Examination of some processing methods for freezing boar semen.

Five experiments were conducted to examine the effect of processing methods and diluents on survival and morphology of boar spermatozoa after freezing. Post-thawing survival of spermatozoa was better for Beltsville-F3 (BF3) than for tris-fructose-EDTA freezing diluent when the seminal plasma and glycerol were removed prior to freezing (method A). Both freezing diluents yielded similar viability results when the spermatozoa were frozen in the presence of siminal plasma and glycerol (method B). Viability of spermatozoa after thawing was better when glycerol concentration in the prefreezing diluent (method A) or in the freezing medium (method B) was 2-5 and 5-0 rather than 7-5%. Cooling of diluted semen to 5 degrees C beyond 4 h decreased the post-thawing survival of spermatozoa. The proportion of spermatozoa with undamaged acrosomes after processing and thawing by different methods was indistinguishable and relatively low. When the semen was frozen at cell concentrations ranging from 0-25 to 2-0 X 10(9)/ml, the viability of spermatozoa declined with increasing concentration following freezing in BF3, and S-1 diluents. Viability results were very similar for all cell concentrations examined when tris-fructose-EDTA diluent was used, indicating the possibility of freezing boar semen in a concentrated state.     

Field and in vitro assay of three methods for freezing ram semen

Glycerol has been the most widely used cryopreservation agent for spermatozoa and a wide range of factors affect its action on sperm viability and fertilizing capacity. We tested three methods for freezing ram semen packed in 0.25 ml straws (final cellular concentration: 100 x 10(6) spz/ml). Method M1: Two-thirds of the final volume of diluent was added as solution A (without glycerol) to the pure semen at 35 degrees C. The sample was cooled to 5 degrees C (-0.30 degrees C/min), one-third of final diluent volume was added as solution B (final concentration of glycerol 4%) and the sample was maintained at 5 degrees C for 2h. It was then frozen in a programmable biofreezer (-20 degrees C/min down to -100 degrees C). Method M2: The sample was diluted with a specific solution at 35 degrees C (final concentration of glycerol 3%), cooled to 5 degrees C (-0.20 degrees C/min) and left for 2h. After that, it was frozen in nitrogen vapours. Method M3: Semen was diluted 1:1 in a specific solution (concentration of glycerol 2%) and cooled to 5 degrees C (-0.25 degrees C/min). The sample was then diluted again in the same solution to the final cellular concentration (final concentration of glycerol 4%). It was left for 1h at 5 degrees C and then frozen in a programmable biofreezer (-20 degrees C/min down to -100 degrees C). Best total motility (TM) and progressive motility (PM) (75.8 and 55.18%) were obtained using Method M3. Methods M1 and M3 gave significantly higher values (P<0.05) for kinetic parameters: average path velocity (VAP) (81.3 and 85.2 microm/s), straight-line velocity (VSL) (72.8 and 77.3 microm/s) and linearity (LIN) (66.6 and 68.8%). Method M2 showed the lowest kinetic parameters of motility (VAP 74.4, VSL 67.3 and LIN 62.5) and the highest percentage of cells with damaged plasma membrane (53.8%). Method M1 gave the worst results in viability and acrosome status assessed using fluorescence probes (31.3%-dead cells with damaged acrosomes-versus 25.4% in M2 and 23.3% in M3). A field trial carried out on fertility showed a significantly higher percentage of pregnant or lambing ewes (P<0.05) with Method M3 (67.3% versus 51.1% for M1 and 58.8% for M2). We concluded that the use of a simple dilution medium (test-fructose-glycerol-egg yolk) with the addition of glycerol (to 2% at 35 degrees C and to 4% at 5 degrees C) in two steps together with a programmable biofreezer was a productive method for freezing ram semen.     

Comparative semen cryopreservation in ferrets (Mustela putorius furo) and pregnancies after laparoscopic intrauterine insemination with frozen-thawed spermatozoa

A study was conducted to determine an optimum technique for semen cryopreservation and the biological competence of frozen-thawed ferret spermatozoa. Fifty-two fresh electroejaculates from 4 males were evaluated for sperm percentage motility, forward progressive motility, motility index (SMI) and acrosomal integrity. To determine the optimum temperature for maintaining sperm motility in vitro and the influence of glycerol on sperm motility, seminal aliquants were diluted in TEST diluent (containing either 0 or 4% glycerol) and maintained at 25 degrees or 37 degrees C. For cryopreservation, semen was diluted in each of 3 cryodiluents (TEST, PDV, BF5F), cooled for 30 min at 5 degrees C and pelleted on solid CO2 or frozen in 0.25 ml straws (20 degrees C/min to -100 degrees C). Following thawing, SMI and acrosomal integrity were determined. Ten females with maximum vulval swelling were given 90 i.u. human chorionic gonadotrophin and laparoscopically inseminated in utero with spermatozoa previously frozen using the optimum diluent and freeze-thaw method. The maintenance temperature of 25 degrees C was superior (P less than 0.05) to 37 degrees C for sustaining sperm motility, and glycerol did not influence (P greater than 0.05) motility for up to 11 h of culture. After thawing, motile spermatozoa were recovered in all treatment groups, but sperm motility and normal acrosomal ratings were highest using the PDV diluent, the pelleting method and thawing at 37 degrees C (P less than 0.05). Seven of the 10 ferrets (70%) inseminated with spermatozoa frozen by this approach became pregnant and produced 31 kits (mean litter size 4.4; range 1-9 kits).(ABSTRACT TRUNCATED AT 250 WORDS)     

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).     

Gene banking of the neotropical fish Leporinus obtusidens (Valenciennes, 1836): a protocol to freeze its sperm in the field

A practical sperm cryopreservation protocol using a dry-shipper and a diluent of simple composition is described for the neotropical fish Leporinus obtusidens (Valenciennes, 1836). The cooling rate of the dry-shipper and its period of useful time, established under laboratory conditions, were respectively 25.7-30.8 degrees C/min (between 0 and -60 degrees C) and 9 days after charging. Sperm donors were selected on the basis of their hyperemic genital papilla and the ability to ooze milt under gentle manual pressure, during the reproductive months of November to January. Milt volume (1.3+/-0.3 mL; n=9 fish), fresh sperm motility rate (93.3+/-2.5%; n=6 fish), and sperm concentration (10.9+/-3.0 x 10(9)spermatozoa/mL of milt) were obtained. The sperm cryopreservation experiments were conducted with the following cryoprotectants (all at 10%, before mixing with milt): dimethyl sulphoxide (DMSO; n=10 fish), methanol (n=6 fish), propanediol (n=6 fish) and ethylene glycol (n=5 fish). Glucose (5%) and hen's egg yolk (10%) made up the diluents containing DMSO, ethylene glycol or propanediol. Milk powder (10%) replaced hen's egg yolk in the diluent containing methanol. Distilled water (up to 100%) completed the diluent solutions. Milt freezing (in 0.5-mL straws) was performed in the dry-shipper after 1:5 (milt:diluent) dilution. Thawed sperm cryopreserved in DMSO-containing diluent and activated by 119 mM NaHCO(3) gave the highest motility rate (62+/-14%). The fertilizing capacity of L. obtusidens sperm was tested using the combination of DMSO-containing diluent as the cryoprotectant and 119 mM NaHCO(3) as the activating solution. Oocytes were obtained from artificial spawning and fertilized with different proportions of spermatozoa. The greatest rate of fertilization (74%) occurred when the ratio of about 112,000 motile spermatozoa:oocyte was used. Thus, a protocol to freeze L. obtusidens sperm can be elaborated as follows. Milt (<1.5 mL fish(-1)) was readily available only in November to January; a simple solution, composed of 10% DMSO (concentration before adding milt), 5% glucose, and 10% hen yolk egg, in distilled water, was used as sperm diluent; cooling rate of 25-30 degrees C/min, yielded in a portable dry-shipper, was adequate to freeze diluted milt (1:5; milt:diluent), in 5-mL straws; about 112,000 thawed motile spermatozoa:oocyte activated by 119 mM NaHCO(3) assured a fertilization rate of 74%.     

Evaluation of extenders and cryopreservatives for cooling and cryopreservation of spermatozoa from the western spotted skunk (Spilogale gracilis)

Experiments were conducted to develop a suitable protocol for cryopreservation of spotted skunk semen. Semen was collected by electroejaculation of captive male skunks (n = 16) from late January through late November. In the first experiment, fresh semen was diluted in either TEST (n = 10), TRIS (n = 9), or BF5F (n = 7) extenders and maintained at 4°C for 16 hr. Sperm motility in these extenders was not significantly different before cooling (P = 0.71), but samples diluted with BF5F exhibited significantly lower sperm motility than the other extenders at all time points after cooling (P < 0.05). In the second experiment, fresh semen was diluted in TEST containing either 3, 5, or 10% DMSO or 3, 5, or 10% glycerol as a cryopreservative. These samples were cooled to 4°C and frozen in 0.25 ml French straws on dry ice. Some samples containing 5% DMSO or 5% glycerol (n = 4), were also frozen on dry ice as pellets. Frozen samples were maintained in liquid nitrogen. Fresh samples had significantly greater sperm motility in dimethyl sulfoxide (DMSO) than in glycerol (P < 0.05), while frozen and thawed samples had the highest motility in 5 or 10% DMSO or 10% glycerol. Samples frozen in French straws had significantly greater sperm motility after freezing and thawing than those frozen by the pellet method (P < 0.05). Optimum cryoprotection was achieved with the TEST extender containing 5 or 10% DMSO, when used in conjunction with French straws. © 1992 Wiley-Liss, Inc.     

Sperm survival during short-term storage and after cryopreservation of semen from striped trumpeter (Latris lineata)

Methods of short-term storage and cryopreservation were examined for semen from striped trumpeter (Latris lineata). For fresh semen at 18 degrees C, the percentage of motile sperm declined rapidly from over 80% immediately after activation with sea water to less than 2% within 9 min after activation. The motility after activation of undiluted fresh sperm stored at 5 degrees C was maintained for two days and then declined markedly so that by the eighth day, sperm were mostly immotile after activation. The post-thawing motility was higher for sperm frozen with a non-activating diluent containing 2.84 M DMSO in saline (117 mM NaCl) than in an activating glycerol (2 M) medium in dilute sea water (300 mOsm). Post-thawing motility was higher for a dilution rate of 1:5 (semen:diluent) than 1:2 or 1:11 but was similar when frozen semen was thawed at 10 degrees, 20 degrees or 30 degrees C. For semen stored at a range of volumes as pellets frozen on dry ice (0.2 to 2.0 mL) or straws frozen in liquid nitrogen vapor (0.25 to 0.5 mL) and thawed in a waterbath at 20 degrees C, the post-thawing motilities were similar even though the patterns of cooling and thawing differed markedly between methods of freezing and sizes of pellets and straws.     

Combined effects of glycerol concentration, cooling velocity, and osmolality of skim milk diluents on cryopreservation of ram spermatozoa

The interaction of glycerol concentration from 0 to 16% and cooling velocity from 1 to 100 degrees C/min on freeze-thaw survival of ram spermatozoa was studied using a diluent based on 15% skim milk (450 mOs/kg water). Optimal spermatozoa survival (percentage motility and rating) was obtained with 4 to 6% glycerol and freezing rates of 10 to 100 degrees C/min. Similar results were obtained with 8% glycerol at freezing rates of 5 to 30 degrees C/min. Although the ram spermatozoa tolerated several cooling velocities at each glycerol concentration, increasing the concentration of glycerol resulted in a downshift in the range of optimal cooling velocities. Glycerol concentrations above 8% were toxic and contributed greatly to the progressive decrease in spermatozoa survival. Comparison of the 15% skim milk diluent (450 mOs/kg water) with a 19% skim milk diluent (600 mOs/kg water) showed that optimal cryosurvival was obtained with 4 to 6% glycerol and freezing rates of 10 to 100 degrees C/min with both diluents.     

Sperm cryopreservation of a live-bearing fish, the platyfish Xiphophorus couchianus

The objectives of this study were to evaluate the effects of cryoprotectant, osmotic pressure, cooling rate, equilibration time, and sperm-to-extender ratio, as well as somatic relationships of body length, body weight, and testis weight to sperm density in the platyfish Xiphophorus couchianus. Sperm motility and survival duration after thawing were significantly different between cryopreservation with dimethyl sulfoxide (DMSO) and glycerol, with the highest motility at 10 min after thawing obtained with 14% glycerol. With subsequent use of 14% glycerol as cryoprotectant, the highest motility after thawing was observed with Hanks' balanced salt solution (HBSS) across a range of 240-300 mOsm/kg. Samples cooled from 5 to -80 degrees C at 25 degrees C/min yielded the highest post-thaw motility, although no significant difference was found for cooling rates across the range of 20-30 degrees C/min. In addition, the highest motility after thawing was found in samples equilibrated from 10 to 30 min with 14% glycerol and cooled at 25 degrees C/min. The post-thaw motility declined rapidly with use of 10% glycerol and cooling at 5 degrees C/min across the equilibration range of 10 min to 2h. Sperm motility with a dilution ratio of sperm to extender of 1:10 was not different at 10 min after thawing with those samples at greater dilutions, but declined significantly from Day 1 after thawing and showed lower survival duration when stored at 4 degrees C. However, the additional dilution of sperm solutions with HBSS (300 mOsm/kg) immediately after thawing significantly slowed the decline of motility and prolonged the duration of survival. Based on the above findings, the highest average sperm motility (78+/-3 %) at 10 min after thawing was obtained when sperm were suspended in HBSS at 300 mOsm/kg with 14% glycerol as cryoprotectant, diluted at a ratio of sperm to HBSS-glycerol of 1:20, equilibrated for 10 min, cooled at 25 degrees C/min from 5 to -80 degrees C before plunging into liquid nitrogen, and thawed at 40 degrees C in a water bath for 7 s. If diluted within 5 h after thawing, sperm frozen by the above protocol retained continuous motility for 15 days when stored at 4 degrees C.     

The effect of glycerol-related osmotic changes on post-thaw motility and acrosomal integrity of ram spermatozoa

Ram semen, collected by artificial vagina, was diluted and processed for long-term storage as described by P. S. Fiser, L. Ainsworth, and R. W. Fairfull (Canad. J. Anim. Sci. 62, 425-428, 1982). The concentration of the cryoprotectant, glycerol, was adjusted to 4% in the diluted semen prior to freezing by a one-step addition at 30 degrees C (Method 1), by cooling the semen to 5 degrees C and addition of the glycerol gradually over 30 min (Method 2), by one-step addition of glycerol prior to equilibration for 2 hr (Method 3), or by cooling to 5 degrees C, followed by a holding period of 2 hr at 5 degrees C, and the one-step addition of glycerol just prior to freezing (Method 4). After thawing, the glycerol concentration of the semen was reduced by stepwise dilution from 4 to 0.4% over 15 or 30 min or by a one-step ten-fold dilution. The average post-thaw percentage of motile spermatozoa was significantly lower after addition of glycerol by Method 1 (39.9%) than when the glycerol was added by the other three methods (range, 44.0-46.4% averaged over the glycerol dilution). The average post-thaw percentage of intact acrosomes (61.2%), highest in semen in which the glycerol was added by Method 2, was not significantly different from those in which glycerol was added to semen by Methods 3 and 4, but it was significantly higher than that found in semen in which the glycerol was added by Method 1 (54.4%). However, when averaged over the method of glycerolation, the post-thaw percentage of motile spermatozoa (range, 43.7-44.2%) and the percentage of intact acrosomes (range, 56.8-59.5%) did not differ significantly in semen subjected to gradual decrease in glycerol concentration and diluent osmolality (over 15 and 30 min) or by a one-step, 10-fold dilution. These data indicate that post-thaw survival of spermatozoa can be influenced by the way in which glycerol is added prior to freezing. However, post-thaw spermatozoa motility and acrosomal integrity can be maintained even after a rapid decrease in glycerol concentration such as that which accompanies insemination or dilution of semen for assessment of motility.     

Effect of cryoprotectants on certain seminal attributes and on the fertility of buck spermatozoa

Semen samples were obtained from 12 bucks (3 Beetal, 3 Black Bengal and 6 Beetal x Black Bengal) and 10 different extenders were constituted with varying concentrations of glycerol, DMSO, glycerol + DMSO and glycerol + lactose as the sperm cryoprotective agents. After the collection of semen samples, they were assessed for quality, diluted in different extenders after removal of seminal plasma, packaged in ministraws and frozen after equilibration (5'C) for 5 h. The samples were evaluated immediately after equilibration and again 24 h after freezing for progressive motility, percentage of live spermatozoa and acrosome, head and tail abnormalities. Both motility and the percentage of live spermatozoa were most affected by extenders containing only DMSO and these values improved in glycerol + DMSO extenders as the concentration of glycerol was increased while DMSO was decreased. However, these values were significantly higher in extenders containing glycerol + lactose as the cryoprotective agents, and were found to increase with increased concentration of lactose, being highest in TYGL (180). Acrosomal and tail abnormalities tended to increase between post equilibration and post thawing stage, and were higher in extenders containing the higher levels of DMSO. Significantly (P < 0.01) lower percentages of abnormalities were recorded in the glycerol + lactose extenders. The fertility results showed nonsignificant effect of extenders on the conception rate of does.     

Semen cryopreservation in Bactrian camel (Camelus bactrianus) using SHOTOR diluent: effects of cooling rates and glycerol concentrations

Experiments were conducted with a final goal of providing a suitable protocol for cryopreservation of Bactrian camel semen. In Experiment I, the effect of average cooling rate (slow cooling: 0.14 versus fast cooling: 0.55 degrees C/min) on the viability of chilled semen was evaluated. In Experiment II, the effect of different concentrations of glycerol (4, 6 and 8%) on the post-thaw viability of frozen sperm was investigated. In Experiment III, the efficiency of SHOTOR diluent was compared with IMV buffers for the cryopreservation of camel semen. Viability parameters including progressive forward motility (PFM), plasma membrane integrity and percentage of live spermatozoa were assessed. Progressive forward motility of sperm cooled at the faster rate was superior after incubating for 24h at 4 degrees C compared to that cooled at the slower rate (P<0.05). Post-thaw viability of Bactrian camel sperm was better using a final glycerol concentration of 6% compared to 4 and 8% (P<0.05). Progressive forward motility of frozen-thawed sperm was greater using SHOTOR diluent (29.9%) compared to IMV buffers (4.2%, P<0.05). In conclusion, semen cryopreservation in Bactrian camel is feasible when it is extended in SHOTOR diluent, cooled within 1h (average cooling rate: 0.55 degrees C/min) to 4 degrees C, and then exposed to glycerol, at the final concentration of 6%.     

Semen cryopreservation of small abalone (Haliotis diversicolor supertexa)

Methods for cryopreserving spermatozoa and maximizing fertilization rate in Taiwan small abalone, Haliotis diversicolor supertexa, were developed. The gametes (spermatozoa and eggs) of small abalone were viable 3 h post-spawning, with fertilization, and development rate decreasing with time. A minimum of 10(2) cell/ml sperm concentration and a contact time of 2 min between gametes is recommended for artificial insemination of small abalone eggs. Eight cryoprotectants, dimethyl sulfoxide (DMSO), dimethyl acetamide (DMA), ethylene glycol (EG), propylene glycol (PG), butylene glycol (BG), polyethylene glycol, glycerol and methanol, were tested at concentrations between 5 and 25% to evaluate their effect on motility of spermatozoa exposed to cryoprotectant for up to 60 min at 25 degrees C before freezing. The least toxic cryoprotectant, 10% DMSO, was added to artificial seawater (ASW) to formulate the extender for freezing. Semen was diluted 1:1 with the extender, inserted into 1.5 ml microtubes and frozen using a cooling rate between -3.5 and -20 degrees C/min to various transition temperatures (0, -30, -60, -90 and -120 degrees C), followed by transfer and storage in liquid nitrogen (-196 degrees C). The microtubes were thawed from +45 to +145 degrees C/min. Spermatozoa, cooled to -90 degrees C at a cooling rate of -12 or -15 degrees C/min and then immersed in liquid nitrogen, had the best post-thaw motility. Post-thaw sperm motility was markedly reduced compared to fresh sperm. More frozen-thawed spermatozoa are required to achieve fertilization rates comparable to those achieved using fresh spermatozoa.     

Effect of initial freezing temperature, addition of glycerol and dilution on the survival and fertilizing ability of deep-frozen ram semen.

The influence oftemperature, addition of glycerol, initial freezing temperature, method of dilution, level of glycerol in the diluted semen, equilibration time and type of diluent on the survival and fertilizing capacity of deep-frozen according to the best conditions was compared with that of "fresh" semen. The addition of glycerol at plus30 degrees C resulted in a highly significant decrease in the mean proportion of motile spermatozoa immediately after thawing compared with the effect of addition at plus 4 degrees C. The immersion of the straws at minus55 degrees C significantly reduced the revival of the spermatozoa compared with initial freezing at lower temperatures. The exposure time to glycerol had no significant effect on the survival of spermatozoa after thawing and incubation, but fertility was significantly higher with 4% than with 2% glycerol. The I. N. R. A. diluent provided better sperm survival and a significantly higher conception rate than did lactose-egg yolk extender. The semen frozen according to the best conditions (about 50% of the samples) had a fertilizing ability similar to that of "fresh" semen when the proportion of motile spermatozoa before, and after 1 or 3 hr of incubation was equal to or above 45, 40 and 30% respectively.     

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.     

A simple method for mouse embryo cryopreservation in a low toxicity vitrification solution, without appreciable loss of viability

Mouse morulae were exposed to solutions containing 30-50% of permeable agents (ethylene glycol, glycerol, propylene glycol) in modified phosphate-buffered saline (PB1 medium) at 20 degrees C for 20 min. A high percentage of them developed to expanded blastocysts in culture, after exposure to 30% and 40% ethylene glycol (98 and 84%, respectively), or 30% glycerol (88%). Ethylene glycol and glycerol were diluted to 30 and 40% with PB1 medium or with PB1 containing 30% Ficoll or 30% Ficoll + 0.5 M-sucrose, immersed in liquid nitrogen in straws and warmed in 20 degrees C water. Solutions containing 40% of a permeable agent with Ficoll did not crystallize during cooling or warming. Mouse morulae were exposed to 40% ethylene glycol in PB1 medium containing 30% Ficoll (EF) or PB1 medium + 30% Ficoll + 0.5 M-sucrose (EFS) for 5-20 min at 20 degrees C. EFS solution was non-toxic to the embryos during 5 min of exposure. When embryos, equilibrated in EFS solution for 2 or 5 min at 20 degrees C, were vitrified at -196 degrees C and were warmed rapidly, nearly all embryos developed in culture (97-98%), and 51% developed to live young at term after transfer. This method, which results in virtually no decrease in embryonic viability, may be of practical use for embryo preservation.     

Effects of treatment with butylated hydroxytoluene on the susceptibility of boar spermatozoa to cold stress and dilution.

Boar spermatozoa acquired resistance to cold shock immediately after exposure to 2.0 mmol butylated hydroxytoluene (BHT) l-1 when Beltsville thawing solution was used as a basic diluent, as judged by motility (the proportion of motile spermatozoa) and acrosomal integrity. The concentration of BHT could be reduced to 0.2 mmol l-1 without decreasing the protective action. However, motility was altered in the presence of greater than 0.15 mmol BHT l-1. Beltsville freezing 5 (BF5) diluent was more effective than Beltsville thawing solution in protecting spermatozoa from cold shock, but addition of BHT to BF5 diluent did not affect the motility and acrosomal morphology of spermatozoa before or after cold shock. Dilution of BHT-treated spermatozoa with BF5 diluent did not restore motility and did not afford further protection against cold shock; it was detrimental to spermatozoa treated with 2 mmol BHT l-1 for greater than 15 min. Egg yolk or lecithin had a detrimental effect. When spermatozoa were treated with 0.05-0.10 mmol BHT l-1 before slow cooling to 5 degrees C, the progressive motility and acrosomal integrity were maintained better after storage for 6 days than in untreated spermatozoa.     

Fertility test of frozen boar semen.

The fertility results of two experiments are presented. In experiment 1, the semen was frozen in tris-fructose-EDTA or BF3 diluents at 0-25 X 10(9)/ml sperm concentration and extended after thawing with either seminal plasma (SP) or the freezing medium (FM) containing no cryoprotective agent. In the second experiment the semen was glycerolated by two methods, frozen at 1-0 X 10(9)/ml sperm concentration, and extended wtih FM before insemination. Fertility after double insemination within one oestrus with semen frozen in tris-fructose-EDTA or BF3 diluents varied depending on the medium used for extension of thawed semen. The farrowing rates for semen frozen in the former diluent with FM and SP post-thawing media were 4/8 and 1/8 respectively, and for semen frozen BF3 diluent with FM and SP post-thawing extenders 1/8 and 5/8. The mean farrowing for the 32 animals inseminasted was 34-4%. Pregnancies for semen frozen in tris-fructose-EDTA and glycerolated at 30 or 5 degrees C were 5/12 and 4/12 respectively, and for single and double inseminations 6/12 and 3/12 respectively. Of 24 animals inseminated 37-5% farrowed.     

Effects of glycerol additions on post-thaw fertility of frozen rainbow trout sperm, with an emphasis on interaction between extender and cryoprotectant

The study was conducted to evaluate the effects of different extenders, cryoprotectants and glycerol additions on the post‐thaw fertility and interactions between extenders and cryoprotectants during cryopreservation. Semen was collected by abdominal stripping from 30 adult male rainbow trout (Oncorhynchus mykiss Walbaum, 1792) and diluted with three different extenders (Erdahl–Graham, Lahnsteiner, glucose‐based) containing 15% DMA, 15% DMSO, 15% DMA + 1% glycerol and 15% DMSO + 1% glycerol at a ratio of 1 : 2. Diluted samples were frozen as 0.1 ml pellets directly on dry ice (solid CO₂, −79°C). Eggs were pooled from 10 females. Fertilization was applied in plastic dishes and 600 eggs were used in each fertilization trial. Pellets were thawed in their own extenders (30°C) at a ratio of 1 : 10. 0.3% NaCl was used for activating motility. Sperm–egg ratio was approximately 3 × 10⁶ sp per egg. Experimental success was determined as the percentage of eyed‐eggs 25 days after fertilization. The highest eyed‐egg rate (49.3%) was obtained from semen frozen with glucose‐based extender containing 15% DMSO + 1% glycerol. Our results indicate that the glucose‐based extender containing DMSO is a useful combination, but that the addition of glycerol does not have a positive effect on post‐thaw fertility, and that interaction of the extender‐cryoprotectant is also important in the cryopreservation of rainbow trout semen.     

Comparison of different extenders for the cryopreservation of Atlantic salmon spermatozoa

Fifteen extenders were produced by adding dimethyl sulfoxide (DMSO) at 8, 10 or 12% of diluent volume to 5 diluents. All extenders were cooled to 4 degrees C. Pooled Atlantic salmon (Salmo salar ) semen with greater than 90% progressive motility was kept at 4 degrees C and added to each extender so that the semen was diluted 1:3 (semen:extender). The equilibration time was less than 5 minutes at 4 degrees C. The extended semen was loaded into 0.5-ml straws and was cooled from 4 degrees C to -90 degrees C at a rate of 30 degrees C per minute. The straws were then plunged into liquid nitrogen for storage. Fluorometry was used to determine the viability of the semen in each of the extenders after freezing and thawing. Cryopreservation of Atlantic salmon semen in Extender 3 (0.137 M NaCl, 0.011 M KCl, 0.004 M Na(2)HPO(4).7H(2)O, 7.5 g/l L-alpha-lecithin and 12% dimethyl sulfoxide) and Extender 12 (0.100 M KHCO(3), 0.0065 M reduced glutathione, 0.125 M sucrose and 12% dimethyl sulfoxide) resulted in significantly (P<0.05) lower percentages of dead spermatozoa than for the other extenders. Furthermore, there was a significantly (P<0.05) lower percentage of dead cells in Extender 3 than in Extender 12.