Effect of storage temperature, cooling rates and two different semen extenders on canine spermatozoal motility

Ejaculates were collected form three mixed-breed male dogs daily for 3 d. The semen was diluted in either a nonfat dried milk solid-glucose (NFDMS-G) or egg yolk citrate (EYC) extender at a concentration of 25 x 10(6) sperm/ml. The diluted samples were exposed to three different storage temperatures (35, 22 and 4 degrees C). Three cooling rates (-1.0, -0.3 and -0.1 degrees C/min) were also investigated at the lowest storage temperature (4 degrees C). The semen was evaluated for total motility, progressive motility and velocity at 0, 6, 12, 24, 48, 72, 96 and 120 h after collection by two independent observers. Interactions between extenders, temperatures and time after collection were found for each of the variables. Nonfat dried milk solid-glucose diluent was superior to EYC (P<0.05) in preservating sperm motility parameters that were evaluated for most of the observations. The evaluated sperm motility parameters were also significantly superior (P<0.05) in semen stored at 4 degrees C than at 35 or 22 degrees C for most of the observations. The progressive motility and velocity of sperm in semen cooled at 4 degrees C in NFDMS-G were higher (P<0.05) at the fast and medium cooling rates (-1.0 and -0.3 degrees C) than at the slow cooling rate (-0.1 degrees C/min) at 24 and 72 h, and at 48 h, respectively. In conclusion, the present study suggests that canine spermatozoal motility is well preserved when a NFDMS-glucose extender is added to the semen and the semen is cooled at a medium or fast rate to a storage temperature of 4 degrees C. Additional studies are needed to evaluate the fertility of semen stored in this manner.     

Determination of temperature and cooling rate which induce cold shock in stallion spermatozoa

Experiments were conducted to determine temperatures between 24 and 4 degrees C at which stallion spermatozoa are most susceptible to cold shock damage. Semen was diluted to 25 x 10(6) spermatozoa/ml in a milk-based extender. Aliquots of extended semen were then cooled in programmable semen coolers. Semen was evaluated by computerized semen analysis initially and after 6, 12, 24, 36 and 48 hours of cooling. In Experiment 1A, semen was cooled rapidly (-0.7 degrees C/minute) from 24 degrees C to either 22, 20, 18 or 16 degrees C; then it was cooled slowly (-0.05 degrees C/minute) to a storage temperature of 4 degrees C. In Experiment 1B, rapid cooling proceeded from 24 degrees C to either 22, 19, 16, or 13 degrees C, and then slow cooling occurred to 4 degrees C. Initiating slow cooling at 22 or 20 degrees C resulted in higher (P<0.05) total and progressive motility over the first 24 hours of cooling than initiating slow cooling at 16 degrees C. Initiation of slow cooling at 22 or 19 degrees C resulted in higher (P<0.05) total and progressive motility over 48 hours of cooled storage than initiation of slow cooling at 16 or 13 degrees C. In Experiment 2A, semen was cooled rapidly from 24 to 19 degrees C, and then cooled slowly to either 13, 10, 7 or 4 degrees C, at which point rapid cooling was resumed to 4 degrees C. Resuming the fast rate of cooling at 7 degrees C resulted in higher (P<0.05) total and progressive motility at 36 and 48 hours of cooled storage than resuming fast cooling at 10 or 13 degrees C. In Experiment 2B, slow cooling proceeded to either 10, 8, 6 or 4 degrees C before fast cooling resumed to 4 degrees C. There was no significant difference (P>0.05) at most storage times in total or progressive motility for spermatozoa when fast cooling was resumed at 8, 6 or 4 degrees C. In Experiment 3, cooling units were programmed to cool rapidly from 24 to 19 degrees C, then cool slowly from 19 to 8 degrees C, and then resume rapid cooling to storage temperatures of either 6, 4, 2 or 0 degrees C. Storage at 6 or 4 degrees C resulted in higher (P<0.05) total and progressive motility over 48 hours of storage than 0 or 2 degrees C.     

Effects of transport container and ambient storage temperature on motion characteristics of equine spermatozoa

This study was conducted to compare the cooling rates and storage temperatures within equine semen transport containers exposed to different ambient temperatures, and to evaluate the ability of these containers to preserve spermatozoal motility following 24 h of storage under these conditions. In Experiment 1, nonfat dried milk solids, glucose, sucrose, equine semen extender was divided into seven 40-mL aliquots and loaded into seven different semen transport containers: Equitainer I, Equitainer II, Equitainer III, ExpectaFoal, Bio-Flite, Lane STS, and Equine Express. After containers were loaded, they were subjected to one of three ambient storage temperatures: 1) 22 degrees C for 72 h, 2) -20 degrees C for 6 h followed by 22 degrees C for 66 h, or 3) 37 degrees C for 72 h. Cooling rates and storage temperatures of semen extender in each container were monitored with thermocouples and a chart recorder. In Experiment 2, semen from each of three stallions (3 ejaculates per stallion) was diluted to 25 x 10(6) spermatozoa/mL with semen extender, divided into 40 mL aliquots and loaded into transport containers as in Experiment I. Containers were subjected to one of three ambient storage conditions: 1) 22 degrees C for 24 h, 2) -20 degrees C for 6 h, followed by 22 degrees C for 18 h, or 3) 37 degrees C for 24 h. After 24 h of storage, spermatozoal motion characteristics (percentage of motile spermatozoa; MOT, percentage of progressively motile spermatozoa; PMOT, and mean curvilinear velocity; VCL) were evaluated using a computerized spermatozoal motion analyzer. Significant interactions were detected among storage conditions and semen transport containers for the majority of the temperature endpoints measured. When exposed to temporary ambient freezing conditions, the lowest temperatures attained by samples in containers ranged from -2.8 to 0.8 degrees C. Lowest temperature samples attained was not correlated (P > 0.05) with spermatozoal motility under any ambient condition. However, time below 4 degrees C was highly correlated (P < 0.05) with a reduction in spermatozoal motility. Mean cooling rates from 20 degrees C to 8 degrees C did not correlate with spermatozoal motility, except when containers were exposed to temporary freezing conditions. No container cooled samples below 6 degrees C in 22 degrees C or 37 degrees C environments except for the ExpectaFoal, in which samples fell below 4 degrees C under all ambient conditions. Ambient temperature affected MOT, PMOT and VCL of semen stored in all containers (P < 0.05) except for the Equitainer II in which motion characteristics remained high and were similar among all ambient temperatures (P > 0.05). Results suggest that stallion semen may be able to tolerate a wider range of cooling rates and storage temperatures than previously considered safe.     

Preservation of ejaculated and epididymal stallion spermatozoa by cooling and freezing

The suitability of ejaculated and epididymal stallion spermatozoa for cooled storage (5 degrees C) and cryopreservation was examined in 5 ejaculates from each of 6 stallions and in spermatozoa recovered from the cauda epididymidis after castration of these stallions. The percentage of progressively motile spermatozoa, examined by subjective estimation (cooled samples) or by computerized analysis (frozen-thawed samples), was used as parameter. In ejaculated semen samples containing 5 and 25% seminal plasma in a skim milk glucose extender, the lower amount of seminal plasma supported spermatozoal motility significantly better throughout storage at 5 degrees C. Addition of 5 or 25% seminal plasma to perfused epididymal spermatozoa (0% seminal plasma) resulted in a significant stimulation of spermatozoal motility by 25% seminal plasma at 0 h (P<0.05) and to a lesser extent at 24 and 48 h. Post-thaw motility of ejaculated as well as epididymal spermatozoa was not influenced by slow cooling to 15 degrees or 5 degrees C with or without glycerol prior to rapid freezing in liquid nitrogen vapor. During cooled storage, seminal plasma had a stimulatory effect on epididymal spermatozoa and depressed motility in ejaculated spermatozoa. Results on cryopreservation indicate that freezability of equine spermatozoa is already determined when spermatozoa leave the tail of the epididymis.     

Effect of centrifugation and partial removal of seminal plasma on equine spermatozoal motility after cooling and storage

The objective of this study was to determine if centrifugation and partial removal of seminal plasma would improve spermatozoal motility in semen from stallions whose whole ejaculates have poor tolerance to cooling and storage. Stallions were divided into two groups (n = 5/group) based on the ability of their extended semen to maintain spermatozoal motility after cooling and storage. Group 1 stallions ("good coolers") produced semen in which progressive spermatozoal motility after 24 h of cooling and storage was reduced by < or = 30% of progressive motility prior to storage. Group 2 stallions ("poor coolers") produced semen in which progressive spermatozoal motility after 24 h of cooling and storage was reduced by > or = 40% of progressive motility prior to storage. The sperm-rich portion of each ejaculate was divided into 4 aliquots. Two aliquots underwent standard processing for cooled transported semen and were examined after 24 and 48 h of cooling and storage in an Equitainer. The remaining two aliquots were diluted 1:1 with semen extender, then centrifuged at 400 x g for 12 min at room temperature. After centrifugation, approximately 90% of the seminal plasma was removed, and the sperm pellet was resuspended in extender to a final concentration of 25 to 50 x 10(6) sperm/mL. These aliquots were then packaged as for the non-centrifuged aliquots and examined after 24 and 48 h of storage. The spermatozoal motion characteristics in fresh semen and after 24 and 48 h of cooling and storage was determined via computer-assisted semen analysis. Centrifugation and partial removal of seminal plasma increased the percentage of progressively motile spermatozoa and limited the reduction in progressive spermatozoal motility of "poor cooling" stallions after 48 h of cooling and storage. Results of this study indicate that centrifugation and partial removal of seminal plasma is beneficial for stallions whose ejaculates have poor tolerance to cooling and storage with routine semen dilution and packaging techniques, especially if the semen is stored for > 24 h.     

Comparison of three containers used for the transport of cooled stallion semen

Three containers commonly used to transport cooled equine semen (Equitainer, ExpectaFoal and a Swedish-designed semen-transport container, previously called the Salsbro Box and now called Equine Express) were compared, using four ejaculates from each of three stallions. Each ejaculate was diluted to a spermatozoal concentration of 25 x 10(6)/ml with a nonfat dry milk-glucose extender containing amikacin sulfate (1 mg/ml) and potassium penicillin G (1000 units/ml). Extended semen was divided into three 40-ml aliquots for placement in each of the three semen-transport containers. The extended semen was stored in the containers for 24 h prior to analysis. Stored semen was warmed for 15 min at 37 degrees C, then video records of sperm motility were obtained for evaluation using a Hamilton-Thorne motility analyzer equipped with a stage warmer set at 37 degrees C. The temperature of 40-ml aliquots of semen extender stored in each container was also measured for 60 h using a copper-constantan thermocouple placed in the center of the stored samples. Intervals from onset of storage until sample temperature exceeded 10 degrees C during the warming phase were 27.5, 33.5 and 53 h, for the Expecta-Foal, Equine Express and Equitainer, respectively. Semen extender stored in the Equitainer compared most favorably to ideal cooling rates and storage temperatures published previously. Following a 24-h storage period, the mean percentages of motile, progressively motile, and rapidly motile spermatozoa, as well as the mean spermatozoal curvilinear velocity were similar (P > 0.05) among the three containers.     

Fertilizing capacity of equine spermatozoa stored for 24 hours at 5 or 20 degrees C

A breeding trial was conducted to evaluate the effect of in vitro storage time and temperature on fertilizing capacity of equine spermatozoa. Semen obtained from one stallion and diluted with skim milk-glucose extender was used to artificially inseminate 45 estrussynchronized mares. The mares were assigned to one of three treatment groups (15 mares per group): 1) insemination with fresh semen (collected within 0.5 h of use), 2) insemination with semen stored for 24 h at 20 degrees C or 3) insemination with semen stored for 24 h at 5 degrees C. The mares were inseminated daily during estrus, from the detection of a 35-mm follicle until ovulation, with 250 x 10(6) progressively motile spermatozoa (based on initial sperm motility of fresh semen). Semen samples (n = 35) were evaluated prior to insemination for percentages of total sperm motility (TSM), progressive sperm motility (PSM) and sperm velocity (SV). Single-cycle 15-d pregnancy rates. resulting from insemination with fresh semen, from fresh semen stored for 24 h at 20 degrees C or from semen stored for 24 h at 5 degrees C were the same (11 15 ; 73%). Mean diameters (mm) of 15-d embryonic vesicles were not different (P>0.05) among these three treatment groups (21.5 +/- 2.9, 19.6 +/- 2.6 and 20.5 +/- 3.6, respectively). Ten pregnant mares were aborted on Day 15 of gestation for use in another project. The pregnancy status of the 23 remaining pregnant mares was again determined at 35 to 40 d and 55 to 60 d of gestation. No pregnancy losses occurred during this time period. Mean TSM percentages were different (P<0.05) among the three groups: the fresh semen percentage was 89 +/- 2, semen stored for 24 h at 20 degrees C was 57 +/- 11 and semen stored for 24 h at 5 degrees C was 80 +/- 6. Similar differences were found for mean PSM and SV. Semen storage at either 20 or 5 degrees C for 24 h had no apparent effect on the fertilizing capacity of the extended semen samples; however, the reduction in all motility parameters tested was more dramatic in semen stored at 20 degrees C than that stored at 5 degrees C.     

Effects of centrifugation, glycerol level, cooling to 5 degrees C, freezing rate and thawing rate on the post-thaw motility of equine sperm

Five experiments evaluated the effects of processing, freezing and thawing techniques on post-thaw motility of equine sperm. Post-thaw motility was similar for sperm frozen using two cooling rates. Inclusion of 4% glycerol extender was superior to 2 or 6%. Thawing in 75 degrees C water for 7 sec was superior to thawing in 37 degrees C water for 30 sec. The best procedure for concentrating sperm, based on sperm motility, was diluting semen to 50 x 10(6) sperm/ml with a citrate-based centrifugation medium at 20 degrees C and centrifuging at 400 x g for 15 min. There was no difference in sperm motility between semen cooled slowly in extender with or without glycerol to 5 degrees C prior to freezing to -120 degrees C and semen cooled continuously from 20 degrees C to -120 degrees C. From these experiments, a new procedure for processing, freezing and thawing semen evolved. The new procedure involved dilution of semen to 50 x 10(6) sperm/ml in centrifugation medium and centrifugation at 400 x g for 15 min, resuspension of sperm in lactose-EDTA-egg yolk extender containing 4% glycerol, packaging in 0.5-ml polyvinyl chloride straws, freezing at 10 degrees C/min from 20 degrees C to -15 degrees C and 25 degrees C/min from -15 degrees C to -120 degrees C, storage at -196 degrees C, and thawing at 75 degrees C for 7 sec. Post-thaw motility of sperm averaged 34% for the new method as compared to 22% for the old method (P<0.01).     

Effects of semen fractionation and dilution ratio on equine spermatozoal motility parameters

Two experiments were conducted to examine the effects of semen fractionation and dilution ratio on motility parameters of stallion spermatozoa. In Experiment 1, three ejaculates from each of three stallions were divided into sperm-rich (SR) and sperm-poor (SP) fractions to determine the difference in sperm concentration. Mean sperm concentration in SR fractions (349.5 x 10(6)/ml) was greater (P < 0.001) than that of SP fractions (96.9 x 10(6)/ml). In Experiment 2, three ejaculates from each of two stallions were divided into SR and SP fractions. Fifty percent of the original volume of SR fractions was combined with 50% of the original volume of SP fractions for each ejaculate to represent total ejaculates. SR and total ejaculates were diluted with skim milk-glucose semen extender as follows: 1) no dilution, or dilution to 2) 100 x 10(6)sperm/ml, 3) 50 x 10(6)sperm/ml, or 4) 25 x 10(6)sperm/ml. Semen samples were evaluated at 0.5, 3, 6, 12, and 24 h postejaculation (25 degrees C storage temperature) for percentages of total spermatozoal motility (TSM) and progressive spermatozoal motility (PSM). Mean TSM was greater (P < 0.05) in SR ejaculates than total ejaculates at 12 and 24 h postejaculation. Mean TSM of undiluted semen was lower (P < 0.05) than other dilution ratios over all periods. Mean TSM was greater (P < 0.05) at a 25 x 10(6)sperm/ml dilution ratio than a 50 x 10(6)sperm/ml dilution ratio at 12 and 24 h postejaculation, and greater (P < 0.05) than a 100 x 10(6)sperm/ml dilution ratio from 3 to 24 h postejaculation. Similar patterns were found for PSM. Collection of SR ejaculates and dilution to 25 x 10(6)sperm/ml improved longevity of spermatozoal motility.     

Advances in cooled semen technology.

In the horse industry, milk or milk-based extenders are used routinely for dilution and storage of semen cooled to 4-8 degrees C. Although artificial insemination (AI) with chilled and transported semen has been in use for several years, pregnancy rates are still low and variable related to variable semen quality of stallions. Over the years, a variety of extenders have been proposed for cooling, storage and transport of stallion semen. Fractionation of milk by microfiltration, ultrafiltration, diafiltration and freeze-drying techniques has allowed preparation of purified milk fractions in order to test them on stallion sperm survival. Finally, a high protective fraction, native phosphocaseinate (NPPC), was identified. A new extender, INRA96, based on modified Hanks' salts, supplemented with NPPC was then developed for use with cooled/stored semen.Four experiments were conducted to compare INRA96 and milk-based extenders under various conditions of storage. The diluted semen was maintained under aerobic conditions when stored at 15 degrees C, and anaerobic conditions when stored at 4 degrees C. In experiment 1, split ejaculates from 13 stallions were diluted either in INRA96 extender then stored at 15 degrees C or diluted in Kenney or INRA82 extenders and then stored at 4 degrees C for 24h, until insemination. In experiment 2, semen from two stallions was extended in INRA96 then inseminated immediately or stored at 15 degrees C for 3 days until insemination. In experiment 3, semen from three stallions was diluted in INRA96 then stored at 15 or 4 degrees C for 24h until insemination, finally, in experiment 4, split ejaculates from four stallions were diluted in INRA96 or E-Z Mixin extenders then stored at 4 degrees C for 24h until insemination. Experiment 1 demonstrated that at 15 degrees C, INRA96 extender significantly improved pregnancy rate per cycle compared to Kenney or INRA82 extenders at 4 degrees C after 24h of storage (57%, n=178 versus 40%, n=171, respectively; P<0.01). Experiment 2 showed that semen stored at 15 degrees C for 3 days can achieve pregnancy at a fertility rate per cycle of 48% (n=52) compared to 68% (n=50, immediate insemination, P=0.06). Experiment 3 demonstrated that INRA96 extender can be as efficient at 15 degrees C (54%, n=37) as at 4 degrees C (54%, n=35) after 24h of storage. Finally, experiment 4 showed that INRA96 extender used at 4 degrees C (59%, n=39) seems to improve fertility per cycle compared to E-Z Mixin at 4 degrees C (49%, n=39, P=0.25), but this result has to be confirmed.These results demonstrate that semen diluted in INRA96 extender and stored at 15 degrees C can be an alternative to semen diluted in milk-based extenders and stored at 4 degrees C for "poor cooler" stallions. Furthermore, INRA96 extender can be as efficient at 15 degrees C as at 4 degrees C, for preserving sperm motility and fertility.     

Effects of cooling and warming conditions on post-thawed motility and fertility of cryopreserved buffalo spermatozoa.

The principal objective of this study was to derive an improved procedure for cryopreservation of swamp buffalo (Bubalus bubalis) spermatozoa. Experiments were conducted to determine effects of cooling rate, intermediate plunge temperature and warming rate on motility and acrosome integrity of spermatozoa. Spermatozoa were obtained from three bulls (three ejaculates/bull) and were subjected to nine cooling conditions before being frozen in liquid nitrogen: cooling at 10, 20, or 30 degrees C/min each to -40, -80, or -120 degrees C before being plunged into liquid nitrogen. The spermatozoa frozen under a given condition were then thawed either at 1000 or 200 degrees C/min. Cooling rate, intermediate temperature and warming rate significantly affected survival of spermatozoa obtained from the three bulls. Cooling spermatozoa from 4 to -120 degrees C either at 20 or 30 degrees C/min yielded better progressive motility compared to other cooling conditions (50 versus 30%). Rapid warming was superior to slow warming. In an additional study, motility and fertility of spermatozoa frozen after being cooled to -120 degrees C at 20 degrees C and 30 degrees C/min and those frozen by a standard protocol used routinely for semen processing were assessed. Progressive motility of cryopreserved spermatozoa cooled at 20 degrees C and 30 degrees C/min was 40%, while that of spermatozoa cryopreserved using a standard protocol was 25%. A total of 178 buffalo cows were inseminated with cryopreserved spermatozoa obtained from one bull, and their pregnancy status was assessed 60 days later by rectal palpation. Out of the 60, 26 (43%) and 23 of 58 (40%) cows inseminated with sperm cooled at 20 and 30 degrees C/min, respectively, became pregnant, whereas 17 of 60 (28%) cows inseminated with sperm frozen by a standard protocol became pregnant. This study demonstrates that an effective cryopreservation procedure for buffalo spermatozoa can be derived by systematic examination of various cryobiological factors.     

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%.     

Lipase activity in stallion seminal plasma and the effect of lipase on stallion spermatozoa during storage at 5 degrees C

Previous studies have demonstrated a detrimental effect of seminal plasma on the maintenance of motility of cooled equine spermatozoa; however, the mechanism for the adverse effect of seminal plasma during cooled storage remains undetermined. In goats, a glycoprotein component of bulbourethral gland secretion contains lipase activity that is detrimental to sperm motility when stored in skim milk-based extenders. The objective of the current study was to determine the amount of lipase activity in stallion seminal plasma and to determine the effect of added lipase on spermatozoal motility during cooled semen storage. In the first experiment, seminal plasma (1.0 ml) was assayed for lipase activity based upon hydrolysis of triglycerides (olive oil substrate) into free fatty acids and subsequent titration of pH change (SigmaDiagnostic Lipase Kit). Lipase activity in stallion seminal plasma was 0.36 +/- 0.02 Sigma units/ml, (mean + S.E.M.; n = 16 ejaculates from six stallions). In the second experiment, equine semen (three ejaculates from each of four stallions) was divided into five treatment aliquots. In Treatment 1, semen was extended 1:3 with nonfat dried skim milk extender (NFDSM). In treatment groups 2 through 5, spermatozoa were washed by centrifugation (300 x g for 15 min) and resuspended in NFDSM to a final concentration of 25 x 10(6) spermatozoa/ml. Porcine pancreatic lipase (pPL) was added to Treatment 3 (10 pPL units/ml), Treatment 4 (100 pPL units/ml) and Treatment 5 (100 pPL units/ml, heat inactivated at 100 degrees C for 5 min) while Treatment 2 had no pancreatic lipase added and served as the control. Samples were cooled slowly to 5 degrees C, and stored at 5 degrees C until evaluation. Sperm motility was evaluated at time 0, 24, 48 and 72 h by computerized semen analysis, and data were analyzed via repeated measures ANOVA. The addition of 100 units/ml but not 10 units/ml of pPL decreased (P < 0.01) total and progressive motility of stored sperm. Heat-inactivated pPL (Treatment 5) did not significantly decrease motility of spermatozoa during storage. Because the lipase activity assayed (Sigma units) and the lipase activity added to cooled semen (pPL units) were not equivalent, pPL was assayed in the Sigma Diagnostic Lipase assay. The relationship between Sigma Units (Y) and pPL units (X) appeared to be a log-linear relationship with log(Y) = -0.912 + 0.007X; R2 = 0.90. Mean lipase activity assayed in stallion seminal plasma was equivalent to approximately 64 pPL units/ml. These data suggest that endogenous lipase activity in stallion seminal plasma may be a factor in the adverse effects of seminal plasma on cooled spermatozoa in some stallions.     

Cooling rates,storage temperatures and fertility of extended equine spermatozoa

Two experiments were designed to evaluate cooling rates and storage temperatures for stallion spermatozoa extended in caprogen (CAP), Cornell University extender (CUE), heated skimmilk (SM) and a nonfat-dried milk solids glucose extender (NFDMS-glucose). In Experiment 1, each extender was evaluated in a separate but similar 4 × 4 × 6 factorial trial using two ejaculates from each of six stallions. Aliquots of 66 × 10⁶ spermatozoa were transferred to each of 16 coded tubes and extended to 6 ml with SM, CAP, CUE or NFDMS-glucose. Four tubes of extended semen were either plunged into 5C water or cooled at a rate of ?1.0, ?0.5, or ?0.2C/min. Within each treatment, one tube of extended semen was maintained at 20C, 15C, 10C or 5C. Progressive spermatozoal motility was estimated immediately after dilution (0 h) and at 4, 8, 12, 24 and 36 h. Regardless of extender, all three slower cooling rates were superior (P<0.05) to plunging to 5C; storage temperatures of 20C and 15C were superior (P<0.05) for maintaining spermatozoal motility. Experiment 2 was designed so that all extenders could be evaluated simultaneously. Since CUE resulted in an immediate depression of spermatozoal motility, it was not evaluated further. Semen was collected from 12 stallions and each ejaculate was extended in SM, CAP and NFDMS-glucose. Semen was cooled at ?1.0C/min and maintained at either 20C or 15C. Spermatozoal motility was assessed as in Experiment 1. Overall, the CAP and NFDMS-glucose extenders were superior (P<0.05) to SM for maintenance of spermatozoal motility. Storage at 20C or 15C resulted in similar (P>0.05) spermatozoal motility. Two fertility trials compared the use of SM and NFDMS-glucose extenders. Embryo recovery 6 days post-ovulation (Experiment 3) and pregnancy rate 50 days postestrus (Experiment 4) was similar (P>0.05) for mares inseminated with spermatozoa extended in SM or NFDMS-glucose.     

Benefits of TEMPOL on ram semen motility and in vitro fertility: a preliminary study

Extending the preservation time of fresh semen is an important goal in artificial insemination programs particularly for ewes in natural oestrus, where insemination periods are longer than for ewes synchronized with hormonal treatments. The aim of this study was to evaluate the effect of the antioxidant TEMPOL (4-hydroxy-2,2,6,6-tetramethylpiperidine-1-oxyl) on the maintenance in long term storage of ram semen motility and fertility. Semen from Sarda breed rams was diluted in two extenders: sodium citrate buffer with TEMPOL and skimmed milk, used as control. Samples diluted with TEMPOL were cooled at either 15 degrees C or 22 degrees C, while those diluted with skimmed milk were cooled at 15 degrees C. Each sample was divided into four stocks, and stored for different times (5 min, 24, 48 and 72 h). Three aliquots were taken from each stock for every storage period. One was immediately evaluated under microscope; one was used for in vitro fertilization; one was incubated for 2 h in controlled humidified atmosphere (5% CO2, 7% O2 and 88% N2) at 39 degrees C, then evaluated for motility and utilized for in vitro fertilization. Ram semen diluted with media containing TEMPOL demonstrated increased motility, fertility and an improved protective effect when it was stored at 15 degrees C.     

Effects of dead spermatozoa on motion characteristics and membrane integrity of live spermatozoa in fresh and cooled-stored equine semen

The aim of this study was to determine if dead spermatozoa reduced motility or membrane integrity of live spermatozoa in fresh and cooled-stored equine semen. Three ejaculates from each of three stallions were centrifuged and virtually all seminal plasma was removed. Spermatozoa were resuspended to 25 x 10(6) spermatozoa/ml with EZ-Mixin CST extender and 10% autologous seminal plasma, then divided into aliquots to which 0 (control), 10, 25, 50, or 75% (v/v) dead spermatozoa were added. Dead spermatozoa preparations contained 25 x 10(6) spermatozoa/ml and 10% seminal plasma from pooled ejaculates of the three stallions, in EZ-Mixin CST extender. Spermatozoa were killed in the pooled ejaculates by repeated freezing and thawing, then stored at -20 degrees C until warmed to 37 degrees C and mixed with aliquots of fresh spermatozoa to be cooled and stored in an Equitainer for 24h. Motion characteristics (% total motility (MOT), % progressive motility (PMOT), and mean curvilinear velocity (VCL)) for fresh and 24h cooled samples were determined using a computerized spermatozoal motion analyzer. The presence of up to 75% dead spermatozoa did not adversely affect MOT or PMOT of live spermatozoa in either fresh or cooled-stored semen. However, VCL and the percentage of membrane-intact spermatozoa were reduced compared to control samples when 75% (v/v) dead spermatozoa were added. Membrane integrity, as assessed by staining with carboxyfluoresein diacetate-propidium iodide, was highly correlated (r>0.8; P<0.001) with MOT and PMOT in both fresh and cooled-stored semen samples. Results of this study have application to the processing of both cooled and frozen equine semen.     

Development of a chemically defined ram semen diluent (RSD-1)

A chemically defined ram semen diluent (RSD-1) has been developed. RSD-1 maintained spermatozoal motility of diluted semen containing approximately 800 million spermatozoa ml⁻¹ during cooling to 15°C and its storage for 1 h. Motility was further maintained when the cooled semen was diluted to 100 million spermatozoa ml⁻¹ and incubated at 38°C for about 24 h. In contrast, a conventional milk-based diluent supported motility for less than 6 h at 38°C. Spermatozoal motility was influenced by the buffering capacity, osmolarity and the presence or absence of macromolecules and calcium in the chemically defined diluent. Among the organic buffers tested, MOPS (3-(N-morpholino)propanesulphonic acid) had a marked influence on the maintenance of spermatozoal motility. The presence of MOPS also overcame the detrimental effects of 2 mM calcium in Krebs Ringer improved (KR-I) buffer.     

Influence of extender, cryoperservative and seminal processing procedures on postthaw motility of canine spermatozoa frozen in straws

Experiments were conducted to evaluate two extenders (egg-yolk Tris and egg-yolk lactose), varying concentrations of two cryopreservatives (glycerol and dimethyl sulfoxide), and rates for cooling to 5 degrees C, cooling from 5 to -100 degrees C, and warming for canine spermatozoa packaged in 0.5-ml French straws. At optimal concentrations of glycerol, egg-yolk Tris extender was superior to egg-yolk lactose in preserving spermatozoal motility. Addition of dimethyl sulfoxide, alone or in combination with glycerol in either extender, was not beneficial to spermatozoal survival after thawing. Canine spermatozoa withstood a range of cooling and equilibration times with no detrimental effect on spermatozoal motility prior to freezing. However, there were differences in spermatozoal motility immediately after thawing; these differences were variable, resulting in a cooling time by equilibration time interaction. Spermatozoal motility after thawing was best preserved by freezing in egg-yolk Tris extender containing 2-4% glycerol, using a moderate rate of cooling from 5 to -100 degrees C (-5 degrees C/min from 5 to -15 degrees C, then -20 degrees C/min from -15 to -100 degrees C). Three of 12 bitches inseminated intravaginally with semen frozen using this protocol became pregnant.     

Storage of Chinchilla lanigera Semen at 4°C for 24 or 72 h with Two Different Cryoprotectants

The objectives of this study were to: (a) test the functional activity of Chinchilla lanigera spermatozoa suspended in either glycerol or ethylene glycol, cooled to 4 degrees C, and stored for 24 or 72 h and (b) investigate, after these cooling periods, the effects of incubating sperm at 37 degrees C (for 4 h) upon sperm functional activity. The ejaculate was mixed with the cryoprotectant medium (at 1 M final concentration) and cooled to 4 degrees C. After warming, sperm motility, sperm viability, hypoosmotic swelling test results, and acrosomal integrity were significantly higher for samples containing ethylene glycol than for those in glycerol, stored for 24 or 72 h, and then assayed after 0 or 4 h incubation at 37 degrees C. A significant reduction of sperm motility and viability was detected only when the glycerol cryoprotectant agent was employed, compared to the fresh samples. These results clearly indicate that under our experimental conditions, ethylene glycol is a better protectant for sperm storage than glycerol.     

Equine spermatozoal motility and fertility associated with the incorporation of d-(+)-mannose into semen extender

Mannose is capable of decreasing bacterial attachment to the uterine mucosa in mares. Bacteria gain entry into the mare's uterus during breeding; therefore, a practical method to deliver mannose to the uterus is to incorporate it into semen extenders. The effect of mannose on spermatozoal motility and subsequent sperm fertilizing capability is unknown. The present study evaluated progressive spermatozoal motility in semen extender formulations incorporating mannose and assessed the fertility of mares inseminated with a mannose-containing semen extender. In Experiment 1, progressive spermatozoal motility in extender mixtures containing 0 mannose (control), 25, 37 or 49 mg/mL mannose was evaluated at 20 degrees C or 5 degrees C holding temperatures for 0, 12, 24 and 48 h post-dilution. Measures were repeated three times using five stallions of proven fertility. High concentrations of mannose in the extender affected progressive motility beyond the time and temperature effects noted in the controls. Extender containing only mannose sugar (49 mg/mL) displayed an immediate depression in progressive motility compared with controls (45.5% versus 62.9%, respectively; P<0.001). The 37 mg/mL mannose extender had a less dramatic decrease in motility (P<0.05) and only after storage at 5 degrees C for > or =12h (48.7% versus 58.0%, respectively). Extender with 25 mg/mL mannose performed no differently than the control formulation under all conditions. In Experiment 2, two groups of mares (n=11 each) were inseminated with 500 x 10(6) progressively motile spermatozoa extended in a traditional skim milk (control) extender or the 37 mg/mL mannose extender preparation. A single-cycle pregnancy rate of 72% was achieved by both groups. Present data suggest that a semen extender containing up to 37 mg/mL mannose could maintain motile spermatozoa for on-farm use and 25 mg/mL mannose concentrations preserved motility during long-term cooling. Likewise, sperm extended with up to 37 mg/mL of mannose had the same fertilizing capability as sperm in traditional extender mixtures.