Potential of hypertonic medium treatment for embryo micromanipulation: II. Assessment of nuclear transplantation methodology, isolation, subzona insertion, and electrofusion of blastomeres to intact or functionally enucleated oocytes in rabbits

The objective of this research was to study efficiency of embryo development following transfer of blastomeres into the perivitelline space of oocytes. Single blastomeres from 8-, 16-, and 32-cell embryos were obtained following mucin coat and zona pellucida removal by combined treatments with pronase and acidic phosphate-buffered saline (PBS, pH = 2.5). Blastomeres were separated by pipetting with a fire-polished micropipette following incubation in Ca+(+)-free PBS for 15 min at 39 degrees C. This procedure resulted in over 97% blastomere separation. For ease of blastomere insertion, oocytes were placed in droplets of 0.5 M sucrose in PBS (SPBS) during micromanipulation. To functionally enucleate oocytes some were stained with Hoechst 33342 DNA stain and irradiated. A single 8- or 16-cell blastomere was aspirated into an injection pipette (35 microns or 25 microns at the tip, respectively) and inserted into the perivitelline space of an irradiated or non-irradiated oocyte, but not fused with the oocyte. This micromanipulation procedure did not affect development of individual blastomeres into blastocysts or trophectoderm vesicles when compared with cultured control single blastomeres (P greater than .05). When the inserted blastomere was induced to fuse with an intact non-irradiated oocyte under an electric field, 56-57% were fused and 39-45% of the fused and activated oocytes developed to morulae or blastocysts. When an inserted blastomere (from 8-32-cell embryos) was induced to fuse with a functionally enucleated oocyte treated by Hoechst 33342 staining, followed by washing and UV-light irradiation, 63-66% of them were fused, but only 15-22% developed to the morula or blastocyst stage. This research demonstrated that the use of hypertonic medium treated oocytes greatly improved the ease and success rate of blastomere subzona insertion, but the value of functionally enucleated oocytes as recipient cells for nuclear transfer requires further investigation.     

Estimates of mouse oviductal fluid tonicity based on osmotic responses of embryos

Zygotes and early cleavage-stage embryos are very sensitive to increased osmolality in vitro, although the tonicity of their in vivo environment, oviductal fluid, is unknown. A preference for low osmolality in vitro might imply similar conditions in vivo or be specific to culture. Previous electron probe x-ray microanalysis measurements of total ion content predicted oviductal fluid osmolalities of 310-360 mOs/kg, higher than osmolalities tolerated by mouse zygotes in vitro. However, such indirect estimates may not reflect the tonicity experienced by embryos. We have now used embryos themselves as osmosensors to determine the tonicity of mouse oviductal fluid. In one method, we measured the mean volume of zygotes in undiluted oviductal fluid and compared this to the mean volumes measured for zygotes in media spanning a range of osmolalities. The osmolality corresponding to the measured mean volume in oviductal fluid was taken to be isotonic. In another, independent method, the sizes of zygotes and two-cell embryos were measured as a function of time beginning immediately after removal from oviducts. The osmolality in which the embryos neither swelled nor shrank was taken to be isotonic. Both methods yielded approximately the same range for the tonicity of oviductal fluid: around 290-300 mOs/kg.     

Ontogeny of hypertonic preabsorptive inhibitory control of intake in neonatal rats

The ontogenetic development of postingestive inhibitory control of ingestion by the osmotic load of a preload was examined in rats. On postnatal days 6 (P6) and 12 (P12), pups were deprived for either 6 or 24 h. Gastric preloads (5% body wt) of water, mannitol (a sugar alcohol that is not absorbed) in six concentrations [from 0.125 M (hypotonic) to 1.0 M (hypertonic)], or sham preloads were administered 5 min before a 30-min intake test. Compared with sham treatment, isotonic mannitol (0.25 M), a probe of volumetric control, significantly reduced intake on P12, but not on P6. Compared with isotonic mannitol, the three highest hypertonic concentrations (0.5, 0.66, and 1.0 M) significantly decreased intake on P12, at both levels of deprivation. On P6, 0.66 and 1.0 M mannitol reduced intake after 24 h, but not after 6 h, of deprivation. Thus, on P6, the hypertonic control was detectable only after prolonged deprivation and the volumetric control was not present. On P12, both controls were observed and the hypertonic control was more potent than on P6.     

The effect of high concentrations of cryoprotectants on the passage of bovine viral diarrhea virus through the zona pellucida of in vitro fertilized embryos.

The effect of high concentrations of cryoprotectants on the passage of bovine viral diarrhea virus (BVDV) through the zona pellucida (ZP) of intact bovine embryos during the pre-freezing step of cryopreservation was investigated in a series of experiments. In vitro fertilized (IVF) embryos at the blastocyst stage were exposed to 10(6) TCID50 BVDV (non-cytopathic NY-1 strain) in a 30% suspension of either ethylene glycol, glycerol, DMSO, or 2 M sucrose in physiological saline for 10 min at 20 degrees C. Subsequently, the embryos were washed free of residual unbound viral particles, and the ZP of some embryos were removed by micromanipulation. Groups of ZP-intact embryos, ZP-free embryonic cells and their respective ZP were then tested separately for the presence of virus. The infectious virus was detected in association with 81% (17/21) of samples containing non-micromanipulated ZP-intact embryos which were exposed to the virus and cryoprotectants and then washed 10 times and in 83% (43/53) of the samples containing only ZP from micromanipulated embryos (P > 0.05). The virus was not found in the samples containing the corresponding embryonic cells of embryos exposed previously to the virus and cryoprotectants. It was concluded that the transfer of embryos from the isotonic PBS solution into a highly hypertonic cryoprotectant solution did not cause the passage of BVDV through ZP and its entry to embryonic cells.     

Cryomicroscopic observations of cattle embryos during freezing and thawing

A cryomicroscope was used to observe changes in the appearance of day 6 1 2 to 7 1 2 cattle embryos during cooling and warming in 1.4M glycerol/PBS. Embryos were cooled at various rates between 0.2 and 25 degrees C/min to temperatures between -25 and -60 degrees C and then cooled rapidly ( approximately 250 degrees C/min) to temperatures below -140 degrees C. The volume of the embryos calculated from the cross-sectional area during slow cooling decreased at -25 degrees C to about 50% of the isotonic volume. Fracture planes could be observed in the extracellular ice matrix surrounding the embryos after rapid cooling to approximately -140 degrees C. The fracture planes often touched the zona pellucida and sometimes caused cracks in the zona. Cracks in the zona pellucida were observed more often after rapid cooling from temperatures between -20 to -35 degrees C (9 13 ) than from temperatures between -36 to -60 degrees C (2 7 ). When embryos were warmed rapidly ( approximately 250 degrees C/min) from temperatures below -140 degrees C, no change was observed in the appearance of either the embryo or its surroundings except the melting of the extracellular ice. However, when embryos were warmed slowly (2 or 5 degrees C/min), a series of events was observed; first, at approximately -70 degrees C the cytoplasm and the extracellular space gradually darkened and reached maximum darkness at approximately -55 degrees C. Then, on continued slow warming, the dark material gradually disappeared and finally the large extracellular ice crystals melted.     

Quantification of deep and superficial sensibility in saline-induced muscle pain-a psychophysical study

The aim of the present study was to study the sensibility in the area of saline-induced muscle pain. In three experiments, ten subjects were exposed to computer-controlled infusion of 0.5 ml isotonic (0.9%) or hypertonic (9%) saline into the anterior tibial muscle. The pain intensity was assessed on a visual analogue scale (VAS). The pain threshold (PT) to pressure and electrical stimulation in muscle and subcutaneous tissues was determined. Three experiments were performed in which infusion of hypertonic saline produced significantly higher VAS scores than isotonic saline. In all three experiments, there was no significant difference in PT obtained after infusion of isotonic saline compared with infusion of hypertonic saline. In experiment 1, the PT was determined at the infusion site and 4 cm from the infusion site. At the infusion site, the pressure PT decreased (- 19 2%) 1, 3, 5, 7 and 9 min after infusion of isotonic and hypertonic saline, but remained unchanged 4 cm from the infusion site. The intramuscular electrical PT at the infusion site and 4 cm from the infusion site increased significantly (29 6%) 5, 7 and 9 min after saline infusion. In experiment 2, the pressure PT and the intramuscular electrical PT were recorded after two infusions of saline separated by 1 day. The day after the first infusion, the pressure PT was decreased compared with the PT before the first infusion, but the electrical PT was not affected. Moreover, the hypertonic saline infusion given on the second day produced significantly higher (130 50%) VAS scores than the infusion given on the first day. In experiment 3, the PT was determined in the subcutaneous tissue, but no significant effects of saline infusion were found. The present placebo-controlled experiments failed to show muscular or subcutaneous hyperalgesia after saline-induced muscle pain per se.     

Fusion and development rates of single blastomere pairs of mouse two- and four-cell embryos using the electrofusion method

The present study was undertaken to find suitable conditions for blastomere fusion of mouse two- and four-cell embryos using the electrofusion method to simplify the nuclear transfer procedure. Single blastomeres of ICR and F1 (C57BL/6J x CBA/N) two-cell embryos or ICR four-cell embryos and F1 two-cell embryos were paired and treated with electric stimulus under different fusion conditions. Two hours after electrofusion treatment, the fused blastomere pairs were encapsulated in alginate gel and cultured for 96 hours to observe their developmental potential. When the single blastomere pairs of two-cell embryos were exposed to electric pulses of 1.0, 1.5 and 2.0 kV/cm for 30, 60 and 90 mu sec, high fusion rates were obtained (84.6 to 100%). However, when two-cell blastomere were paired with four-cell blastomere and then treated under the same conditions, the fusion rates (27.5 to 87.5%) were lower than that of single blastomere pairs of two-cell embryos regardless of the duration and strength of the d.c. pulses. The blastocyst developmental rate after in vitro culture of the fused blastomere pairs of two-cell embryos using the above electrofusion conditions was high (81.8 to 100%). Lower blastocyst developmental rates were obtained on the fused blastomere pairs of two- and four-cell embryos (46.4 to 76.2%). Based on the results of this study, a pulse duration of 60 mu sec and a pulse strength of 1.0kV/cm were the most suitable conditions for single blastomere pair fusion of two-cell or two- and four-cell embryos. The study further showed that alginate gel is a good substitute for zonae pellucidae for encapsulating zona-free embryos.     

Quick freezing of rat embryos

Quick freezing of rat morulae and blastocysts was attempted after they were dehydrated at room temperature. Combined solutions of 2.8 M glycerol and 0.125, 0.25, 0.50 and 1.0 M sucrose in phosphate buffered saline + 20% steer serum were compared. Survival rates (expanding blastocysts 15 h after thawing) were 42.1, 79.4, 87.5 and 16.7%, respectively (P<0.01). Freezing procedures consisted of either a direct plunge into liquid nitrogen (48.8%), holding for 5 min in the neck of a liquid nitrogen container or holding the samples for 60 min at -30 degrees C before insertion into liquid nitrogen. The direct plunge method resulted in a lower survival rate than either the 5- or the 60-min treatments (48.8% vs 76.9% and 77.6%, respectively). After thawing, dilution at room temperature in sucrose solutions of 0.25, 0.50 and 1.0 M gave survival rates of 80.0, 90.6 and 69.4%, respectively (NS). If diluted directly in PBS + 20% steer serum, 86.8% of embryos survived at +37 degrees C vs 0% at 0 degrees C (P<0.01).     

Vitrification of early-stage bovine and equine embryos

The objectives of this study were to: (1) determine an optimal method and stage of development for vitrification of bovine zygotes or early embryos; and (2) use the optimal procedure for bovine embryos to establish equine pregnancies after vitrification and warming of early embryos. Initially, bovine embryos produced by in-vitro fertilization (IVF) were frozen and vitrified in 0.25 mL straws with minimal success. A subsequent experiment was done using two vitrification methods and super open pulled straws (OPS) with 1- or 8-cell bovine embryos. In Method 1 (EG-O), embryos were exposed to 1.5 M ethylene glycol (EG) for 5 min, 7 M ethylene glycol and 0.6 M galactose for 30 s, loaded in an OPS, and plunged into liquid nitrogen. In Method 2 (EG-DMSO), embryos were exposed to 1.1 M ethylene glycol and 1.1 M dimethyl sulfoxide (DMSO) for 3 min, 2.5 M ethylene glycol, 2.5 M DMSO and 0.5 M galactose for 30 s, and loaded and plunged as for EG-O. Cryoprotectants were removed after warming in three steps. One- and eight-cell bovine embryos were cultured for 7 and 4.5 d, respectively, after warming, and control embryos were cultured without vitrification. Cleavage rates of 1-cell embryos were similar (P > 0.05) for vitrified and control embryos, although the blastocyst rates for EG-O and control embryos were similar and higher (P < 0.05) than for EG-DMSO. The blastocyst rate of 8-cell embryos was higher (P < 0.05) for EG-O than EG-DMSO. Therefore, EG-O was used to cryopreserve equine embryos. Equine oocytes were obtained from preovulatory follicles. After ICSI, injected oocytes were cultured for 1-3 d. Two- to eight-cell embryos were vitrified, warmed and transferred into recipient's oviducts. The pregnancy rate on Day 20 was 62% (5/8) for equine embryos after vitrification and warming. In summary, a successful method was established for vitrification of early-stage bovine embryos, and this method was used to establish equine pregnancies after vitrification and warming of 2- to 8-cell embryos produced by ICSI.     

Effect of equilibration period on the viability of frozen-thawed mouse morulae after rapid freezing

Mouse morulae were frozen with 1.5-4.0 M glycerol + 0.25 M lactose solution by direct plunging into liquid nitrogen vapor 0.5-30 min after equilibration at room temperature. After thawing, embryos were cultured in vitro, and the highest survival rates were obtained after exposure for 3 min at 3.0 and 4.0 M and for 5 min at 1.5 and 2.0 M glycerol levels. Significant reductions in the survival rates (P less than 0.05) were observed when equilibration periods were extended for 3-5 min at 3.0 and 4.0 M and for 5-10 min at 1.5 and 2.0 M glycerol levels. These results clearly demonstrate that the equilibration time of embryos in glycerol-lactose mixture is one of the most important factors in the present rapid freezing conditions. To clarify the factors that lower embryo viability after prolonged equilibration, we performed further experiments on the effects of exposure to glycerol-lactose mixture on the developmental potential of embryos without freezing and on the volume changes of embryos during the exposure to glycerol solution with or without lactose. It was suggested that the detrimental effects of prolonged equilibration are due not only to the toxicity and osmotic injury of higher concentrations of cryoprotectant solution but also to the influx of water into embryonic cells caused by the hypotonic salt concentration of the extracellular (freezing) solution.     

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.     

Vitrification of in vitro cultured rabbit morulae

In the present work, we attempt to establish an efficient vitrification procedure for 32-cell rabbit embryos obtained in vitro. In experiment 1, both the effect of the composition of the vitrification solutions and the cryoprotectant addition (either in one or two steps) were studied. For one-step addition, straws with embryos in the final vitrification solution (total time 60s) were plunged into liquid nitrogen. For two-step addition, previously embryos were 2 min pre-equilibrated in 0.5 ml of (1:1) PBS plus 20% FCS: vitrification solution without sucrose. Different solutions of cryoprotectants were compared: 25 vol.% ethylene glycol supplemented with 0.25 M sucrose (25EG+S) and 20% ethylene glycol plus 20% dimethyl sulfoxide, alone (20EG+20DMSO-S) or supplemented with 0.25 M sucrose (20EG+20DMSO+S). Six percent (30/487) of the total of 32-cell embryos obtained by in vitro culture in each experimental session was slow-frozen by a classical method as a technical efficiency control. Only 30% slow-frozen embryos reached blastocyst stage. Significant differences in embryo development were detected between the one-step (25EG+S) and two-step (25EG+S) groups and the one-step (20EG-20DMSO+S) and two-step (20EG-20DMSO-S) groups (0-6% versus 36-50%, respectively). Consequently, in the following experiments only these two vitrification procedures were used. In experiment 2, we attempted to substitute the use of PBS by HEPES-buffered Ham's F-10 (h-CM) in all cryoprotective solutions or media. When h-CM was used, a significant reduction in the in vitro embryo development was observed when the HEPES-buffered groups were compared with one-step (20EG-20DMSO+S) group in s-PBS (35-45% versus 73%). In experiment 3, the one-step (20EG+20DMSO+S) and two-step (20EG+20DMSO-S) procedures were assayed using two FCS levels (20 and 40%) in the PBS-based media. Relative to in vitro development, the highest rates were reached with one step (20EG-20DMSO+S), using PBS plus 20% FCS, which was different from two steps (20EG-20DMSO-S), regardless of percentage of FCS in the PBS-based media (81% versus 41-45%; P<0.05). In conclusion, we propose either the one step (20EG-20DMSO+S) or two steps (20EG-20DMSO-S) prepared in PBS plus 20% serum for use in future works.     

Sucrose dilution of glycerol from mouse embryos frozen rapidly in liquid nitrogen vapour

The toxic effects of sucrose and the conditions of in-straw glycerol removal after freezing and thawing were studied using Day-3 mouse embryos. At 20 degrees C, exposure to less than or equal to 1.0 M-sucrose for periods up to 30 min had no adverse effects on freshly collected embryos. At 25 and 36 degrees C, however, greater than or equal to 1.0 M-sucrose significantly reduced the developmental potential (P less than 0.001). In the freezing experiments the embryos were placed in 0.5 ml straws containing 40 microliters freezing medium separated by an air bubble from 440 microliters sucrose solution. The straws were frozen rapidly in the vapour about 1 cm above the surface of liquid nitrogen. The post-thaw viability was substantially better after sucrose dilution at 20 degrees C than at 36 degrees C. Mixing the freezing medium with the sucrose diluent immediately after thawing further improved the rate of survival relative to mixing just before freezing (P less than 0.001). The best survival was obtained when the freezing medium contained 3.0 M-glycerol + 0.25 M-sucrose; it was mixed with the diluent after thawing and the glycerol was removed at 20 degrees C. Under such conditions the sucrose concentration in the diluent had no significant effect on the rate of development (0.5 M, 69%; 1.0 M, 73%; 1.5 M, 64%). The results show that during sucrose dilution the temperature should be strictly controlled and suggest that intracellular and extracellular concentrations of glycerol are important in the cryoprotection of embryos.     

Immunolocalization of PIP aquaporins in protoplasts from the suspension culture of sugar beet mesophyll under isoosmotic conditions and osmotic stress

Protoplasts from the suspension culture of sugar beet (Beta vulgaris L.) mesophyll were found to change their volume in response to short-term osmotic stress. When the sorbitol concentration in the external medium was increased 1.5-fold (from 0.4 to 0.6 M) or decreased from 0.4 to 0.25 M, the volume of protoplasts decreased and increased, respectively, by 55–60%. These changes started immediately after the shift in osmoticum concentration and completed within 1–3 min. In the presence of an endocytosis marker FM1-43, its fluorescence increased conspicuously after replacement of isotonic medium with the hypotonic solution but did not change after the substitution with hypertonic medium. At the same time, the hypertonic shrinkage of protoplasts was accompanied by accumulation of fluorescent material in the periplasmic space. The western blot analysis with the use of immune serum for conservative sequence of PIP-type aquaporins revealed their presence in the plasmalemma and intracellular membranes. This conclusion was confirmed by indirect immunofluorescence microscopy: the membrane-bound secondary antibodies labeled with a fluorescent probe Alexa-Fluor 488 were distributed comparatively uniformly on the boundary between the plasmalemma and the protoplast internal compartment. As evident from micrographs of protoplasts exposed to the hypotonic treatment, the fluorescence was smoothly distributed over the plasmalemma after protoplast swelling but its intensity was not so bright. The protoplast shrinkage during the hypertonic treatment resulted in heterogeneous alternate distribution of fluorescent and transparent plasmalemma regions, the fluorescence of stained regions being very intense. The results are interpreted as the evidence that the short-term osmotic stress activates exo-and endocytosis. The migrating regions of the plasmalemma were depleted of PIP-type aquaporins; hence, the induction of osmotic stress has no effect on the amount of this type aquaporins in the plasma membrane.     

Effect of 1,2-propanediol versus 1,2-ethanediol on subsequent oocyte maturation, spindle integrity, fertilization, and embryo development in vitro in the domestic cat

This study assessed the impact of various cryoprotectant (CPA) exposures on nuclear and cytoplasmic maturation in the immature cat oocyte as a prerequisite to formulating a successful cryopreservation protocol. In experiment 1, immature oocytes were exposed to 0, 0.75, 1.5, or 3.0 M of 1,2-propanediol (PrOH) or 1,2-ethanediol (EG) at room temperature (25 degrees C) or 0 degrees C for 30 min. After CPA removal and in vitro maturation, percentage of oocytes reaching metaphase II (MII) was reduced after exposure to 3.0 M PrOH at 0 degrees C or 3.0 M EG at both temperatures. All CPA exposures increased MII spindle abnormalities compared to control, except 1.5 M PrOH at 25 degrees C. In experiments 2 and 3, immature oocytes were exposed to CPA conditions yielding optimal nuclear maturation that either had caused spindle damage (0.75 M PrOH, 1.5 M EG, and 3.0 M PrOH at 25 degrees C) or not (1.5 M PrOH at 25 degrees C). After maturation and insemination in vitro, oocytes were cultured for 7 days to assess treatment influence on developmental competence. CPA exposure did not affect fertilization, but the high incidence of MII spindle abnormalities resulted in a low percentage of cleaved embryos. Blastocyst formation and quality were influenced by both CPA types (EG was more detrimental than PrOH) and concentration (3.0 M was more detrimental than 1.5 M). Overall, cat oocytes appear to be highly sensitive to CPA except after exposure to 1.5 M PrOH at 25 degrees C, a treatment that still allowed approximately 60% of the oocytes to reach MII and approximately 20% to form blastocysts.     

Cryopreservation of murine embryos with trehalose and glycerol

Several concentrations of trehalose (0.0, 0.04, 0.1, 0.25 M) in combination with three concentrations of glycerol (1.0, 1.5, 2.0 M) were evaluated for the cryopreservation of murine embryos. Embryos were transferred through increasing concentrations of glycerol in Dulbecco's phosphate-buffered saline with 10% fetal calf serum (PBS + FCS) to reach the final glycerol concentrations. They were then randomly assigned to one of the concentrations of trehalose. A total of 506 morulae were packaged individually in 0.25-ml plastic straws and cooled from ambient temperature at 1.0 degrees C/min in a programmable methanol freezer. Embryos were seeded at -7 degrees C and then cooled to -25 degrees C at 0.3 degrees C/min before being plunged into liquid nitrogen. After thawing and a one-step dilution of glycerol, embryos were cultured for 48 hr and viability was determined by blastocoel formation. Highest viability (70.0%) after 48 hr in culture was obtained for embryos frozen in 1.5 M glycerol plus 0.10 M trehalose as compared to 31% viability for embryos frozen with glycerol alone. These observations suggest that trehalose can be used in combination with glycerol as a cryoprotectant and that a high rate of viability can be achieved after a one-step dilution of the cryoprotectants.     

In vitro assessment of a direct transfer vitrification procedure for bovine embryos

We developed a simple vitrification technique for bovine embryos that could permit direct transfer. Embryos were produced in-vitro by standard procedures. The base medium for cryopreservation was a chemically defined medium similar to SOF + 25 mM Hepes and 0.25% fatty acid free bovine serum albumin (FAF-BSA) (HCDM2). In experiment 1, embryos were first exposed to 3.5M ethylene glycol (V1) for 1, 2 or 3 min at room temperature (20-24 degrees C), and then moved to 7 M ethylene glycol (V2) at 4 or 20-24 degrees C and loaded in 0.25-mL straws. After 45 s in 7 M ethylene glycol, straws were placed in liquid nitrogen. Embryos that were loaded at 20-24 degrees C had higher survival rates than those loaded at 4 degrees C (P<0.05). Exposure for 1 min was best for morulae, while 3 min was best for blastocysts. In experiment 2, blastocysts were handled at 24 degrees C and exposed to two concentrations of ethylene glycol in V1 (3.5 or 5 M) followed by V2 as in experiment 1, two warming temperatures (20 or 37 degrees C) and two post-warming holding times until culture (5 or 15 min). Exposure to 5 M ethylene glycol and warming at 37 degrees C was the optimal combination of procedures, and embryos survived well after 15 min in straws if warmed at 37 degrees C. In experiment 3, ethylene glycol concentration (3, 4 or 5 M) and exposure time (0.5 or 1 min) during two-step addition of cryoprotectant were studied for bovine morulae. In experiment 4, morulae were exposed to V2 for 30 or 45 s in HCDM2 or Vigro holding medium and then held in 22-24 degrees C air or 37 degrees C water post-warming. Experiment 5 was like experiment 4 except blastocysts were used. Overall survival rates of blastocysts in experiment 5 averaged 80% of non-vitrified controls after 48 h culture. The survival rates with in vitro-produced morulae in experiments 1, 3 and 4 were unacceptable. Vitrification solutions based on Vigro tended to result in higher survival than HCDM2 for blastocysts, but not morulae. In experiment 6, the survival rate in vitro of in vivo-produced morulae and blastocysts after two-step vitrification was nearly 100%. Our vitrification technique was very effective for in vitro produced blastocysts, but not for in vitro-produced morulae.     

Osmotic tolerance and freezability of isolated caprine early-staged follicles

Isolated caprine early-staged follicles were submitted to osmotic tolerance tests in the presence of sucrose, ethylene glycol (EG), or NaCl solutions and were exposed to and cryopreserved (by slow or rapid cooling) in MEM alone or MEM supplemented with sucrose, EG (1.0 or 4.0 M), or both. When follicles were exposed to 1.5 M NaCl, only 2% of the follicles were viable, whereas 87% of the follicles were viable after exposure to 4.0 M EG. Regarding exposure time, the highest percentage of viable follicles was obtained when follicles were exposed for 10 min to 1.0 M EG + 0.5 M sucrose; exposure for 60 s to 4.0 M EG + 0.5 M sucrose also maintained high percentage viability in follicles. Slow cooling in the presence of 1.0 M EG + 0.5 M sucrose (75%) or rapid cooling in the presence of 4.0 M EG + 0.5 M sucrose (71%) resulted in a significantly higher proportion of viable follicles than all other treatments (P < 0.05). A 24-h culture of frozen-thawed follicles was used to assess survival; only slow-frozen follicles showed viability rates similar to control follicles (64% vs. 69% respectively; P > 0.05). Interestingly, the percentage of viable rapid-cooled follicles (59%) was similar to that obtained after in vitro culture of conventional slow-cooled follicles but was significantly lower than that in controls. Thus, in addition to determining improved procedures for the exposure of follicles to EG and sucrose before and after freezing of caprine early-staged follicles, we report the development of rapid- and slow-cooling protocols.     

Development and viability of frozen-thawed cattle embryos

Embryos recovered 7 to 8 days after estrus were frozen from -7 to -30 degrees C at 0.3 degrees C/min, from -30 to -33 degrees C at 0.1 degrees C/min, and then plunged into liquid nitrogen. They were thawed in a 25 degrees C waterbath. In a preliminary study, 15 of 18 embryos continued to develop during the 24-hour culture post-thaw in either Ham's F-10 or modified Dulbecco's phosphate buffered saline (PBS). In the main study, 5 of 20 embryos developed to 60-day pregnancies when embryos were transferred within 5 hours after thawing. The incidence of extended estrous cycles (pregnancy or presumed embryonic mortality) was 10 of 14, when the zona pellucida was intact after thawing, and 0 of 6, when it was ruptured or absent (P<.05). Embryos cultured in PBS tended to develop more readily than those in Ham's F-10 (15 of 20 vs 9 of 20, respectively, P reverse similar.1). Quality of the embryos, at recovery from the donor and after thawing, affected development in culture (19 of 27 embryos excellent at recovery developed vs 5 of 13 poor to very good, P reverse similar.1; 23 of 33 embryos good to excellent after thawing developed vs 1 of 7 poor, P<.05). The proportion of pyknotic nuclei in embryos which were cultured ranged from 18 to 100%. The pregnancy rate from embryos which were cultured was low (2 of 20). Thirty percent of frozen and thawed embryos had damaged zonae pellucidae. The study showed that: the pregnancy rate from frozen embryos was approximately half that achieved with unfrozen embryos; culturing embryos for 24 hours before transfer was not beneficial; the PBS culture system appears to be the system of choice for assessing embryo viability in vitro .