High ice nucleation temperature of zebrafish embryos: slow-freezing is not an option

Although fish embryos have been used in a number of slow-freezing cryopreservation experiments, they have never been successfully cryopreserved. In part this is because little is known about whether ice forms within the embryo during the slow-freezing dehydration process. Therefore, we examined the temperature of intraembryonic ice formation (T(IIF)) and the temperature of extraembryonic ice formation (T(EIF)), using a cryomicroscope. We used both unmodified zebrafish embryos and those with water channels (aquaporin-3 or AQP3) inserted into their membranes to increase permeability to water and cryoprotectants, examined at 100% epiboly to the 6-somite stage. In these experiments we examined: (1) the spontaneous freezing of (external) solutions; (2) the spontaneous freezing of solutions containing embryos; (3) the effect of preloading the embryos with cryoprotectants on T(IIF); (4) whether preloading the embryos with cryoprotectant helps in survival after nucleating events in the solution; and (5) the damaging effects of extracellular nucleation events versus solution toxicity on the embryos. The solutes alone (embryo medium--EM, sucrose culture medium, 1 M propylene glycol in EM, and 1 M propylene glycol in a sucrose culture medium) froze at -14.9 +/- 1.1, -17.0 +/- 0.3, -17.8 +/- 1.0, and -17.7 +/- 1.4, respectively. There was no difference amongst these means (P > 0.05), thus adding cryoprotectant did not significantly lower the nucleation point. Adding embryos (preloaded with cryoprotectant or not) did not change the basic freezing characteristics of these solutes. In all these experiments, (T(EIF)) equaled (T(IIF)), and there was no difference in the freezing point of the solutions with or without the embryos (P > 0.05). Additionally, there was no difference in the freezing characteristics of embryos with and without aquaporins (P > 0.05). The formation of intraembryonic ice was lethal to the zebrafish embryos in all cases. But this lethal outcome was not related to solution injury effects, because 88-98% of embryos survived when exposed to a higher solute concentration with no ice present. Taken together, these data suggest that slow-freezing is not a suitable option for zebrafish embryos. The mechanism of this high temperature nucleation event in zebrafish embryos is still unknown.     

Effect of cooling rate and partial removal of yolk on the chilling injury in zebrafish (Danio rerio) embryos

High chilling sensitivity is one of the main obstacles to successful cryopreservation of zebrafish embryos. So far the nature of the chilling injury in fish embryos has not been clear. The aim of this study is to investigate the effect of cooling rate and partial removal of yolk on chilling injury in zebrafish embryos. Zebrafish embryos at 64-cell, 50%-epiboly, 6-somite and prim-6 stages were cooled to either 0 degrees C or -5 degrees C at three different cooling rates: slow (0.3 degrees C/min or 1 degree C/min), moderate (30 degrees C/min), and rapid (approximately 300 degrees C/min). After chilling, embryos were warmed in a 26 degrees C water bath, followed by 3-day culturing in EM at 26 +/- 1 degrees C for survival assessment. When embryos were cooled to 0 degrees C for up to 30 min, 64-cell embryos had higher survival after rapid cooling than when they were cooled at a slower rate. When 64-cell embryos were held at -5 degrees C for 1 min, their survival decreased greatly after both slow and rapid cooling. The effect of cooling rate on the survival of 50%-epiboly and 6-somite embryos was not significant after 1 h exposure at 0 degrees C and 1 min exposure at -5 degrees C. However, rapid cooling resulted in significantly lower embryo survival than a cooling rate of 30 degrees C/min or 1 degree C/min after 1 h exposure to 0 degrees C for prim-6 stage or 1 h exposure to -5 degrees C for all stages. Chilling injury in 64-cell embryos appears to be a consequence of exposure time at low temperatures rather than a consequence of rapid cooling. Results also indicate that chilling injury in later stage embryos (50%-epiboly, 6-somite and prim-6) is a consequence of the combination of rapid cooling and exposure time at low temperatures. Dechorionated prim-6 embryos were punctured and about half of yolk was removed. After 24 h culture at 26 +/- 1 degrees C after removal of yolk, the yolk-reduced embryos showed higher embryo survival than did control embryos after rapid cooling to -5 degrees C for 10 to 60 min. Results suggest that cold shock injury after rapid cooling can be mitigated after partial removal of yolk at the prim-6 stage. These findings help us to understand the nature of chilling sensitivity of fish embryos and to develop protocols for their cryopreservation.     

Effects of methanol and developmental arrest on chilling injury in zebrafish (Danio rerio) embryos

Stage-dependent chilling sensitivity has been reported for many species of fish embryos. Most of these studies reveal that developmental stages beyond 50% epiboly are less sensitive to chilling, but the chilling sensitivity accelerates rapidly at subzero temperatures. In this study, the effects of methanol and developmental arrest on chilling injury were studied using zebrafish (Danio rerio) embryos at 64-cell, 50% epiboly, 6-somite, prim-6 and long-bud stages. Embryos were exposed to methanol or anoxic conditions before they were cooled to 0 or -5 degrees C with slow (1 degrees C/min), medium (30 degrees C/min) or fast ( approximately 300 degrees C/min) cooling rates and were held at these temperatures for different time periods. Embryo survival was evaluated in terms of the percentage of treated embryos with normal developmental appearance after 3-day culture. Experiments on the effect of methanol on chilling sensitivity of the embryos showed that the addition of methanol to embryo medium increased embryo survival significantly at all developmental stages and under all cooling conditions. Higher concentration of methanol treatment generally improved embryo survival when embryos were cooled at a fast cooling rate of 300 degrees C/min. Experiments on the effect of developmental arrest on chilling sensitivity of embryos showed that embryos at 50% epiboly and prim-6 stages underwent developmental arrest almost immediately after 15 min oxygen deprivation. After 4h in anoxia, the survival rates of the embryos were not significantly different from their respective aerobic controls. Anoxia and developmental arrest had no effect on the chilling sensitivity of zebrafish embryos.     

Stage-dependent hatching responses of rohu (Labeo rohita) embryos to different concentrations of cryoprotectants and temperatures

Hatching performances of three embryonic stages of postfertilization rohu (Labeo rohita) (9-, 12-, and 15-h) were examined after treatment with various concentrations (0.5-4.5M) of two cryoprotectants (methanol and propylene glycol) supplemented with 0.1M trehalose. Different lengths of storage (1-48 h) and temperature (-4 degrees C to ambient) were studied. Of the three stages of embryonic development, the 12-h stage proved to be the most suitable stage for low temperature storage, showing the highest percentage of hatch out (72+/-2%) with 2.0M methanol and 0.1M trehalose. Methanol was more useful for storage at higher temperatures and propylene glycol at subzero temperatures. The maximum possible duration of effective storage of 12-h embryos was 31h in 2.0M methanol at 0 degrees C. No hatch out was found beyond 31h of storage with all concentrations of methanol at 0 degrees C. The results of interactions was that the optimal concentration of methanol was 3.0M at 4 degrees C, 2.0M at 0 degrees C, and 1.5M at 4 degrees C. Among three embryonic stages 12-h stage showed better results in trehalose treatment than sucrose. Among all concentrations of trehalose tested 0.1M gave the maximal survival rate of the rohu embryos.     

Expression of aquaporin-3 improves the permeability to water and cryoprotectants of immature oocytes in the medaka (Oryzias latipes)

The permeability of the plasma membrane plays a crucial role in the successful cryopreservation of oocytes and embryos. Several efforts have been made to facilitate the movement of water and cryoprotectants across the plasma membrane of fish oocytes/embryos because of their large size. Aquaporin-3 is a water/solute channel that can also transport various cryoprotectants. In this study, we tried to improve the permeability of immature medaka (Oryzias latipes) oocytes to water and cryoprotectants by artificially expressing aquaporin-3. The oocytes were injected with aquaporin-3 cRNA and cultured for 6-7 h. Then, hydraulic conductivity (L(P)) and cryoprotectant permeability (P(S)) were determined from volume changes in a hypertonic sucrose solution and various cryoprotectant solutions, respectively, at 25 degrees C. The L(P) value of the cRNA-injected oocytes was 0.22+/-0.04 microm/min/atm, nearly twice larger than that of intact or water-injected oocytes (0.14+/-0.02 and 0.14+/-0.03 microm/min/atm, respectively). P(S) values of intact oocytes for ethylene glycol, propylene glycol, and DMSO were 1.36+/-0.34, 1.97+/-0.20, and 1.17+/-0.52 x 10(-3) cm/min, respectively. The permeability to glycerol could not be calculated because oocytes remained shrunken in the glycerol solution. On the other hand, cRNA-injected oocytes had significantly higher P(S) values (glycerol, 2.20+/-1.29; ethylene glycol, 2.98+/-0.36; propylene glycol, 3.93+/-1.70; DMSO, 3.11+/-0.74 x 10(-3) cm/min) than intact oocytes. When cRNA-injected oocytes were cultured for 12-14 h, 51% matured to the metaphase II stage, and 43% of the matured oocytes were fertilized and hatched following in vitro fertilization and 14 days of culture. Thus, the permeability of medaka oocytes to water and cryoprotectants was improved by the artificial expression of aquaporin-3, and the oocytes retained the ability to develop to term.     

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.     

Survival of IVF-derived bovine embryos frozen in glycerol or ethylene glycol

Survival of IVF-derived bovine embryos of different ages and stages of development, produced in 2 different co-culture systems and frozen in 2 different cryoprotectants, was investigated. In vitro-derived bovine embryos (n = 5,525) were utilized to study survival following exposure to cryoprotectants and after freezing. Survival of the frozen embryos was based on blastocyst re-expansion 24 h and hatching 72 h after thawing. There was no difference in survival when embryos were exposed to either glycerol (Gly) or ethylene glycol (EG) for 10 or 40 min with the cryoprotectant diluted with or without freezing. In 2 of 3 experiments in which a comparison was possible, more blastocysts frozen in 1.4 M glycerol than in 1.5 M ethylene glycol survived. Addition of 0.25 M sucrose to 1.5 M ethylene glycol in the freezing solution did not improve embryo survival. More blastocysts frozen on Day 7 of in vitro culture survived than those frozen on Day 6 or Day 8. On Days 6, 7 and 8, embryos in the most advanced stage of development survived better than those at less advanced stages. Post-thaw survival did not differ for embryos produced in co-culture with Buffalo Rat Liver (BRL) cells with either Menezo B2 Medium or Tissue Culture Medium 199 and frozen in 1.4 M glycerol.     

Dechorionation as a tool to improve the fish embryo toxicity test (FET) with the zebrafish (Danio rerio)

Prior to hatching, the zebrafish embryo is surrounded by an acellular envelope, the chorion. Despite repeated speculations, it could not be clarified unequivocally whether the chorion represents an effective barrier and, thus, protects the embryo from exposure to distinct chemicals. Potentially, there is a risk of generating false negative results in developmental toxicity studies due to limited permeability of the chorion for some compounds. The simplest way to exclude this is to remove the chorion and expose the “naked” embryo. In the context of ecotoxicity testing, standardized protocols do not exist for fish embryo dechorionation, and survival rates of dechorionated embryos have usually not been subjected to statistical analysis. Since reproducibly high survival rates are of fundamental importance for chemical toxicity assessment, the present study was designed to develop and optimize a dechorionation procedure. With appropriate modifications of the fish embryo test protocol, embryos can be dechorionated at 24 h post-fertilization (hpf) with survival rates of ≥ 90%. However, for fish embryo tests with dechorionated embryos, the standard positive control test substance, 3,4-dichloroaniline, should be replaced by another compound, e.g., acetone, since 3,4-dichloroaniline exerts its effects during the first 24 h of development. Dechorionation of younger stages (< 24 hpf) is generally possible, however with lower survival rates. The effect of dechorionation was demonstrated with the cationic polymer Luviquat HM 552, which is blocked by the chorion non-dechorionated embryos due to its molecular weight of ~ 400,000 Dalton, but becomes strongly toxic after dechorionation.     

Characterization of intracellular ice formation in Drosophila melanogaster embryos

Cryomicroscopy and differential scanning calorimetry (DSC) were used to characterize the incidence of intracellular ice formation (IIF) in 12- to 13-hr-old embryos of Drosophila melanogaster (Oregon-R strain P2) as influenced by the state of the eggcase (untreated, dechorionated, or permeabilized), the composition of the suspending medium (with and without cryoprotectants), and the cooling rate. Untreated eggs underwent IIF over a very narrow temperature range when cooled at 4 or 16 degrees C/min with a median temperature of intracellular ice formation (TIIF50) of -28 degrees C. The freezable water volume of untreated eggs was approximately 5.4 nl as determined by DSC. IIF in dechorionated eggs occurred over a much broader temperature range (-13 to -31 degrees C), but the incidence of IIF increased sharply below -24 degrees C, and the cumulative incidence of IIF at -24 degrees C decreased with cooling rate. In permeabilized eggs without cryoprotectants (CPAs), IIF occurred at much warmer temperatures and over a much wider temperature range than in untreated eggs, and the TIIF50 was cooling rate dependent. At low cooling rates (1 to 2 degrees C/min), TIIF50 increased with cooling rate; at intermediate cooling rates (2 to 16 degrees C/min), TIIF50 decreased with cooling rate. The total incidence of IIF in permeabilized eggs was 54% at 1 degree C/min, and volumetric contraction almost always occurred during cooling. Decreasing the cooling rate to 0.5 degree C/min reduced the incidence of IIF to 43%. At a cooling rate of 4 degrees C/min, ethylene glycol reduced the TIIF50 by about 12 degrees C for each unit increase in molarity of CPA (up to 2.0 M) in the suspending medium. The TIIF50 was cooling rate dependent when embryos were preequilibrated with 1.0 M propylene glycol or ethylene glycol, but was not so in 1.0 M DMSO. For embryos equilibrated in 1.5 M ethylene glycol and then held at -5 degrees C for 1 min before further cooling at 1 degree C/min, the incidence of IIF was decreased to 31%. Increasing the duration of the isothermal hold to 10 min reduced the incidence of IIF to 22% and reduced the volume of freezable water in embryos when intracellular ice formation occurred. If the isothermal hold temperature was -7.5 or -10 degrees C, a 10- to 30-min holding time was required to achieve a comparable reduction in the incidence of IIF.     

Water- and cryoprotectant-permeability of mature and immature oocytes in the medaka (Oryzias latipes)

The permeability of the plasma membrane plays a crucial role in the successful cryopreservation of oocytes/embryos. To identify a stage feasible for the cryopreservation of teleost oocytes, we investigated the permeability to water and various cryoprotectants of medaka (Oryzias latipes) oocytes at the germinal vesicle (GV) and metaphase II (MII) stages. In sucrose solutions, the volume changes were greater in GV oocytes than MII oocytes. Estimated values for osmotically inactive volume were 0.41 for GV oocytes and 0.74 for MII oocytes. Water-permeability (microm/min/atm) at 25 degrees C was higher in GV oocytes (0.13+/-0.01) than MII oocytes (0.06+/-0.01). The permeability of MII oocytes to various cryoprotectants (glycerol, propylene glycol, ethylene glycol, and DMSO) was quite low because the oocytes remained shrunken during 2 h of exposure in the cryoprotectant solutions at 25 degrees C. When the chorion of MII oocytes was removed, the volume change was not affected, except in DMSO solution, where dechorionated oocytes shrunk and then regained their volume slowly; the P(DMSO) value was estimated to be 0.14+/-0.01x10(-3) cm/min. On the other hand, the permeability of GV oocytes to cryoprotectants were markedly high, the P(s) values (x10(-3) cm/min) for propylene glycol, ethylene glycol, and DMSO being 2.21+/-0.29, 1.36+/-0.18, and 1.19+/-0.01, respectively. However, the permeability to glycerol was too low to be estimated, because GV oocytes remained shrunken after 2 h of exposure in glycerol solution. These results suggest that, during maturation, medaka oocytes become less permeable to water and to small neutral solutes, probably by acquiring resistance to hypotonic conditions before being spawned in fresh water. Since such changes would make it difficult to cryopreserve mature oocytes, immature oocytes would be more suitable for the cryopreservation of teleosts.     

Pregnancy rate and survival in culture of in vitro fertilized bovine embryos frozen in various cryoprotectants and thawed using a one-step system

Bovine oocytes surrounded with compact cumulus cells were cultured for 20 to 22 hours (38.5 degrees C, 5% CO(2)) in modified TCM-199 medium supplemented with 5% superovulated cow serum (SCS) and inseminated by in vitro capacitated spermatozoa. Day 7 to 8 embryos were equilibrated for 10 minutes in 1.3 M methyl cellosolve (MC), 1.1 M diethylene glycol (DEG), 1.8 M ethylene glycol (EG), 1.6 M propylene glycol (PG) and 1.1 M 1, 3-butylene glycol (BG) solutions. They were then loaded into 0.25-ml straws, placed into an alcohol bath freezer at 0 degrees C, cooled from 0 degrees C to -6 degrees C at -1 degrees C/minute, seeded, held for 10 minutes, and cooled again at -0.3 degrees C or -0.5 degrees C/minute to -30 degrees C. Straws were then plunged and stored in liquid nitrogen. After thawing in 30 degrees C water, the embryos were rehydrated in TCM-199 medium and then cultured for 48 hours in TCM-199 plus 5% SCS. Embryos were considered viable if they progressed to later developmental stages with good morphology. Some of the embryos frozen in each cryoprotectant were thawed and transferred nonsurgically without removing the cryoprotectant. Hatched embryos survived freezing and one-step dilution as follows: EG (50.0%), MC (53.6%), DEG (56.9%), PG (58.0%) and BG (11.5%). The survival rate of embryos cooled at -0.3 degrees C vs -0.5 degrees C/minute was not significantly different (P>0.05), however, blastocysts hatched most often (P<0.01) in vitro when cooled at a rate of -0.3 degrees C/minute (64.6%, 31 48 ) than at -0.5 degrees C/minute (22.6%, 12 53 ). Pregnancy rates resulting from embryos frozen in the different cryoprotectants were as follows: MC (48%, 10 21 ); DEG (30%, 3 10 ); EG (74%, 20 27 ); and PG (40%, 4 10 ). These results indicate that MC, DEG, EG and PG have utility as cryoprotectants for the freezing and thawing of IVF bovine embryos.     

Overcoming a permeability barrier by microinjecting cryoprotectants into zebrafish embryos (Brachydanio rerio)

The goal of this research was to examine the developmental effects on zebrafish embryos (Brachydanio rerio) when cryoprotectants were directly microinjected into the yolk. Our objectives were to: (i) determine the final concentration of propylene glycol (PG) and dimethyl sulfoxide (Me(2)SO) that the embryos could tolerate without causing teratogenic effects; (ii) determine if the toxicity of Me(2)SO could be reduced by the simultaneous presence of various proportions of amides; and (iii) examine whether this intracellular cryoprotectant incorporation could reduce the cryodamage to the yolk syncytial layer (YSL) after vitrification trials. The rationale for conducting these microinjection experiments was to overcome the permeability barrier of the YSL. Intracellular PG produced better survival than Me(2)SO (P < 0.05). Embryos tolerated both 10- and 30-nl microinjections of PG, yielding final concentrations of 2.3 and 5.0 M within the yolk, resulting in 70 +/- 3 and 35 +/- 4% survival at day 5, respectively. In similar experiments with Me(2)SO, survival was lower than PG at 60 +/- 4 and 14 +/- 4% at 2.4 and 5.2 M. Unlike other cellular systems, the presence of amides, specifically acetamide or formamide, did not reduce the toxicity of Me(2)SO in zebrafish embryos (P > 0.05). During vitrification trials, we estimated a 25% dehydration of the yolk, yielding an effective PG concentration of 5.9 M. However, the incorporation of this vitrifiable concentration of PG was not sufficient to improve the postthaw morphology of the YSL (P > 0.05). Clearly, other factors need to be examined in establishing a successful vitrification protocol for zebrafish embryos.     

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 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.     

Effect of cryoprotectants and their concentration on post-thaw survival and development of expanded mouse blastocysts frozen by a simple rapid-freezing procedure

Experiments were conducted to develop a simple rapid-freezing protocol for expanded mouse blastocyst-stage embryos. The effect of type of cryoprotectant (ethylene glycol and propylene glycol) and its concentrations (4.5, 6.0 and 7.0 mol/L each with 0.5 mol/L sucrose) on morphological survival and development in vitro were studied. The survival and development of embryos frozen with best concentration of each cryoprotectant pre-exposed to either a low concentration (1.5 mol/L with 0.25 mol/L sucrose) of the respective cryoprotectant or ascending concentrations of sucrose were also compared. The in vivo development of embryos frozen with best protocol (pre-exposure to 1.5 mol followed by 7.0 mol ethylene glycol) was compared with nonfrozen embryos. The rate of re-expansion and hatching was influenced by the type and concentration of the cryoprotectant. A significantly higher re-expansion and hatching rate was achieved at 7.0 mol of both cryoprotectants compared with 4.5 and 6.0 mol of the respective cryoprotectants. When comparing 2 cryoprotectants, a higher (P < 0.05) rate of hatching was obtained with ethylene glycol at 7.0 mol compared with a similar concentration of propylene glycol. The highest re-expansion (91%) and hatching (86%) of expanded blastocysts was achieved with pre-exposure of embryos to a low concentration of ethylene glycol followed by freezing in the same cryoprotectant at 7.0 mol. The transfer of embryos frozen using this protocol resulted in the development of live fetuses. The proportion of live fetuses in the pregnant recipients with frozen-thawed embryos were not different from those transferred nonfrozen embryos (49 vs 57%). It may be concluded that simple rapid-freezing with dehydration in ascending sucrose concentrations or pre-equilibration in a low concentration of ethylene glycol or propylene glycol followed by exposure to the respective cryoprotectant at 7.0 mol resulted in high survival and development of expanded blastocysts. Ethylene glycol at 7.0 mol with pre-equilibration is, however, most effective for cryopreservation of this stage in the mouse.     

The effect of internal and external cryoprotectants on zebrafish (Danio rerio) embryos

The study investigated the effects of internal (DMSO, 1,2-propanediol, glycerol, ethylene glycol, methanol, N,N-dimethylacetamide) and external cryoprotectants (glucose, sucrose) on the viability and on morphometric parameters of zebrafish embryos. From the tested internal cryoprotectants, DMSO had the lowest toxicity, followed by 1,2-propanediol and glycerol. The external cryoprotectants were less toxic then the internal ones. Early ontogenetic stages were more sensible to cryoprotectant exposure than advanced stages. Two-step incubation procedures in increasing concentrations of internal and external cryoprotectants were superior to multiple-step exposure procedures. All tested vitrification solutions exceeded the tolerance limit of embryos. The tolerance of zebrafish embryos to cryoprotectants was highly variable in a concentration range causing approximately 50% embryo mortality. The width of the perivitelline space showed significant morphometrical changes due to cryoprotectant exposure. In the germinative tissue non-significant changes occurred. The yolk did not change morphometrically after exposure to internal cryoprotectants and showed no sign of dehydration after exposure to external cryoprotectants. Based on these results the study comes to the following conclusions: as yolk dehydration was impossible and as vitrification solutions were over the tolerance limit it seems unlikely that successful vitrification of zebrafish embryos can be achieved. Under these considerations slow freezing methods would be a better option as lower cryoprotectant concentrations can be used and embryos can be dehydrated during freezing.     

Viability of frozen-thawed bovine IVM/IVF embryos in relation to aging using various cryoprotectants

Bovine IVF embryos developed on Days 7, 8 and 9 were equilibrated with 1.6 M propylene glycol (PG), 1.8 M ethylene glycol (EG), 1.1 M diethylene glycol (DEG) or 1.3 M ethylene glycol monomethyl ether (EME) for 10 to 20 min in modified phosphate buffered saline. (mPBS) supplemented with 10% superovulated cow serum. The embryos were loaded into 0.25-ml plastic straws and were placed directly into a 0 degrees C alcohol bath chamber and held for 2 min. They were cooled from 0 degrees C to -5.5 degrees C at 1 degrees C/min and then seeded, followed by a 10-min holding period at -5.5 degrees C. The straws were then cooled to -30 degrees C at 0.3 degrees C/min before plunging into liquid nitrogen. Embryos were thawed and placed directly into the culture medium and washed 3 times. The survival rates of the Day-9 embryos based on reappearance of blastocoele, expansion, and hatching after 48 h of post-thaw culture were significantly lower (P<0.01) than those of the Day-7 and 8 embryos, in all of the cryoprotectants tested. On the other hand, while the reappearance of blastocoele and expansion of blastocysts after 48 h of post-thaw culture were not significantly different among each cryoprotectant, the percentage of hatching blastocysts were significantly different between DEG and EME (P<0.05), between DEG and EG (P<0.01) and between PG and EG (P<0.05). These findings demonstrate that the age of the embryo (Day 7 and 8) is very important for the successful freezing of IVF bovine embryos. Also, as to the hatching rates, EME and EG are superior as cryoprotectants than the other 2 cryoprotectants tested.     

Preliminary experiments on the cryopreservation of penaeid shrimp (Penaeus japonicus) embryos, nauplii and zoea

To improve availability of penaeid seedstock during periods of high demand, experiments were conducted to determine the feasibility of stockpiling embryos by freezing them. Embryos were screened for developmental stage; cryoprotectants, chilling effects, and freezing regimens were likewise evaluated. Juvenile forms (embryos, nauplii and zoea) of Penaeus japonicus were exposed to various cryoprotectants, including dimethyl sulfoxide, glycerol, methanol, ethylene glycerol and polyethylene glycol 300 under ambient temperature (25 degrees C). Following this bioassay, maximum safe concentrations of each cryoprotectant were tested on the juveniles under chilling to 0 degree C and with 42 freezing regimens. Methanol was found to be relatively nontoxic. Early developmental stages were the most sensitive to chilling. Initial attempts to freeze P. japonicus juveniles were reported. The survival rate of nauplii and zoea treated with 10% methanol in natural sea water (35 ppt salinity) and frozen to -15 degrees C was 85%, and some nauplii and zoea survived freezing to -25 and -196 degrees C. However, no treatment yielded normal nauplii or zoea after freezing.     

Preliminary studies on the vitrification of red sea bream (Pagrus major) embryos

The objective was to identify an appropriate cryoprotectant and protocol for vitrification of red sea bream (Pagrus major) embryos. The toxicity of five single-agent cryoprotectants, dimethyl sulfoxide (DMSO), propylene glycol (PG), ethylene glycol (EG), glycerol (GLY), and methyl alcohol (MeOH), as well as nine cryoprotectant mixtures, were investigated by comparing post-thaw hatching rates. Two vitrifying protocols, a straw method and a solid surface vitrification method (copper floating over liquid nitrogen), were evaluated on the basis of post-thaw embryo morphology. Exposure to single-agent cryoprotectants (10% concentration for 15 min) was not toxic to embryos, whereas for higher concentrations (20 and 30%) and a longer duration of exposure (30 min), DMSO and PG were better tolerated than the other cryoprotectants. Among nine cryoprotectant mixtures, the combination of 20% DMSO+10% PG+10% MeOH had the lowest toxicity after exposure for 10 min or 15 min. High percentages of morphologically intact embryos, 50.6+/-16.7% (mean+/-S.D.) and 77.8+/-15.5%, were achieved by the straw vitrifying method (20.5% DMSO+15.5% acetamide+10% PG, thawing at 43 degrees C and washing in 0.5M sucrose solution for 5 min) and by the solid surface vitrification method (40% GLY, thawing at 22 degrees C and washing in 0.5M sucrose solution for 5 min). After thawing, morphological changes in the degenerated embryos included shrunken yolks and ruptured chorions. Furthermore, thawed embryos that were morphologically intact did not consistently survive incubation.     

Investigation of cryoprotectant toxicity to porcine embryos

The objective of this study was to examine the potential toxicity of sucrose (Experiment 1) and of various cryoprotectants (Experiment 2) to porcine preimplantation embryos. In Experiment 1, 65 embryos, ranging from compact morulae to hatched blastocysts, were allocated within donor female across 5 concentrations of sucrose (0, 0.25, 0.50, 1.0, 2.0 M) to determine the highest concentration that would not inhibit subsequent embryo development. After a 48-h post-treatment culture period, the embryos were stained and cell nuclei were counted. The concentration of sucrose affected embryo development (P < 0.001) and embryo quality (P < 0.001). Embryos placed into 2.0 M sucrose exhibited poorer development and quality than embryos at the lower 4 concentrations, which were not different from one another. In Experiment 2, 182 embryos of the same developmental stages as in Experiment 1 were collected from 16 donors. Embryos were allotted within donor female to 2 of the 5 concentrations (10, 20, 30, 40, or 50%) of each of 3 cryoprotectants (ethylene glycol, propylene glycol, glycerol). After a 30-sec exposure to a cryoprotectant, the embryos were cultured and stained as in Experiment 1. As the concentration of an individual cryoprotectant increased beyond 30%, embryo development decreased. Embryos exposed to glycerol or propylene glycol exhibited poorer development than did embryos placed into ethylene glycol, especially at concentrations of 40% or higher.