A new procedure for the cryopreservation of equine embryos

Early equine blastocysts and blastocysts were collected nonsurgically at six days post-ovulation. Thirty-two embryos were randomly assigned to a 2x2 factorial design. Factors were: 1) 0.5-ml straws or 1-ml glass ampules; and 2) plunging into liquid nitrogen (IN(2)) at -33 C or -38 C. Cryoprotectant, 10% glycerol in PBS plus 5% fetal calf serum (FCS) was added in two steps, 5% then 10%. Embryos were cooled at 4 C/min to -6 C and then seeded, 0.3 C/min to -30 or -35 C and 0.1 C/min to -33 or -38 C. Samples were thawed in 37 C water and glycerol removed in six steps, 10 min per step. Embryo quality and stage of development were evaluated prior to freezing, immediately post-thaw and after 24 h culture in Ham's F10 with 5% FCS. The mean post-thaw quality of embryos plunged at -33 C was superior (P<0.05) to that of embryos plunged at -38 C (2.0 vs 2.9). Embryos frozen in ampules and plunged at -38 C were of poorer quality (P<0.05) than those frozen in ampules and plunged at -33 C or frozen in straws and plunged at -33 C. After 24 h of culture, more embryos developed if frozen in straws compared to ampules, and plunging at -33 C resulted in higher quality embryos than plunging at -38 C. In Experiment 2, 23 embryos were packaged in straws and plunged at -33 C as described in Experiment 1. Six of the 23 surgically transferred frozen embryos were degenerate at thawing and the remaining 17 surgically transferred were via flank incision. Pregnancy rate at 50 days post-ovulation was 53% (nine of 17). Early blastocysts resulted in a higher (P<0.05) pregnancy rate (8 10 , 80%) than expanded blastocysts (1 7 , 14%).     

Factors affecting survival of deep frozen bovine embryos in vitro: The effect of freezing container and method of removing cryoprotectant

The effect of freezing container and method of glycerol removal on in vitro survival of frozen-thawed Day 7 bovine embryos was investigated. Two hundred and fifteen embryos were frozen in ampules or straws, in either vertical or horizontal position and at a cooling rate of 0.3 degrees C/minute from -7 degrees C to -35 degrees C, before being plunged into liquid nitrogen. Samples were thawed in a water bath at +35 degrees C and glycerol was removed by either step-wise dilution (increments 0.25 M) or by exposure to 1.0 M sucrose for 10 minutes. A total of 197 embryos was recovered post-thaw (91%) with an overall survival after 1, 3, 6 and 24 hours in culture of 87, 81, 71, and 23%, respectively. Embryonic quality and percent survival, as assessed morphologically, did not change significantly between 1 and 3 hours but decreased significantly between 6 and 24 hours in culture (p < 0.05). Survival at 24 hours was significantly higher after removal of the cryoprotectant with sucrose when compared to the step-wise glycerol dilution (p < 0.05). Overall, embryonic survival in straws equaled that in ampules; freezing orientation of straws did not affect results. Further, glycerol removal with sucrose tended to yield survival superior to that provided by a step-wise dilution technique.     

Freezing bovine embryos with a portable liquid nitrogen freezer requiring no external seeding

One-hundred and twenty excellent morula to blastocyst stage bovine embryos were obtained nonsurgically from superovulated Holstein heifers. Completely portable, nonelectric (manual) liquid nitrogen (LN) freezers combined with simplified freezing curves utilizing self-seeding were compared to a programmable LN freezer (Planner-R204) following the conventional freezing rate for freezing embryos. Seeding was self induced in ampules at -6.8 degrees C and at -5.5 degrees C in straws in the manual freezers. Glycerol was used as the cryoprotectant at 1.5 M concentration. Post-thaw appearance, fluorscein diacetate testing (FDA), and growth after 12 and 24 h incubation were used as indicators of embryo viability. There were no significant differences between embryos frozen in the two types of freezers in terms of the viability tests used. Pregnancy rates resulting from transfer of embryos frozen in the two types of freezers will be determined in subsequent field trials. The manual LN freezers used in this study are capable of successfully freezing bovine embryos. The simplified nature of these freezers and the freezing procedures used with them greatly decreases the complexity and expense of freezing embryos.     

A comparative study of mouse embryo freeze-preservation including the examination of a thermoelectric freezing device

In Study 1 over 2000 4- to 8-cell mouse embryos were randomly pooled and assigned to 1 of 12 treatment groups. A 2 X 2 X 3 factorial design was used to analyze two types of cryoprotectant/post-thaw (PT) dilutions (dimethyl sulfoxide [Me2SO]/stepwise dilution versus glycerol/sucrose dilution), two storage containers (glass ampoules versus plastic straws), and three cooling treatments. Two commercial, controlled-rate freezing machines were examined, employing either nitrogen gas (Planer) or thermoelectric (Glacier) cooling. Embryos were cooled slowly (0.5 degrees C/min) to -35 or -80 degrees C and then cooled rapidly by transfer into liquid nitrogen (LN2). Thawed embryos were cultured for 24 hr after which developmental stage, post-thaw survival (PTS), embryo degeneration rate (EDR), quality grade (QG), and fluorescein diacetate viability grade (VG) were assessed. Overall, PTS and EDR were similar (P greater than 0.05) among the three freezing unit/plunge temperature treatments. Cumulative results of container and cryoprotectant/PT dilution treatments consistently demonstrated greater PTS, QG, and VG ratings and lower EDR values when embryos were frozen in ampoules using glycerol/sucrose dilution. Embryos treated with Me2SO/stepwise dilution were particularly sensitive to freezing damage when stored in plastic straws and plunged into LN2 at -35 degrees C. Study 2 was directed at determining whether Study 1 methods for diluting Me2SO-protected embryos markedly affected PTS rates. Post-thaw culture percentages were no different (P greater than 0.05) for four- to eight-cell Me2SO-treated embryos frozen in ampoules (using the forced-LN2 device), thawed, and diluted either conventionally in reduced concentrations of Me2SO or in the sucrose treatment normally accorded glycerolated embryos.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of rapid addition and dilution of dimethyl sulfoxide and 37 degrees C equilibration on viability of rabbit morulae thawed rapidly

The aim of the present study was to examine the effects of various conditions of addition and dilution of dimethyl sulfoxide (Me2SO) and 37 degrees C equilibration, and also the effects of freezing in the solution which was prepared in advance and stored in plastic straws at -20 degrees C on the viability of rabbit morulae thawed rapidly. The embryos were cooled from room temperature to -30 degrees C at 1 degree C/min in the presence of 1.5 M Me2SO using a programmable liquid nitrogen vapor freezing machine with an automatic seeding device, then cooled rapidly, and stored in liquid nitrogen. The frozen straws were thawed rapidly (greater than 1000 degrees C/min). When Me2SO was added in a single step, equilibrated with embryos at 37 degrees C for 15 min and diluted out in a single step, a very high survival was obtained: transferable/recovered, 90%: developed/recovered, 96%. When embryos were pipetted into 1.5 M Me2SO that was prepared in advance, stocked in straws at -20 degrees C, and cooled, the proportions of transferable and developed embryos were equivalent to those of embryos frozen in the solution that was prepared immediately before use.     

Freezing of bovine embryos: Effects of embryo quality,time from thawing to transfer and number frozen per vial

Over a ten-month period 736 embryos were collected from 103 cows induced to superovulate. Embryos were frozen in 10% glycerol and, after thawing, 655 appeared viable and were transferred nonsurgically to synchronous recipients. When embryos did not appear degenerative before freezing and transfers were performed within 3 hr of thawing, 40% of the embryos resulted in pregnancies. If embryos showed signs of degeneration before freezing, only 27% resulted in pregnancies after thawing and transfer. Similarly, when non-degenerative embryos were kept in Casou straws for more than 3 hr after thawing, fewer produced pregnancies (25%) following transfer. The number of embryos frozen in each vial ranged from one to 18 and this had no significant effect on success. By selecting embryos to be frozen and transferring them soon after thawing, the proportion of embryos surviving the freeze-thaw process can be very high.     

Viral contamination of embryos cryopreserved in liquid nitrogen

Despite the worldwide application of embryo-freezing technology as the means of preserving germplasm of mammalian species, there is no information available on the possible transmission of infectious agents to cryopreserved embryos via contaminated liquid nitrogen (LN). Recently, it has been reported that new methods of cryopreservation which employ ultrarapid freezing or vitrification require direct contact between the freezing medium containing oocytes or embryos and liquid phase nitrogen (LPN). As models for human and animal viral pathogens three bovine viruses, bovine viral diarrhea virus (BVDV), bovine herpesvirus-1 (BHV), and bovine immunodeficiency virus (BIV), were employed to study the potential for their transmission by experimentally contaminated LN to embryos frozen and stored in open freezing containers. Bovine embryos in a mixture of 20% ethylene glycol, 20% ME(2)SO, and 0.6% sucrose were vitrified in either unsealed standard 0.25 ml or modified open pulled straws or in plastic cryovials and then plunged into contaminated LPN. After 3-5 weeks of storage in LN, embryos were thawed and sequentially washed and only those with intact ZP were pooled together and tested in batches of three for viral contamination. From this pool of 83 batches, 13 of 61 (21.3%) batches exposed to BVDV and BHV-1 tested positive for viral association while all 22 batches exposed to BIV in unsealed containers tested negative. All control embryos vitrified in sealed cryovials and straws were free from viral contamination.     

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.     

An association between chromosomal abnormalities in rapidly frozen 2-cell mouse embryos and the ice-forming properties of the cryoprotective solution

This paper investigates the effect of straw handling on the viability of 2-cell mouse embryos rapidly frozen in dimethyl sulphoxide (DMSO) solutions. During the brief (3 min) equilibration step, straws were either rotated periodically to keep the embryos in suspension, or kept still to allow the embryos to settle onto the the inner surface of the straw. The effects of these straw movements were tested with cryoprotectant solutions containing 1.5, 3.0 or 4.5 M-DMSO. Rapidly cooled straws containing 4.5 M-DMSO vitrify throughout on cooling, but ice forms on warming. The survival and normality of embryos frozen in 4.5 M-DMSO was not influenced by straw handling as 91-92% formed blastocysts in vitro, 77-78% formed normal fetuses, and no chromosomal rearrangements were observed. In solutions containing less than 4.5 M-DMSO ice formation occurred throughout (1.5 M-DMSO), or in parts (3.0 M-DMSO) of the cryoprotectant during cooling. The viability of embryos frozen in 3.0 or 1.5 M-DMSO solutions was reduced both in vitro and in vivo and structural chromosome aberrations, predominantly tri- and quadri-radial rearrangements, were observed. The reduction in embryo viability, and the chromosomal damage was particularly pronounced in embryos frozen in 3.0 M-DMSO in straws which were rotated during the equilibration step (47% blastocysts, 15% fetuses, 77% chromosome rearrangements). The results indicate that rapid freezing of 2-cell mouse embryos in 4.5 M-DMSO is safe and efficient, whereas freezing at lower DMSO concentrations is associated with severe chromosome damage, and reduced viability in vitro and in vivo.     

Commercial freezing of bovine embryos in straws

Bovine embryos were frozen commercially in clear double length $\text{1}\text{2}$ cc French straws with the wick and powder plug in the center of the straw. One-half of the double length straw serves as a handle and contains a color coded $\text{1}\text{4}$ cc straw around which an adhesive backed label has been applied. After plunging into liquid nitrogen, straws are transferred into goblets on canes while under liquid nitrogen. The straws are stored in the liquid phase of a nitrogen tank and canes containing straws are not transferred from one container to another unless the goblet containing the straws is full of liquid nitrogen.Embryos held for longer than 4 hours after collection prior to freezing showed a steady decline in pregnancy rate related to the length of time held prior to freezing. The percentage of embryos thawed and then evaluated as being transferrable was related to the quality of the embryos prior to freeze (Grade 1–93.6%, Grade 2–87.0%, Grade 3–63.8%). There was no statistical difference in pregnancy rates obtained from prefreeze Grade 1 embryos when comparing advanced blastocysts (45.2%), blastocysts (38.7%), early blastoclyst (43.1%) and advanced morula (41.6%).     

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.     

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).     

A new pellet technique for cryopreserving ram and bull spermatozoa using the cold surface of cattle fat

A technique for freezing ram and bull spermatozoa in pellet form, using the cold surface of cattle fat was compared to other freezing procedures. Three freezing methods were compared to cryopreserve ram spermatozoa: 0.25 ml straws, pellets frozen on the cold surface of paraffin wax and pellets frozen on the cold surface of cattle fat. In addition, two cryoprotectants, glycerol or sucrose, in an egg yolk-Tris diluent were compared. Ram spermatozoa frozen as pellets on cattle fat exhibited higher percentages of motile cells after thawing (54%) than spermatozoa frozen in straws (49%) or as pellets on paraffin wax (42%, S.E.M. = 1; P < 0.05). However, the percentages of acrosome intact cells were similar for spermatozoa frozen as pellets (49%) and spermatozoa frozen in straws (48%; P > 0.05), but higher than for spermatozoa frozen as pellets on paraffin wax (39%, S.E.M. = 1; P > 0.05). Ram spermatozoa exhibited higher percentages of motile cells after thawing when the cryoprotectant was sucrose (51%) compared to glycerol (46%; P < 0.05). Similarly, acrosomal integrity was greater with sucrose (49%) than with glycerol (42%; P < 0.05). Bull spermatozoa exhibited higher percentages of motile cells after thawing, when cells were frozen in straws (47%) than in the pellet form, regardless of the surface on which the pellets were frozen (31-37%, S.E.M. = 3; P < 0.05). However, bull spermatozoa exhibited higher percentages of motile cells when frozen as pellets on the surface of cattle fat (66%) or dry ice (61%), than when frozen on paraffin wax (53%, S.E.M. = 4; P < 0.05). In conclusion, although bull spermatozoa survive cryopreservation more effectively in straws, ram spermatozoa can be cryopreserved as pellets on the cold surface of cattle fat using sucrose as the cryoprotectant. This technique is simple, requires little equipment, is less expensive than using straws and may prove useful for cryopreserving ram and possibly bull spermatozoa in developing countries.     

Sheep embryo cryopreservation by vitrification and conventional freezing

The survival of ovine embryos (morulae and blastocysts) either frozen by a conventional method or vitrified was investigated in culture. In Experiment I, embryos were vitrified using a solution containing 25% propylene glycol and 25% glycerol. A group of embryos (simulated control) was processed without freezing to evaluate the toxicity of the vitrification solution. In Experiment II, embryos were exposed to a solution of PBS containing 10% glycerol and 0.25 M sucrose placed horizontally in a programmable freezer. Automatic seeding was applied at -7 degrees C in 2 positions on straws and cooled at -0.3 degrees C/min to -25 degrees C and then stored in liquid nitrogen. In vitro development rates of vitrified embryos were 12% (morulae) and 19% (blastocysts). Simulated embryos showed a higher rate of survival than embryos cryopreserved by vitrification (67 and 63%, morulae and blastocysts respectively). In conventional cooling, the blastocysts showed the highest viability percentage (67%) of all the experimental groups but these values decreased significantly in morulae (31%). Differences in temperature between straws placed in distinct positions in the freezing chamber and thermic deviation were observed when automatic seeding was applied. Embryo viability differed from 51 to 75% according the relative position of the embryos within the chamber. Survival was higher when automatic seeding was applied on the meniscus of the embryo column versus the central point of this column (65 vs 21%). The damage of both cryopreservation methods on zona pellucida integrity (27 and 35% in vitrified and conventionally frozen embryos, respectively) had no effect on the in vitro survival.     

Blastocyst viability and generation of transgenic cattle following freezing of in vitro produced, DNA-injected embryos

This study examined whether the viability, determined in vitro, of DNA-injected bovine embryos produced in vitro was affected by freezing, and if the frozen embryos developed to term following transfer to recipients. In vitro fertilized zygotes were injected with the pBL1 gene and then co-cultured with mouse embryonic fibroblasts (MEF) in CR1aa medium. Embryos were prepared for cryopreservation by exposure to a 10% (v/v) glycerol solution, loaded into 0.25 ml straws and then frozen by conventional slow freezing. Thawing was by rapid warming in water (37 degrees C) and embryos were rehydrated in PBS diluents of 6%, 3% and 0% (v/v) glycerol supplemented with 0.25 M sucrose and 0.5% (w/v) BSA. In Experiment 1, blastocysts that developed from DNA-injected embryos were individually classified into three morphological groups and three stages of development prior to freezing. DNA-injected blastocysts of excellent quality at freezing showed a higher survival rate (78.8+/-10.6%) after thawing than those of good (60. 9+/-16.4%) or fair (12.5+/-5.9%) quality (P<0.05). Post-thaw survival rate, judged in vitro, increased with more advanced stage of blastocyst development at freezing (early 48.8+/-15.9%, mid 52. 1+/-12.6% and expanded 71.2+/-1.1; P<0.05). In Experiment 2, the frozen/thawed embryos were transferred to recipients to examine in vivo viability. Following transfer of one or two embryos per recipient, pregnancy rates at 60 days of gestation were 13.6% (13/96) for frozen embryos and 26.5% (43/162) for fresh embryos (P<0. 05). Of the 12 live calves born from the frozen/thawed embryos, two males (18.3%) were transgenic. None of the live-born calves derived from fresh embryos exhibited the transgene. One of transgenic bulls did not produce transgenic sperm. Three out of 23 calves (13.0%) produced from cows inseminated with semen of the other bull were transgenic, suggesting that this animal was a germ-line mosaic. These studies indicated that the viability of in vitro produced, DNA-injected bovine blastocysts was affected by freezing and by both the quality and stage of development of the embryo prior to freezing. The generation of transgenic cattle demonstrates that it is feasible to freeze DNA-injected, in vitro produced embryos.     

Zona fracture damage and its avoidance during the cryopreservation of mammalian embryos

Although fracture damage to the zonae pellucidae and blastomeres is frequently observed after the cryopreservation of mammalian embryos, little is known of the mechanism by which this occurs. The incidence of damage to zonae was measured when bovine ova with normal zonae were frozen in straws or glass test tubes by standard embryo cryopreservation procedures that yield high rates of survival. Ova were examined for zona damage after warming by procedures that ought to produce little or no thermal stress (slow warming in 20 degrees C air) or high levels of stress (rapid warming in liquid baths). Ova frozen in straws exhibited no zona damage after slow warming at 150 degrees C/min in air (n = 206). However, the incidence of zona damage increased when the straws were warmed rapidly in 20 degrees C (n = 157) or 36 degrees C (n = 159) water (17 and 24%, respectively). Ova in straws warmed rapidly in nonaqueous liquids (ethylene glycol, or silicone oil) exhibited lower rates of zona damage (2 to 5%). Ova frozen in glass tubes exhibited a much higher incidence of zona damage than those frozen in straws, regardless of the warming conditions. Thus, 30% of 114 ova exhibited damage when tubes were warmed slowly at 25 degrees C/min in air, while 54% of 98 ova showed zona damage when tubes were warmed rapidly at 500 degrees C/min in 36 degrees C water. These results are consistent with the view that zona damage is associated with thermally-induced fracturing of the suspension during rapid changes of temperature.     

Survival and fertility of ram spermatozoa frozen in pellets, straws and minitubes

The post-thaw survival and fertility of ram spermatozoa frozen in pellets, 0.25- and 0.5-ml PVC straws, and 0.25-ml minitubes were examined. In 5 experiments, a freezing height of 6 cm above the level of liquid nitrogen was optimal for 0.25- and 0.5-ml straws, whereas 4 cm was best for the 0.25-ml minitubes. Post-thaw motility of spermatozoa was lower for semen frozen in straws and minitubes than in pellets (Experiment 1: 43.7 vs 53.4%, P < 0.001), but after freezing was better in 0.5-ml straws and 0.25-ml minitubes than in 0.25-ml straws (Experiment 1: 44.9 vs 41.3%, P < 0.05; Experiment 2: 49.6 vs 46.8%, P < 0.01). Sperm motility was also better for 1:8 (semen:diluent) pre-freezing dilution rate (50.5%) than for 1:4 (45.6%, P < 0.01) and 1:2 (39.8%, P < 0.001) but not the 1:16 (49.5%) dilution rate. Dry ice was a better freezing medium than liquid nitrogen vapor (49.2 vs 46.9% motile spermatozoa, P < 0.001). The post-thaw motility of spermatozoa was similar for the three freezing packages if the semen was loaded at 5 degrees C, but motility was poorer for semen loaded into 0.25-ml straws than 0.25-ml minitubes at 30 degrees C (P < 0.05). In a fertility test, pregnancy rates were influenced by rams (3 rams, P < 0.05) and freezing package (pellets vs 0.25-ml minitube vs 0.25-ml straw vs 0.5-ml straw, P < 0.05) but not freezing medium (liquid nitrogen vapor vs dry ice). More ewes were pregnant after insemination with pellet-frozen semen (106/150, 71%) than with semen frozen in 0.25-ml straws (85/150, 57%; P < 0.05) and in 0.5-ml straws (83/150, 55%; P < 0.01) but not minitubes (98/150, 65%). It was concluded that minitubes provide a useful alternative to pellets as a storage package for ram spermatozoa, allowing for individual dose identification and easier storage while maintaining a fertility rate indistinguishable from that obtained with pellet-frozen semen.     

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.     

The effect of embryo quality at freezing on subsequent development of thawed cow embryos

Day 7 to 9 embryos were frozen by a rapid two-step method to ?38°C before being plunged into liquid nitrogen. Glycerol was used as the cryoprotectant and, following thawing, the embryos were cultured for 12 – 24 hours in PBS + 15% heat-treated steer serum. In Experiment 1, embryos were frozen in 2.0 ml glass ampoules or 0.5 ml Cassou straws. Two levels of glycerol (1.0M and 1.4M) gave comparable $\text{in vitro}$ survival rates ($\text{12}\text{20}$ and $\text{13}\text{25}$, respectively). A greater proportion of embryos developed in culture after freezing in straws. In Experiment 2, embryos were classified morphologically before and after freezing into 5 grades (1 = excellent; 2 = good; 3 = fair; 4 = poor; 5 = degenerate). Only embryos of grade 1, 2 and 3 were frozen. The post-thaw survival rates for embryos graded 1, 2 and 3 before freezing were 100% ($\text{11}\text{11}$), 86% ($\text{24}\text{28}$) and 83% ($\text{20}\text{24}$), respectively. Furthermore, the porportion of surviving embryos estimated to be of poor quality (grade 4) was greater for embryos graded 3 before freezing ($\text{13}\text{20}$) than for embryos graded 2 ($\text{6}\text{24}$) or 1 ($\text{1}\text{11}$). The percentage of embryos which developed normally after $\text{in vitro}$ culture for each of the pre-freezing grades 1, 2 and 3 was 91% ($\text{10}\text{11}$), 50% ($\text{14}\text{28}$) and 29% ($\text{7}\text{24}$), respectively. Of the total number of frozen-thawed embryos which developed in culture, $\text{5}\text{31}$ (16%) were of poor quality. The proportion of poor quality developing embryos was greater inembryos graded 3 before freezing ($\text{3}\text{7}$) than those graded 2 ($\text{2}\text{14}$). All of the embryos graded 1 before freezing and which developed in culture were of good quality. Results indicate that, if high post-thaw survival rates are to be obtained, stringent embryo selection processes will be required.     

Status of cryopreservation of embryos from domestic animals.

The discovery of glycerol as an effective cryoprotectant for spermatozoa led to research on cryopreservation of embryos. The first successful offspring from frozen-thawed embryos were reported in the mouse and later in other laboratory animals. Subsequently, these techniques were applied to domestic animals. Research in cryopreservation techniques have included studies concerning the type and concentration of cryoprotectant, cooling and freezing rates, seeding and plunging temperatures, thawing temperatures and rates, and methods of cryoprotectant removal. To date, successful results based on pregnancy rates have been obtained with cryopreserved cow, sheep, goat, and horse embryos but no success has been reported in swine. Post-thaw embryo survival has been shown to be dependent on the initial embryo quality, developmental stage, and species. The freezing techniques most frequently used in research and by commercial companies are identified as "equilibrium" cryopreservation. In this technique the embryos are placed in a concentrated glycerol solution (1.4 M in PBS supplemented with BSA) at room temperature and the glycerol is allowed to equilibrate for a 20-min period. During the cooling process the straws are seeded (-4 to -7 degrees C) and cooling is continued at a rate of 0.3 to 0.5 degree C/min to -30 degrees C when bovine embryos may be plunged into LN2. Sheep embryos are successfully frozen with ethylene glycol (1.5 M) or DMSO (1.5 M) rather than with glycerol. Horse embryos have been frozen in 0.5 rather than 0.25 cc straws but with cooling rates and seeding and plunging temperatures similar to those used with bovine embryos. Swine embryos have shown a high sensitivity to temperature and cryoprotectants probably due to their high lipid content and a temperature decrease to 15 or 10 degrees C causes a dramatic increase in the percentage of degenerated embryos. However, a recent study has shown that hatched pig blastocysts survived exposure below 15 degrees C. Recent research has shown that embryos may also be frozen by a "nonequilibrium" method. This rapid freezing by vitrification consists of dehydration of the embryo at room temperature by a very highly concentrated vitrification media (3.5 to 4.0 M) and a very rapid freeze that avoids the formation of ice allowing the solution to change from a liquid to a glassy state. Vitrification solutions consist of combinations of sucrose, glycerol, and propylene glycol. With this technique, 50% pregnancy rates have been reported with the bovine blastocyst.