells, as well as functional increases in gene groups. In this study, we performed gene expression analysis of SCK-cryopreserved hiPS cells using a DNA microarray gene chip. The hiPS cells vitrified with SCK or DMSO-based vitrification solutions were thawed and cultured on Matrigel under feeder-free conditions, and RNA was extracted for DNA microarray analysis. Genes obtained from DNA microarray data were classified by the keywords of Gene Ontology Biological Process Term, and their relationships were analyzed using DAVID or the GeneMANIA database.SCK-cryopreserved hiPS cells expressed several anti-apoptotic genes, as well as genes related to cell adhesion or proliferation at levels that were nearly equivalent to those of non-frozen hiPS cells. Gene enrichment analysis with selected genes of SCK-cryopreserved hiPS cells whose expression differences were superior to those of DAP-cryopreserved showed strong interactions of negative regulation of apoptotic process, cell adhesion and positive regulation of cell proliferation in DAVID analysis. We demonstrated that SCK successfully maintained the key functions of hiPS cells, including anti-apoptosis, cell adhesion, and cell proliferation, during cryopreservation.     

Successful cryopreservation of mouse blastocysts using a new vitrification solution.

Mouse blastocysts were exposed to solutions containing four concentrations (10, 20, 30 and 40% v/v) of six permeating cryoprotectants (glycerol, ethylene glycol, propylene glycol, dimethyl sulfoxide, 1,3-butanediol and 2,3-butanediol) in phosphate-buffered saline (PBS) with calf serum (CS) at room temperature (20-22 degrees C). Blastocysts were exposed to these solutions for various periods, diluted into PBS plus CS with or without 1 mol trehalose l-1 solution and their subsequent survival in vitro was examined. Two-way anova showed a significant interaction (P < 0.01) between cryoprotectant type, concentration of cryoprotectant and method of dilution. However, no significant interaction was observed between cryoprotectant type and duration of exposure. Results suggest that cryoprotectant-induced injury to nonfrozen blastocysts is variable and depends on the cryoprotectant used. On the basis of toxicity assays, ethylene glycol was the least harmful and was combined with dimethyl sulfoxide and 1,3-butanediol to produce a new vitrification solution. Mouse blastocysts were successfully cryopreserved using a vitrification solution (designated as VSv) consisting of 20% ethylene glycol, 20% dimethyl sulfoxide and 10% 1,3-butanediol (v/v). Embryos were equilibrated in two steps, first in an equilibration solution (designated as ESv: 10% ethylene glycol, 10% dimethyl sulfoxide and 5% 1,3-butanediol; v/v) and then to VSv or one-step in VSv at different exposure times at room temperature, and then vitrified by direct plunging into liquid nitrogen. High developmental rates were obtained in vitro when the embryos were exposed to ESv and VSv for 3 and 0.5 min, respectively (96.2%) or exposed to VSv for 0.5 min (95.4%). Prolonged exposure time proved detrimental to subsequent embryo development in vitro. When vitrified warmed embryos were transferred immediately to pseudopregnant recipients, the rate of development to normal fetuses did not significantly differ from that of the nonvitrified control (two-step, 54.2 and one-step, 45.0 versus 60.0%, P > 0.05). These results suggest that the simple vitrification solution described in this study is effective for the cryopreservation of mouse blastocysts.     

Cryopreservation of rat precision-cut liver and kidney slices by rapid freezing and vitrification

Precision-cut tissue slices of both hepatic and extra-hepatic origin are extensively used as an in vitro model to predict in vivo drug metabolism and toxicity. Cryopreservation would greatly facilitate their use. In the present study, we aimed to improve (1) rapid freezing and warming (200 degrees C/min) using 18% Me(2)SO as cryoprotectant and (2) vitrification with high molarity mixtures of cryoprotectants, VM3 and VS4, as methods to cryopreserve precision-cut rat liver and kidney slices. Viability after cryopreservation and subsequent 3-4h of incubation at 37 degrees C was determined by measuring ATP content and by microscopical evaluation of histological integrity. Confirming earlier studies, viability of rat liver slices was maintained at high levels by rapid freezing and thawing with 18% Me(2)SO. However, vitrification of liver slices with VS4 resulted in cryopreservation damage despite the fact that cryoprotectant toxicity was low, no ice was formed during cooling and devitrification was prevented. Viability of liver slices was not improved by using VM3 for vitrification. Kidney slices were found not to survive cryopreservation by rapid freezing. In contrast, viability of renal medullary slices was almost completely maintained after vitrification with VS4, however vitrification of renal cortex slices with VS4 was not successful, partly due to cryoprotectant toxicity. Both kidney cortex and medullary slices were vitrified successfully with VM3 (maintaining viability at 50-80% of fresh slice levels), using an optimised pre-incubation protocol and cooling and warming rates that prevented both visible ice-formation and cracking of the formed glass. In conclusion, vitrification is a promising approach to cryopreserve precision-cut (kidney) slices.     

Effect of different cryoprotectants and vitrificant solutions on the hatching rate of turbot embryos (Scophthalmus maximus)

Vitrification could provide a promising tool for the cryopreservation of fish embryos. However, in order to achieve a vitrifiable medium, a high concentration of permeable cryoprotectants must be employed, and the incorporation of high molecular weight compounds should also be considered. The toxicity of these permeable and non-permeable agents has to be assessed, particularly when high concentrations are required. In the present study, permeable and non-permeable cryoprotectant toxicity was determined in turbot embryos at two development stages (F stage-tail bud and G stage-tail bud free). Embryos treated with pronase (2mg/ml, 10 min at 22 degrees C) were incubated in dimethyl sulfoxide (Me2SO), methanol (Meth.) or ethylene glycol (EG) in concentrations ranging from 0.5 to 6M for periods of 10 or 30 min, and in 5, 10, and 15% polyvinylpyrrolidone (PVP), 10, 15, and 20% sucrose or 0.1, 1, and 2% X-1000 for 2 min. The embryos were then washed well and incubated in seawater until hatching. The toxicity of permeable cryoprotectants increased with concentration and exposure time. There were no significant differences between permeable cryoprotectants. However, embryos tolerated higher concentrations of Me2SO than other cryoprotectants. Exposure to permeable cryoprotectants did not affect the hatching rate except at G stage with X-1000 treatment and 20% sucrose. Taking into account the cryoprotectant toxicity and the vitrification ability of cryoprotectant mixtures, three vitrification solutions (V1, V2, and V3), and one protocol for stepwise incorporation were designed. The tested solutions contained 5M Me2SO+2M Meth+1M EG plus 5% PVP, 10% sucrose or 2% X-1000. The hatching rate of embryos that had been exposed to the the vitrification solutions was analyzed and no significant differences were noticed compared with the controls. Our results demonstrate that turbot embryos can be subject to this cryoprotectant protocol without deleterious effect on the hatching rate.     

Cryopreservation in micro-volumes: impact upon Caco-2 colon adenocarcinoma cell proliferation and differentiation

Recent advances in cell-based therapies require new approaches for cell cryopreservation, capable of dealing with large number of samples and providing specific conditions for each cell type. Reduction of sample volume from the commonly used 1 mL to 25 microL in 30-well micro-cryosubstrates improves cryopreservation by allowing automation, data handling and access to individual wells without thawing the whole cryosubstrate. This system was evaluated for the storage of Caco-2 colon adenocarcinoma cells, which differentiate spontaneously after long-term culture. The impact of the cryosample small volume upon post-thawing membrane integrity of the cells and their capacity to proliferate and differentiate was studied. Two different cryoprotectants commonly employed, dimethyl sulfoxide (Me(2)SO) and glycerol, were evaluated as well as the possibility of decreasing their concentration from the 10% concentration, usually used, down to 3% (v/v). The process automation by pipette robotic addition of the cryoprotectant to the micro-cryosubstrates was also evaluated. The micro-cryosubstrates have proven to be at least as efficient as typical 1 mL cryovials for cryopreservation of Caco-2 cells using either Me(2)SO or glycerol. Compared to the manual process, the automatic addition of glycerol to the micro-cryosubstrates allowed higher cell viabilities after thawing while with Me(2)SO no significant changes were observed. Me(2)SO has shown to be more effective than glycerol in maintaining high post-thaw cell membrane integrity, either in micro-cryosubstrates or cryovials, for any of the concentrations tested. The ability of Me(2)SO in maintaining high cell membrane integrity post-thawing was confirmed by long-term (up to 22 days) proliferation and differentiation studies performed with cells cultured immediately after thawing.     

Production of channel catfish with sperm cryopreserved by rapid non-equilibrium cooling

This report describes the feasibility of using vitrification for fish sperm. Vitrification can be used to preserve samples in the field and offers an alternative to conventional cryopreservation, although it has not been systematically studied for sperm of aquatic species. The overall goal of the project was to develop streamlined protocols that could be integrated into a standardized approach for vitrification of aquatic species germplasm. The objectives of the present study in channel catfish (Ictalurus punctatus) were to: (1) evaluate the acute toxicity of 5%, 10%, 20% and 30% methanol, N,N-dimethyl acetamide, dimethyl sulfoxide, 1,2-propanediol, and methyl glycol; (2) evaluate a range of devices commonly used for cryopreservation and vitrification of mammalian sperm; (3) compare vitrification with and without cryoprotectants; (4) evaluate the post-thaw membrane integrity of sperm vitrified in different cryoprotectant solutions, and (5) evaluate the ability of vitrified sperm to fertilize eggs. Cryoprotectant concentrations of higher than 20% were found to be toxic to sperm. Methanol and methyl glycol were the least toxic at a concentration of 20% with an exposure time of less than 5 min. We evaluated a method reported for human sperm, using small volumes in loops (15 μl) or cut standard straws (20 μl) with and without cryoprotectants plunged into liquid nitrogen. Cryoprotectant-free vitrification using loops did not yield fertilization (assessed by neurulation), and the fertilization rates observed in two trials using the cut standard straws were low (∼2%). In general, fertilization values for vitrification experiments were low and the use of low concentrations of cryoprotectants yielded lower fertilization (<10%) than the use of vitrification solutions containing high cryoprotectant concentrations (as high as 25%). The highest neurulation obtained was from a mixture of three cryoprotectants (20% methanol + 10% methyl glycol + 10% propanediol) with a single-step addition. This was reflected in the flow cytometry data from which the highest membrane integrity using loops was for 20% methanol + 10% methyl glycol + 10% propanediol (∼50%). We report the first successful sperm vitrification in fish and production of offspring from vitrified sperm in channel catfish. Although the fertilization values were low, at present this technique could nevertheless be used to reconstitute lines (especially in small aquarium fishes), but it would require improvement and scaling up before being useful as a production method for large-bodied fishes such as catfish.     

Cryopreservation of flounder (Paralichthys olivaceus) embryos by vitrification

Conventional cryopreservation of complex teleost embryos has been unsuccessful, possibly because their large size (1-7 mm diameter), multi-compartmental structure and low water permeability lead to intracellular ice formation and chilling injury. To overcome these obstacles, we have developed a vitrification procedure for cryopreservation of flounder (Paralichthys olivaceus) embryos. In initial toxicity tests, propylene glycol (PG) and methanol (MeOH) were less toxic to embryos than dimethylformamide (DMF) or dimethyl sulfoxide (Me2SO), whereas ethylene glycol (EG) and glycerol (Gly) were toxic to all tested embryos. Embryos between four-somite and tail bud stages were more tolerant to vitrifying solutions than embryos in other developmental stages. Four vitrifying solutions (FVS1-FVS4) were prepared by combining a basic saline solution (BS2) and cryoprotectants PG and MeOH in different proportions (FVS1: 67, 20 and 13%; FVS2: 60, 24 and 16%; FVS3: 55, 27 and 18%; FVS4: 50, 30 and 20% of BS2, PG and MeOH, respectively). Their impact on flounder embryos was then compared. FVS1 produced the highest survival rate; whereas deformation rate was highest for FVS4. Five-step equilibration of embryos in FVS2 resulted in higher survival rates than equilibration in 4, 3, 2 or 1 steps. Flounder embryos varying from the 14-somite to the pre-hatching stage were cryopreserved in the four vitrifying solutions in liquid nitrogen for 1-7 h. From eight experiments, 20 viable thawed embryos were recovered from 292 cryopreserved embryos. Fourteen larvae with normal morphology hatched successfully from the 20 surviving frozen-thawed embryos from five experiments. Embryos at the tail bud stage exhibited greater tolerance to vitrification than embryos at other stages. These results establish that cryopreservation of flounder embryos by vitrification is possible. The technology has many potential applications in teleost germplasm resource conservation.     

Development of a modified vitrification strategy suitable for subsequent scale-up for hepatocyte preservation

This work explores the design of a vitrification solution (VS) for scaled-up cryopreservation of hepatocytes, by adapting VS_basic (40% (v/v) ethylene glycol 0.6 M sucrose, i.e. 7.17 M ethylene glycol 0.6 M sucrose), previously proven effective in vitrifying bioengineered constructs and stem cells. The initial section of the scale-up study involved the selection of non-penetrating additives to supplement VS_basic and increase the solution’s total solute concentration. This involved a systematic approach with a step-by-step elimination of non-penetrating cryoprotectants, based on their effect on cells after long/short term exposures to high/low concentrations of the additives alone or in combinations, on the attachment ability of hepatocytes after exposure. At a second stage, hepatocyte suspension was vitrified and functions were assessed after continuous culture up to 5 days.     

Toxicity and protective efficiency of cryoprotectants to flounder (Paralichthys olivaceus) embryos

With the purpose of finding an ideal cryoprotectant or combination of cryoprotectants in a suitable concentration for flounder (Paralichthys olivaceus) embryo cryopreservation, we tested the toxicities, at culture temperature (16 degrees C), of five most commonly used cryoprotectants-dimethyl sulfoxide (Me2SO), glycerol, methanol (MeOH), 1,2-propylene glycol (PG) and ethylene glycol (EG). In addition, cryoprotective efficiency to flounder embryos of individual and combined cryoprotectants were tested at -15 degrees C for 60 min. Five different concentrations of each of the five cryoprotectants and 20 different combinations of these cryoprotectants were tested for their protective efficiency. The results showed that the toxicity to flounder embryos of the five cryoprotectants are in the following sequence: PG < MeOH < Me2SO < glycerol < EG (P < 0.05); whereas the protective efficiency of each cryoprotectant, at -15 degrees C for a period of 60 min, are in the following sequence: PG > Me2SO approximately MeOH approximately glycerol > EG (greater symbols mean P < 0.05, and approximate symbols mean P > 0.05). Methanol combined with any one of the other cryoprotectants gave the best protection, while ethylene glycol combined with any one of the other cryoprotectants gave the poorest protection at -15 degrees C. Toxicity effect was concentration dependent with the lowest concentration being the least toxic for all five cryoprotectants at 16 degrees C. For PG, MeOH and glycerol, 20% solutions gave the best protection at -15 degrees C; whereas a 15% solution of Me2SO, and a 10% solution of EG, gave the best protection at -15 degrees C.     

Usefulness of polyethylene glycol for cryopreservation by vitrification of in vitro-derived bovine blastocysts

A series of five experiments measured the high survival of bovine blastocysts produced in vitro after cryopreservation by vitrification. The vitrification solution (designated VS) contained 40% (v/v) ethylene glycol, 6% (w/v) polyethylene glycol and 0.5 M sucrose in phosphate-buffered saline. Embryos developed in vitro at Days 7 and 8 (Day 0 = insemination day) were exposed in one step to VS for 1 min or two steps with 10% ethylene glycol for 5 min and then VS for 1 min. In both cases, the embryos were finally cryopreserved in liquid nitrogen. After the embryos were warmed rapidly and the VS solution diluted, the survival rates were assessed by monitoring hatching rate in vitro. They were 13.0% for the one-step and 72.7% for the two-step procedures (P < 0.001). When embryos were exposed to individual solutions containing 6% (w/v) of each of 4 macromolecules (polyethylene glycol, BSA, polyvinylpyrrolidone or Ficoll) in the two-step protocol and then cryopreserved, the survival rates were 79.3, 34.8, 41.4 and 57.1%, respectively. After embryos had been exposed to the VS in two steps and then cryopreserved, there were no significant differences in survival rates when the solutions were diluted with or without sucrose. These results indicated that a vitrification solution containing polyethylene glycol can be used for cryopreservation of bovine blastocysts produced in vitro, and that a two-step addition of VS improved the in vitro survival of post-warming embryos. It was also shown to be possible to dilute post-warming embryos directly without the use of sucrose solution.