Effect of dimethyl sulfoxide and protein concentration on the viability of two-cell mouse embryos frozen with a rapid freezing technique

Two-cell mouse embryos were frozen by direct plunging into liquid nitrogen after a 3-min exposure to solutions containing 0.25 M sucrose with 1.5, 3, or 4.5 M dimethyl sulfoxide (Me2SO), and 0, 4, 8, 16, or 32 mg/ml bovine serum albumin (BSA). In the absence of BSA, significantly more embryos were lost or damaged during freezing and thawing. Increasing the BSA concentration from 4 to 32 mg/ml had no significant effect on subsequent embryo viability in vivo or in vitro. Blastocyst formation in vitro was greater than 90% in embryos exposed to the cryoprotective solutions only. Although development to blastocysts was not significantly different to nonfrozen controls in most groups frozen in 3 and 4.5 M Me2SO (up to 92% blastocysts), it was significantly reduced when embryos were frozen in 1.5 M Me2SO (up to 65% blastocysts). The development to fetuses of embryos frozen in 3 M Me2SO (64 to 74% fetuses) was not significantly different from nonfrozen controls (68 to 79% fetuses) or embryos frozen by a conventional slow cooling method (70%). Frozen thawed two-cell embryos developed into normal adults which were able to reproduce normally. We conclude that this freezing method can efficiently cryopreserve early cleavage stage mouse embryos.     

Studies on replacing most of the penetrating cryoprotectant by polymers for embryo cryopreservation.

Solutions used for vitrification or rapid cooling of embryos usually contain high concentrations of penetrating cryoprotectants. At these concentrations embryos can tolerate the penetrating cryoprotectants for only short periods of time without damage. This study designed and tested cryoprotectant solutions that combined high polymer concentrations with low penetrating cryoprotectant concentrations. Mouse 2-cell embryo development was not compromised by up to 15-min exposure to 30 wt% solutions of the polymers Ficoll 70,000 MW or dextran 69,000 MW at room temperature. However, our batches of polyvinylpyrrolidone (PVP) 10,000 and PVP 40,000 were embryo-toxic even after extensive dialysis against Milli-Q water. As both Ficoll and dextran contribute to a solution's physical vitrification properties, we formulated vitrifying solutions containing only 11 to 27 wt% ethylene glycol (EG) by including 34 to 49 wt% polymers (27 wt% EG + 34 wt% Ficoll, 27 wt% EG + 34 wt% dextran, 16 wt% EG + 39 wt% Ficoll, or 11 wt% EG + 49 wt% Ficoll, in phosphate-buffered saline (PBS)). Novel solutions were designed for 0.25 ml straw as a viscous matrix for encapsulation of embryos. These yielded high rates of development of 2-cell mouse embryos after rapid cooling and warming (> or = 96% expanded blastocysts in vitro and > or = 62% viable fetuses as assessed on day 15 of gestation in vivo) in all tested solutions. All control 2-cell embryos formed expanded blastocysts in vitro and 78% formed fetuses in vivo. Comparable results were obtained with both 4-cell and 8- to 16-cell mouse embryos. The lower toxicity of Ficoll and dextran may explain why these new solutions gave better results than had previously been reported for solutions containing 7.5% PVP and low concentrations of EG (2 M).     

Some factors affecting the viability of mouse and cattle embryos frozen to −40°C before transfer to liquid nitrogen

A total of 1161 8- to 16-cell mouse embryos and 31 cattle early morulae and late blastocysts were frozen to ?40°C before transfer to liquid nitrogen. After thawing, mouse embryo viability was determined by in vitro development to the blastocyst stage and cattle embryo viability by both in vivo and in vitro development.Using glycerol as the cryoprotective agent, 88% of the mouse embryos developed to the blastocyst stage: thawing at 45 and 360° C/min gave the best results (88.8 and 84.8%, respectively). In another test with holding times at ?40°C of up to 60 min, about 70% of embryos developed to blastocysts with holding time 30–60 min.In cattle, 11 embryos frozen in DMSO and thawed at 360°C/min were transplanted to eight recipients. Four pregnancies (six fetuses) resulted. Thawing rates of 200 and 360°C/min resulted in the best in vitro development of cattle embryos.     

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.     

In-straw cryoprotectant dilution of IVP bovine blastocysts vitrified in hand-pulled glass micropipettes

The aim of this study was to determine the influence of two ethylene glycol-based vitrification solutions on in vitro and in vivo survival after in-straw cryoprotectant dilution of vitrified in vitro-produced bovine embryos. Day-7 expanded blastocysts were selected according to diameter (> or = 180 microm) and osmotic characteristics and randomly assigned to one of three groups (i) VSa: vitrification in 40% EG+17.1% SUC+0.1% PVA; (ii) VSb: vitrification in 20% EG+20% DMSO; (iii) control: non-vitrified embryos. Vitrification was performed in hand-pulled glass micropipettes (GMP) and cryoprotectant dilution in 0.25 ml straws after warming in a plastic tube. Embryo viability was assessed by re-expansion and hatching rates after 72 h of IVC and by pregnancy rates after direct transfer of vitrified embryos. No differences in re-expansion rates were observed between vitrified groups after 24 h in culture (VSa=84.5%; VSb=94.8%). However, fewer VSa embryos (55.2%, P<0.05) hatched after 72 h than the VSb (75.8%) and control embryos (80.0%). To evaluate in vivo viability, vitrified embryos (VSa=20; VSb=21) were warmed under field conditions and individually transferred to synchronous recipients. Pregnancy rates (day 60) were similar between groups (VSa=20%; VSb=19%). Greater hatching rates occurred after 72 h of IVC for EG+DMSO than EG+SUC+PVA vitrification solutions. However, using a GMP vitrification container and in-tube warming, both solutions provided similar pregnancy rates after the in-straw cryoprotectant dilution and direct embryo transfer.     

Nonequilibrium cryopreservation of rabbit embryos using a modified (sealed) open pulled straw procedure

The study was designed to evaluate the efficiency of a modified (sealed) open pulled straw (mOPS) method for cryopreserving rabbit embryos by vitrification or rapid freezing. An additional objective was to determine whether the mOPS method could cause the vitrification of a cryoprotectant solution generally used in rapid freezing procedures. Two consecutive experiments of in vitro and in vivo viability were performed. In Experiment 1, the in vitro viability of rabbit embryos at the morula, compacted morula, early blastocyst and blastocyst stages was assessed after exposure to a mixture of 25% glycerol and 25% ethylene glycol (25GLY:25EG: vitrification solution) or 4.5 M (approximately 25% EG) ethylene glycol and 0.25 M sucrose (25EG:SUC: rapid freezing solution). Embryos were loaded into standard straws or mOPS and plunged directly into liquid nitrogen. The mOPS consisted of standard straws that were heat-pulled, leaving a wide opening for the cotton plug and a narrow one for loading embryos by capillarity. The embryos were aspirated into the mOPS in a column positioned between two columns of cryoprotectant solution separated by air bubbles. The mOPS were then sealed with polyvinyl-alcohol (PVA) sealing powder. The vitrification 25GLY:25EG solution became vitrified both in standard straws and mOPS, whereas the rapid freezing 25EG:SUC solution crystallized in standard straws, but vitrified in mOPS. The total number of embryos cryopreserved was 1695. Embryos cryopreserved after exposure to each solution in mOPS showed higher rates (88.2%) of survival immediately after thawing and removal of the cryoprotectant than those cryopreserved in 0.25 ml standard straws (78.8%; P < 0.0001). After culture, the developmental stage of the cryopreserved embryos significantly affected the rates of development to the expanded blastocyst stage. Regardless of the cryoprotectant used, lower rates of in vitro development were obtained when the embryos were cryopreserved at the morula stage, and higher rates achieved using embryos at blastocyst stages. Based on the results of Experiment 1, the second experiment was performed on blastocysts using the mOPS method. Experiment 2 was designed to evaluate the in vivo viability of cryopreserved rabbit blastocysts loaded into mOPS after exposure to 25GLY:25EG or 25EG:SUC. Embryos cryopreserved in mOPS and 25GLY:25EG solution gave rise to rates of live offspring (51.7%) not significantly different to those achieved using fresh embryos (58.5%). In conclusion, the modified (sealed) OPS method allows vitrification of the cryoprotectant solution at a lower concentration of cryoprotectants than that generally used in vitrification procedures. Rabbit blastocysts cryopreserved using a 25GLY:25EG solution in mOPS showed a similar rate of in vivo development after thawing to that shown by fresh embryos.     

Use of sucrose during removal of cryoprotectants after thawing eight-cell mouse embryos

Eight-cell mouse embryos were frozen in 0.5-ml plastic straws in modified Dulbecco's phosphate buffered saline (PBS) plus 5% steer serum plus either 1.32 M dimethyl sulfoxide (DMSO) or 1.32 M glycerol. Upon thawing, embryos were diluted 1:4 with 0.0, 0.2, 0.6, or 1.0 M sucrose solutions within the straws. Thawing was either in air at ambient temperature or in 8 degrees C or 38 degrees C water. After 48 h of culture, more embryos frozen in DMSO and thawed in 8 degrees C and 37 degrees C water developed to blastocysts (87 and 93%, respectively) than embryos thawed in air (75%; P < 0.05). No significant differences in development were noted among the three thawing regimens when embryos were frozen with glycerol. There was no significant effect of concentration of sucrose during dilution on development of embryos postthaw. With glycerol as the cryoprotectant, damage to zonae pellucidae increased as thawing rates increased, whereas the opposite was observed with DMSO as the cryoprotectant (P < 0.05).     

The survival of whole and bisected rabbit morulae after cryopreservation by the vitrification method

The survival of whole and bisected rabbit morulae cryopreserved by the vitrification method was investigated. The embryos were loaded in a column of vitrification solution (VS, a mixture of 25% glycerol and 25% 1, 2-propanediol in PBS+16% calf serum), which was located between two columns of 1 M sucrose solution in a plastic straw. The embryos were frozen by being plunged into liquid nitrogen and thawed in a water bath at 20 degrees C. Two methods of loading embryos into straws were used: the single and double column vitrification solution methods. The embryonic survival rates between these two methods were compared. Seventy-one (86.6%) out of 82 morulae vitrified in double column straws developed into the blastocyst stage in vitro. Eleven (18.3%) live fetuses were obtained after the transfer of 60 frozen-thawed morulae to four recipients. By contrast, the survival rate (36.5%, 27 74 ) of embryos vitrified in the single column straws was significantly lower (P<0.05). The vitrification solution of the single column straws became opaque, indicating ice-crystal formation, upon thawing in 5 of 11 straws, which was assumed to have damaged the embryos. More than 80% (29 36 ) of the bisected morulae frozen and thawed in the double column straws developed to the blastocyst stage in vitro when cryoprotectant was diluted stepwise with 1 M and 0.25 M sucrose solution. When the cryoprotectant was removed by one-step dilution with 1 M sucrose solution, swelling in blastomeres was observed and the development rate of the recovered embryos decreased (45.8%, 11 24 ). These results indicate that the vitrification method employed in our experiment is not only efficient for the cryopreservation of rabbit morulae, but it can also be used for the preservation of bisected rabbit morulae, which had not been successful using previous methods.     

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

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

Analysis of cryoprotectant, cooling rate and in situ dilution using conventional freezing or vitrification for cryopreserving sheep embryos

Two studies were conducted to evaluate the influence of cryoprotectant, cooling rate, container and cryopreservation procedure on the post-thaw viability of sheep embryos. In Study 1, late morula- to blastocyst-stage embryos were exposed to 1 of 10 cryoprotectant (1.5 M, glycerol vs propylene glycol)-plunge temperature treatments. Embryos were placed in glass ampules and cooled at 1 degrees C/min to -5 degrees C, seeded and further cooled at 0.3 degrees C/min to -15, -20, -25, -30 and -35 degrees C before rapid cooling by direct placement in liquid nitrogen (LN(2)). Post-thaw embryo viability was improved (P<0.01) when embryos were cooled to at least -30 degrees C before LN(2) plunging. Although there were no overt differences in embryo viability between cryoprotectant treatments (each resulted in live offspring after embryo transfer), there was a lower (P<0.01) incidence of zona pellucida damage using propylene glycol (4%) compared to glycerol (40%). In Study 2, embryos were equilibrated in 1.5 M propylene glycol or glycerol or a vitrification solution (VS3a). Embryos treated in propylene glycol or glycerol were divided into ampule or one-step((R)) straw treatments, cooled to -6 degrees C at 1 degrees C/min, seeded, cooled at 0.5 degrees C/min to -35 degrees C, held for 15 minutes and then transferred to LN(2). Embryos vitrified in the highly concentrated VS3a (6.5 M glycerol + 6% bovine serum albumin) were transferred from room air to LN(2) vapor, and then stored in LN(2). Propylene glycol- and glycerol-treated embryos in straws experienced lower (P<0.05) degeneration rates (27%) and yielded more (P<0.05) hatched blastocysts (73 and 60%, respectively) at 48 hours of culture and more (P<0.05) trophoblastic outgrowths (67 and 53%, respectively) after 1 week than vitrified embryos (47, 40 and 20%, respectively). In vitro development rate for VS3a-treated embryos was similar (P>0.10) to that of ampule controls, which had fewer (P<0.05) expanded blastocysts compared to similar straw treatments. Live offspring were produced from embryos cryopreserved by each straw treatment (propylene glycol, 3 of 7; glycerol, 1 of 7; VS3a, 2 of 7). In summary, freeze-preservation of sheep embryos was more effective in one-step straws than glass ampules and propylene glycol tended to be the optimum cryoprotectant. Furthermore, these findings demonstrate, for the first time, the biological competence of sheep embryos cryopreserved using the simple and rapid procedure of vitrification.     

In vivo and in vitro survival of goat embryos after freezing with ethylene glycol or glycerol

The aim of the present study was to compare the survival rates of goat morulae and blastocysts after different freezing procedures. The viability of frozen-thawed embryos was assessed both in vivo and in vitro. Two cryoprotectants, ethylene glycol and glycerol, were used and three cryoprotectant removal procedures were compared: progressive dilution in 1.0, 0.5, 0.3 and 0 M of cryoprotectant in PBS; a similar progressive dilution with cryoprotectant in PBS plus 0.25 M of sucrose; or one-step transfer in PBS containing 0.25 M of sucrose. In vitro development of frozen-thawed blastocysts was always higher than that of frozen morulae irrespective of the cryoprotectant (52 129 = 40.3% vs 23 161 = 14.3% ; P< 0.001). In vivo, however, frozen-thawed morulae developed equally as well as blastocysts after an identical freezing-thawing protocol. Development both in vivo and in vitro showed ethylene glycol to be a better cryoprotectant than glycerol for goat embryos at both developmental stages (23 vs 0%, 45 vs 35% in vitro; 34.5 vs 21%, 35 vs 23% in vivo for morulae and blastocysts, respectively).     

Survival of frozen mouse embryos after rapid thawing from -196 degrees C.

The effect of the rate of rewarming on the survival of 8-cell mouse embryos and blastocysts was examined. The samples were slowly cooled (0.3--0.6 degrees C/min) in 1.5 M-DMSO to temperatures between -10 and -80 degrees C before direct transfer to liquid nitrogen (-196 degrees C). Embryos survived rapid thawing (275--500 degrees C/min) only when slow cooling was terminated at relatively high subzero temperatures (-10 to -50 degrees C). The highest levels of survival in vitro of rapidly thawed 8-cell embryos were obtained after transfer to -196 degrees C from -35 and -40 degrees C (72 to 88%) and of rapidly thawed blastocysts after transfer from -25 to -50 degrees C (69 to 74%). By contrast, for embryos to survive slow thawing (8 to 20 degrees C/min) slow cooling to lower subzero temperatures (-60 degrees C and below) was required before transfer to -196 degrees C. The results indicate that embryos transferred to -196 degrees C from high subzero temperatures contain sufficient intracellular ice to damage them during slow warming but to permit survival after rapid warming. Survival of embryos after rapid dilution of DMSO at room temperature was similar to that after slow (stepwise) dilution at 0 degrees C. There was no difference between the viability of rapidly and slowly thawed embryos after transfer to pseudopregnant foster mothers. It is concluded that the behaviour of mammalian embryos subjected to the stresses of freezing and thawing is similar to that of other mammalian cells. A simpler and quicker method for the preservation of mouse embryos is described.     

Use of ethylene glycol as a cryoprotectant for bovine embryos allowing direct transfer of frozen-thawed embryos to recipient females

Four experiments were conducted to define a system for the direct transfer of frozen-thawed bovine embryos to recipient females. In Experiment I, nonsurgically recovered embryos were frozen in 1.5 M ethylene glycol (EG), 1.5 M propylene glycol (PG), 1.5 M DMSO or 1.4 M glycerol (GLY), and then thawed and placed directly into holding medium. Viability at 72 hours of post-thaw culture was 70, 11, 25 and 30% for the four groups, respectively. In Experiments II and III, 1.0, 1.5 and 2.0 M concentrations of EG were compared; a concentration of 1.5 M appeared to provide optimal cryopreservation and survival after direct rehydration. In Experiment IV, embryos were packaged in straws containing only 1.5 M EG, in straws containing a column of 1.5 M EG and the embryo and two columns of PB1 in a 1:3 ratio of volumes (EG PB1 ), or were frozen in 1.4 M glycerol. After thawing, embryos in EG and EG PB1 treatments were transferred directly to recipient females, while embryos frozen in GLY were rehydrated using a three-step procedure. In the first trial, pregnancy rates at approximately 60 days of gestation for embryos frozen in EG and GLY groups were 39 and 62%, respectively (P<0.10). In the second trial, the pregnancy rate for embryos frozen in EG PB1 was equal to that of embryos frozen in GLY (50% in both groups). These experiments demonstrate the potential for using ethylene glycol as a cryoprotectant for bovine embryos, thus permitting direct transfer of frozen-thawed embryos to recipient females.     

The effect of prefreezing the diluent portion of the straw in a step-wise vitrification process using ethylene glycol and polyvinylpyrrolidone to preserve bovine blastocysts.

A total of 678 bovine blastocysts, which had been produced by in vitro maturation, fertilization, and culture, were placed into plastic straws and were vitrified in various solutions of ethylene glycol (EG) + polyvinylpyrrolidone (PVP). Part of the straw was loaded with TCM199 medium + 0.3 M trehalose as a diluent; the diluent portions of the straw were prefrozen to either -30 or -196 degrees C. Then, the embryos suspended in the vitrification solution were pipetted into the balance of the straw and vitrified by direct immersion into liquid nitrogen. For thawing, the straws were warmed for 3 s in air and 20 s in a water bath at 39 degrees C and then agitated to mix the diluent and cryoprotectant solution for 5 min followed by culture in TCM199 + 10% FCS + 5 + microg/ml insulin + 50 microg/ml gentamycin sulfate for 72 h. Variables that were examined were the time of exposure to EG prior to vitrification, the PVP concentration, and the temperature of exposure to EG + PVP prior to vitrification. Survival and hatching rates of the blastocysts exposed to 40% EG in four steps at 4 degrees C were higher than those of embryos exposed in two steps (81.3 +/- 4.3% and 80.2 +/- 3.4% vs 67.6 +/- 4.5% and 71.5 +/- 4.7%, respectively; P < 0.05). The same indices were superior following vitrification-thawing of the blastocysts in 40% EG + 20% PVP than it was in 40% EG + 10% PVP (76.1 +/- 5.5% vs 63.7 +/- 1.8%; P < 0.05; and 61.6 +/- 6.0% vs 70.5 +/- 4.7%; P < 0.01, respectively). Exposure to the vitrification solution (40% EG + 20% PVP) at higher temperatures (37.5 degrees C vs 4 degrees C) reduced both survival and hatching rates (45.8 +/- 6.9% vs 83.9 +/- 4.4% and 41.5 +/- 1.8% vs 64.0 +/- 4.7%, respectively; P < 0.001). These results indicate that blastocysts vitrified after prefreezing the diluent portions of the straws do favor developmental competence of in vitro produced embryos.     

Vitrification of mouse oocytes: improved rates of survival, fertilization, and development to blastocysts

Rall and Fahy's (1985) vitrification procedure for the cryopreservation of 8-cell embryos was applied to unfertilized mouse oocytes. Unchanged, this method resulted in a mean of 24.1% of vitrified oocytes fertilizing and developing to blastocysts in vitro. Exposure of oocytes to the cryoprotectant media, but without the vitrification, resulted in 30.8% developing to blastocysts. Modifications to the durations of and media used in the dilution and equilibration steps of the procedure produced a final protocol giving a mean of 55.4% of vitrified oocytes and 72.4% of nonvitrified VS1-exposed oocytes developing to blastocysts; 85.7% of control oocytes develop to blastocysts. Osmotically induced damage was found to be the most important cause of loss of viability in these methods. Cooling of oocytes to 5-8 degrees C during the procedure had no significant effect on their viability. No parthenogenetic activation of oocytes occurred as a result of exposure to the procedure.     

Development of OPS vitrified pig blastocysts: effects of size of the collected blastocysts, cryoprotectant concentration used for vitrification and number of blastocysts transferred

Unhatched blastocysts from Large White hyperprolific gilts (n=103) were identified, measured and vitrified using the Open Pulled Straw (OPS) technique to evaluate the effects of the collected blastocyst size and cryoprotectant concentrations used for vitrification, and the number of embryos transferred per recipient. Vitrified/warmed blastocyst viability was estimated in vitro, as the percentage of embryos developing after 72h, and in vivo, on pregnancy Day 30. In the in vitro study, we compared the use of three cryoprotectant concentrations (16.5, 18, or 20% DMSO+16.5, 18, or 20% EG+0.4M sucrose). Survival rates differed significantly between the control (98.3%) and the three cryoprotectant concentrations (67, 62.3, and 57%, respectively). Blastocyst size at vitrification determined the further in vitro development of embryos (26% survival for blastocysts 126-144microm versus 100% for blastocysts >199microm). For the in vivo study, blastocysts were vitrified using cryoprotectant concentrations of 16.5 or 18% DMSO+EG and transferred surgically in groups of 20 or 30 per recipient (n=40). Recipients were slaughtered on pregnancy D30. No significant differences were detected in gestation rates (50-70%) and embryo survival rates (14.7-25%), although survival was higher (P=0.0003) when 20 blastocysts were transferred compared to 30 (24.7% versus 15.5%). Our findings indicate that best results, in terms of subsequent in vivo embryo survival, were achieved after transferring 20 embryos at the blastocyst or expanded blastocyst stage, previously vitrified using cryoprotectant concentrations of 16.5 or 18%.     

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.     

Piglets born after vitrification of embryos using the open pulled straw method

Morulae and unhatched blastocysts from Large White hyperprolific (LWh) and Meishan (MS) gilts were selected to test an ultrarapid open pulled straw (OPS) vitrification method with two media. The viability of vitrified/warmed embryos was estimated by the percentage of embryos that developed to the hatched blastocyst stage in vitro or by birth after transfer. In Experiment 1, two cryoprotectant dilution media were compared for cryopreservation of MS and LWh blastocysts: TCM was a standard Hepes-buffered TCM199 + 20% NBCS medium and PBS was a PBS + 20% NBCS medium. After a two-step equilibration in ethylene glycol, dimethyl sulfoxide, and sucrose, 2-5 blastocysts were loaded into OPS and plunged into liquid nitrogen. Embryos were warmed; a four-step dilution with decreasing concentrations of sucrose was applied. In PBS, LWh blastocysts (27%) had a lower viability in vitro than MS blastocysts (67%; P = 0.001). In TCM, no significant difference was observed between genotypes (41% for LWh and 43% for MS blastocysts) and both viability rates were lower than that of the control groups. In Experiment 2, morula-stage LWh and MS embryos were vitrified and warmed using PBS. The viability rate was low and did not differ between LWh (11%) and MS (14%). In Experiment 3, 200 MS and 200 LWh blastocysts were vitrified/warmed as described in Experiment 1 (PBS). In each of 20 MS recipients, 20 embryos were transferred. The farrowing rate was 55% and recipients farrowed four and five piglets (median) for MS and LWh blastocysts, respectively. The OPS method is therefore appropriate for cryopreservation of unhatched porcine blastocysts.     

Development of in vitro matured bovine oocytes after cryopreservation with different cryoprotectants

In vitro matured bovine oocytes at the metaphase-II stage were slowly frozen in phosphate buffered saline (PBS) containing 1.0 M glycerol, 1.0 M dimethylsulfoxide (DMSO) or 1.0 M propylene glycol (PROH). When thawed rapidly, more (P<0.05) oocytes were morphologically normal after being frozen with DMSO (86%) or PROH (83%) than with glycerol (62%). When inseminated in vitro with frozen-thawed bull spermatozoa, higher (P<0.05) penetration rates were observed in DMSO (79%) or PROH (76%) than in glycerol (48%). The percentages of oocytes developing to the 2-cell stage at 48 h postinsemination were also significantly (P<0.05) higher in DMSO (51%) and PROH (54%) than in glycerol (33%). However, a significant increase in the proportions of 8-cell embryos (46 vs 21 to 26%; P<0.05) at 72 h postinsemination and morulae (14 vs. 6 to 8%; P<0.05) was derived from oocytes frozen with PROH than with DMSO or glycerol. In conclusion, the type of cryoprotectant used is one of the critical factors affecting developmental competence of bovine oocytes frozen at the metaphase-II stage. For this stage of oocytes, PROH was the most effective, yielding a large number of 8-cell embryos and morulae than either glycerol or DMSO in a slow freezing method combined with a 3-step thawing protocol.     

Effect of vitrification on viability and chromosome abnormalities in 8-cell mouse embryos at various storage durations

This study was designed to investigate the effect of vitrification and post-thaw survival and chromosomal aberrations caused by vitrification of vitrified 8-cell mouse embryos in comparison with a control group. To this purpose the survival rate and the frequency of chromosomal aberrations were assessed in frozen-thawed 8-cell mouse embryos after various storage durations in the presence of ethylene glycol as cryoprotectant. eight-cell mouse embryos were obtained from NMRI mice 3 days after mating. Retrieved embryos were transferred to vitrification solution containing ethylene glycol as cryoprotectant, then transferred into a vitrification straw using standard technique, and vitrified in liquid nitrogen. Six groups of embryos according to storage duration (24 hours, 1 and 2 weeks, 1-6 months) were frozen. After appropriate storage periods embryos were thawed and studied for their viability 4-6 hours after thawing and intact embryos were transferred to fresh medium containing colcemid. After 48 hours, the embryos were fixed and studied for their chromosome abnormalities using Tarkowsky's drying technique. Results indicate that freezing affects the viability and chromosome structure of embryos when compared with the control group. Furthermore increasing the storage duration reduces the viability and increases the chromosome aberrations of embryos (such as aneuploidy and polyploidy). This result might indicate that the effects of vitrification on the cytoskeleton or other cellular organelle might produce chromosomal alterations leading to cell death.