Effects of cooling rate and storage temperature on equine spermatozoal motility parameters

Two experiments were conducted to examine the effects of cooling rate and storage temperature on motility parameters of stallion spermatozoa. In Experiment 1, specific cooling rates to be used in Experiment 2 were established. In Experiment 2, three ejaculates from each of two stallions were diluted to 25 x 10(6) sperm/ml with 37 degrees C nonfat dry skim milk-glucose-penicillin-streptomycin seminal extender, then assigned to one of five treatments: 1) storage at 37 degrees C, 2) storage at 25 degrees C, 3) slow cooling rate to and storage at 4 degrees C, 4) moderate cooling rate to and storage at 4 degrees C, and 5) fast cooling rate to and storage at 4 degrees C. Total spermatozoal motility (TSM), progressive spermatozoal motility (PSM), and spermatozoal velocity (SV) were estimated at 6, 12, 24, 48, 72, 96 and 120 h postejaculation. The longevity of spermatozoal motility was greatly reduced when spermatozoa were stored at 37 degrees C as compared to lower spermatozoal storage temperatures. At 6 h postejaculation, TSM values (mean % +/- SEM) of semen stored at 37 degrees C, slowly cooled to and stored at 25 degrees C or slowly cooled to and stored at 4 degrees C were 5.4 +/- 1.1, 79.8 +/- 1.6, and 82.1 +/- 1.6, respectively. Mean TSM for semen that was cooled to 4 degrees C at a slow rate was greater (P<0.05) than mean TSM of semen cooled to 4 degrees C at a moderate rate for four of seven time periods (6, 24, 72 and 120 h), and it was greater (P<0.05) than mean TSM of semen cooled to 4 degrees C at a fast rate for five of seven time periods (6, 12, 24, 72 and 120 h). Mean TSM of semen cooled to 4 degrees C at a slow rate was greater (P<0.05) than mean TSM of semen cooled to 25 degrees C for five of seven time periods (24 to 120 h). A similar pattern was found for PSM. Mean SV of semen cooled to 4 degrees C at a slow rate was greater (P<0.05) than mean SV of semen cooled to 25 degrees C for all time periods. A slow cooling rate (initial cooling rate of -0.3 degrees /min) and a storage temperature of 4 degrees C appear to optimize liquid preservation of equine spermatozoal motility in vitro.     

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.     

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.     

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.     

Advances in cryopreservation of stallion semen in modified INRA82.

In the procedure used in this paper, semen was first diluted in INRA82+2% egg yolk (E1) at 37 degrees C. Before or after cooling to 4 degrees C, semen was centrifuged and diluted in E1+2.5% glycerol (E2). Cooled semen was frozen in 0.5-ml straws. Straws were thawed at 37 degrees C for 30s. For fertility trials, frozen ejaculates were used only if total post-thaw motility was above 35%. Most mares were inseminated two times before ovulation with 400 x 10(6) total spermatozoa every 24h. This paper presents post-thaw motility (CASA) and fertility results obtained when some steps of the procedure were evaluated.Use of the first three jets of ejaculate before the centrifugation did not improve post-thaw motility compared to use of the whole semen (25% versus 25%, 2 stallions x 12 ejaculates, P>0.80). When the first dilution was performed in E2 at 22 degrees C instead of in E1 at 37 degrees C, motility was slightly improved (38% versus 36%, n>283 ejaculates per group, P<0.04) but fertility was similar (51% versus 58%, n>196 cycles per group, P>0.10). Coating the spermatozoa with 0.5, 1, 2, 4 and 8mM of Concanavalin A resulted in unchanged post-thaw motility (6 stallions x 3 ejaculates, P>0.05). The extender E2 was modified or supplemented with different substances. Increasing egg yolk concentration from 2 to 4% (v/v) did not increase post-thaw motility (42% versus 34%, 6 stallions x 2 ejaculates, P>0.05). Different glycerol concentrations (range: 1.7-3.7%) had no significant effect on post-thaw motility even though 2.4-2.8% resulted in a nonsignificant higher motility (7 stallions x 2 ejaculates, P>0.05). Glutamine at 50mM in E2 improved post-thaw motility compared with no glutamine (49% versus 46%, n>584 ejaculates per group, P<0.0001) but not fertility (53% versus 54%, n>451 cycles per group, P>0.80). Thawing at 75 degrees C for 10s slightly increased motility after 120 min at 37 degrees C (6 stallions x 1 ejaculate, P<0.05) but no effect on per-cycle fertility was noted (32% (19 cycles) versus 41% (17 cycles), P>0.50). When post-thaw dilution was performed using a fixed molarity multi-step system (25 mOsm per step) from various osmolarities (900-690 mOsm) to 365 mOsm, motility was unaffected compared with dilution in one step (36% versus 38%, 6 stallions x 1 ejaculate, P>0.20).     

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.     

Semen parameters and level of microsatellite heterozygosity in Noriker draught horse stallions

It was the aim of the present study to determine physiological values for different semen parameters in an endangered draught horse breed, the Austrian Noriker. Because small population size is often believed to cause a decrease in fertility and/or semen quality through inbreeding and a reduction in genetic variation, the general genomic heterogeneity of the breed was estimated on the basis of microsatellite variation and correlated to semen parameters. Semen could be collected from 104 of 139 stallions with semen collection being more often successful in younger stallions. Mean volume of ejaculates was 90.8+/-55.1 ml, density 243+/-114 x 10(6)ml(-1), total sperm count 21.0+/-23.7 x 10(9), percentage of morphologically normal spermatozoa 38+/-18% and total motility 50+/-23%. Total sperm count and semen motility were significantly affected by age. Blood samples of 134 stallions were analysed for 12 microsatellite DNA markers. Genotypes of 110 stallions with at least 11 successfully typed markers were used for calculation of heterozygosity. A total of 82 alleles was identified with a mean of 6.8 alleles per marker. Heterozygosity varied between 35 and 76% for the different markers, mean heterozygosity was calculated to 63%. No correlation between heterozygosity and semen parameters was found.     

Effect of L-carnitine administration on the seminal characteristics of oligoasthenospermic stallions

The effect of orally administered l-carnitine on the quality of semen obtained from stallions with different semen qualities was investigated. Four stallions with proven fertility (high motility group, HM) and with normal seminal characteristics (>50% progressive motility and > 80 x 10(6) spermatozoa/ml), and four questionable breeders (low motility group, LM) with <50% of sperm progressive motility and < 80 x 10(6) spermatozoa/ml, received p.o. 20 g of l-carnitine for 60 days. Blood and semen samples were collected before treatment (T0) and after 30 (T1) and 60 days (T2). Semen evaluation were performed on five consecutive daily ejaculates (n = 120 ejaculates) and conventional semen analysis was carried out on each ejaculate, both at collection and after refrigeration for 24, 48, and 72 h. Furthermore l-carnitine, acetylcarnitine, pyruvate, and lactate concentrations, and carnitine acetyltransferase activity (CAT) were determined both in raw semen and seminal plasma. There were an increase in progressive motile spermatozoa only in the LM group (26.8 +/- 12.9, 39.1 +/- 15.5, and 48.8 +/- 8.6 for T0, T1, and T2, respectively). Free seminal plasma carnitine concentration was higher in the LM group compared to the HM one. Both pyruvate and lactate were higher in the LM group. Raw semen and seminal plasma carnitine and acetylcarnitine levels correlate positively with both sperm concentration and progressive motility; moreover, acetylcarnitine content was positively correlated with total motile morphologically normal spermatozoa. In conclusion, oral administration of l-carnitine to stallions with questionable seminal characteristics may improve spermatozoa kinetics and morphological characteristics; whereas, it seem to be ineffective in normospermic animals.     

Effect of semen collection practices on sperm characteristics before and after storage and on fertility of stallions

This study analyzed effects of different methods and intervals of semen collection on the quantity and quality of fresh, cool-stored, and frozen-thawed sperm and fertility of AI stallions. In Experiment 1, ejaculates were obtained from six stallions (72 ejaculates per stallion) using fractionated versus non-fractionated semen collection techniques. Initial sperm quality of the first three jets of the ejaculate was not different from that of total ejaculates. Centrifugation of sperm-rich fractions before freezing improved post-thaw motility and sperm membrane integrity when compared to non-centrifuged sperm-rich fractions or non-fractionated centrifuged ejaculates (P<0.05). In Experiment 2, semen from four stallions (60-70 ejaculates per stallion) was collected either once daily or two times 1h apart every 48 h. The first ejaculates of double collections had significantly higher sperm concentrations, percentages of progressively motile sperm (PMS) after storage for 24h at 5 degrees C and lower percentages of midpiece alterations than single daily ejaculates. Semen collected once daily showed significantly lower values of live sperm after freezing and thawing than the first ejaculate of two ejaculates collected 1h apart every 48 h. In Experiment 3, semen was collected from 36 stallions (> or =12 ejaculates per stallion) during the non-breeding season and the time to ejaculation and the number of mounts was recorded. When time to ejaculation and the number of mounts increased, volume and total sperm count (TSC) also increased (P<0.05), whereas a decrease was observed in sperm concentration, percentage of PMS after storage for 24 h at 5 degrees C, percentage of membrane-intact sperm in fresh semen (P<0.05) as well as motility and percentage of membrane-intact sperm of frozen-thawed sperm (P<0.05). In Experiment 4, AI data of 71 stallions were retrospectively analyzed for the effect of number of mounts per ejaculation and frequency, time interval of semen collections on pregnancy, and foaling rates (FRs) of mares. Semen volume increased, but sperm concentration and percentage of PMS after 24-h cool-storage decreased with increasing number of mounts on the phantom (P<0.05). A statistically significant inter-relationship was demonstrated between frequency and interval of semen collection and FR. Mares inseminated with stallions from which semen was collected frequently (> or =1 on an average per day) showed significantly higher FRs than mares inseminated with semen from stallions with a daily collection frequency of 0.5-1 or <0.5. FR of mares inseminated with stallions having 0.5-1 days between semen collections was significantly better than FR of mares that were inseminated with stallions having semen collection intervals of 1-1.5 days or >2.5 days.     

Seminal traits, suitability for semen preservation and fertility in the native Portuguese horse breeds Puro Sangue Lusitano and Sorraia: Implications for stallion classification and assisted reproduction

The Puro Sangue Lusitano (PSL) is the major national breed of horse in Portugal, but no studies exist on its seminal characteristics, or on the possibility of conserving semen for future use. The aim of this study was to evaluate semen parameters, fertility and the aptness to semen preservation in Lusitano Stallions. In order to compare characteristics defined by a single or by multiple semen collections per stallion 152 ejaculates obtained from 152 Lusitano stallions presented at an annual breeding soundness examination as well as data related to 371 ejaculates obtained from 9 PSL were analyzed. These latter samples were also evaluated in terms of their possible use in assisted reproduction and were compared with 113 ejaculates obtained from 4 Sorraia horses, a rare and endangered Portuguese breed. The percentage of motile spermatozoa (PMS) was assessed after collection (AC), after semen dilution (AD) and at 24h of cool-storage. Mean values obtained for sperm motility and morphology and semen pH observed after semen collection differ significantly (P<0.05) between single collection/multiple stallions and multiple collections/limited stallions, and no age related effects were detected. Overall, Lusitano semen quality was comparable to that of related breeds, while Sorraia stallions had very poor semen quality. The response to cool-storage of diluted semen samples differed among stallions and breeds, and the best results for progressive motile sperm cells at 24h were in a range of 35-53% for PSL stallions and were lower for Sorraia stallions. Fertility rates obtained with artificial insemination (AI) averaged at 85% for PSL. With the exception of PMS AC, sperm vitality and semen pH no other seminal trait seemed to influence fertility rates in the Lusitano breed.     

Fertility of stallion semen processed, frozen and thawed by a new procedure

The fertility of frozen-thawed and fresh semen from three stallions was compared in a trial using a randomized block design and 90 mares for 108 cycles. Semen was collected every third day, diluted to 50 x 10(6) sperm/ml with a citrate-based centrifugation medium, and centrifuged. The cells were resuspended at 700 x 10(6) progressively motile sperm/1.0 ml of added lactose-EDTA-egg yolk extender containing 4% glycerol, packaged by placing 0.55 ml into polypropylene straws, and frozen. Semen was thawed by immersion in 75 degrees C water for 10 sec. All of the 43 ejaculates collected were frozen, but 21 were discarded because progressive sperm motility was <35% immediately after thawing or <40% after 30 min of incubation at 37 degrees C. semen from the same stallions was collected daily for inseminations with fresh semen. Semen containing 200 x 10(6) progressively motile sperm was added to 10 ml of heated skimmilk extender. Mares were inseminated daily starting on the third day of estrus or when a >/=4-cm follicle was detected, whichever came later, and continuing through the end of estrus or for nine days. Based on palpation per rectum on day 50 postovulation, the pregnancy rates from inseminations during one estrus were 50, 56 and 61% with frozen semen and 67, 67 and 61% with fresh semen (P>0.05) from the three stallions, respectively. Thus, mean pregnancy rate with frozen semen was 86% of the rate attained with fresh semen.     

Generation of reactive oxygen species by equine neutrophils and their effect on motility of equine spermatozoa

Contaminating leukocytes in the ejaculate are an important source of reactive oxygen species (ROS) in human semen. When present in sufficient numbers, they can have a detrimental influence on sperm function in humans. Unfortunately, there is little published information regarding the importance of leukocytes in stallion semen. The objectives of this study were to determine the production of hydrogen peroxide (H2O2) by activated equine neutrophils and to examine the effect of this ROS production on equine sperm motility in vitro. Motile equine spermatozoa (two ejaculates each from four stallions) and peripheral blood neutrophils were isolated on discontinuous Percoll gradients, washed and resuspended in a modified Tyrode's medium. Spermatozoa (25 x 10(6)/ml) were incubated for 30 min at 38 C with neutrophils (0,0.5 x 10(6),1 x 10(6), 5 x 10(6) and 10 x 10(6)/ml) activated by either the protein kinase C agonist, 12-myristate, 13-acetate phorbol ester (PMA; 100 nM) or the leukocyte chemotactic peptide, formyl-methionyl-leucyl-phenylalanine (FMLP; 0.1 mM). Sperm motility was determined by computer-assisted semen analysis (CASA) at time 0 min (T0) and time 30 min (T30), and H2O2 was measured at T30 with the Amplex Red assay kit. At T30, there was a significant (P < 0.01) increase in H2O2 with the addition of 5 x 10 and 10 x 10(6) neutrophils/ml activated by FMLP (0.76 +/- 0.3 and 0.99 +/- 0.4 microM, respectively, versus 0.0024 +/- 0.002 microM in sperm alone), and this increase was associated with a significant (P < 0.001) decrease in total motility (52 +/- 5.1 and 48 +/- 6.0%, respectively, versus 80 +/- 4.7% in sperm alone). At T30, there was also a significant (P < 0.001) increase in H2O2 with the addition of 5 x 10(6) and 10 x 10(6) neutrophils/ml activated by PMA (1.88 +/- 0.2 and 2.07 +/- 0.3 microM, respectively, versus 0.0009 +/- 0.0006 microM in sperm alone). The results of this study demonstrate that 5 x 10(6) activated neutrophils/ml are sufficient to impair equine sperm motility in vitro.     

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.     

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.     

Comparison of ticarcillin and piperacillin in Kenney's semen extender

Ticarcillin and piperacillin were compared to determine their effect on sperm motility and bacterial growth of equine semen samples diluted in Kenney's glucose skim milk semen extender. Each ejaculate (n=11) was divided into three portions and glucose skim milk semen extender solution was added. The control semen extender solution contained extended semen and no antibiotic, whereas ticarcillin and piperacillin solutions contained extended semen plus 1.0mg/mL of ticarcillin or piperacillin, respectively. An aliquot was removed (1h after collection) to evaluate sperm motility and microbial concentration. All three solutions were stored at 4 degrees C and aliquots were obtained at 24 and 48 h to determine sperm motility and microbial concentration. Mean percentages of motile and progressively motile sperm did not differ significantly among control and antibiotic-containing solutions after storage. Control-extended semen samples from ejaculates of stallions (n=11) were contaminated with aerobic gram-positive and gram-negative bacteria. In solutions that contained either antibiotic, growth of these microbes was inhibited after 1, 24, and 48 h at 4 degrees C. Semen samples from stallions (n=5) were extended with Kenney's glucose skim milk extender containing no antibiotic, ticarcillin or piperacillin and then inoculated with approximately 5 x 10(2)CFU/mL Klebsiella pneumoniae or Pseudomonas aeruginosa; there was no significant difference between antibiotics in the inhibition of microbial growth. In conclusion, piperacillin was an appropriate alternative to ticarcillin in extenders for equine semen.     

Influence of ejaculation frequency of stallions on characteristics of semen and output of spermatozoa.

Approximately 1 week was required to stabilize the extragonadal sperm reserves in stallions ejaculated daily for 10 weeks. The true daily sperm output of a stallion was equal to the mean daily sperm output of seven ejaculates +/- 1-35 X 10(9) spermatozoa. Mean concentrations of spermatozoa/ml and number of spermatozoa/ejaculate were higher (P less than 0-01) for X1 and X3/week ejaculation frequencies than for a X6/week frequency. Sperm output/week was nearly identical for a X6/week frequency. Sperm output/week was nearly identical for the X3 and X6 frequencies and higher (P less than 0-01) than the X1 frequency. Increase of ejaculation frequency from one to two ejaculates/day twice weekly significantly (P less than 0-01) raised the output of spermatozoa/week. Gel-free semen volume, spermatozoa/ml, and number of spermatozoa/ejaculate were higher (P less than 0-01) in the first, than in the second, ejaculate. Collection of semen on alternate days would be a practical ejaculation frequency for inseminating mares. Two ejaculates collected twice a week would be a practical ejaculation frequency for long-term storage of stallion semen.     

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.     

Effect of cryopreservation methods and precryopreservation storage on bottlenose dolphin (Tursiops truncatus) spermatozoa

Research was conducted to develop an effective method for cryopreserving bottlenose dolphin (Tursiops truncatus) semen processed immediately after collection or after 24-h liquid storage. In each of two experiments, four ejaculates were collected from three males. In experiment 1, three cryopreservation methods (CM1, CM2, and CM3), two straw sizes (0.25 and 0.5 ml), and three thawing rates (slow, medium, and fast) were evaluated. Evaluations were conducted at collection, prefreeze, and 0-, 3-, and 6-h postthaw. A sperm motility index (SMI; total motility [TM] x % progressive motility [PPM] x kinetic rating [KR, scale of 0-5]) was calculated and expressed as a percentage MI of the initial ejaculate. For all ejaculates, initial TM and PPM were greater than 85%, and KR was five. At 0-h postthaw, differences in SMI among cryopreservation methods and thaw rates were observed (P < 0.05), but no effect of straw size was observed. In experiment 2, ejaculates were divided into four aliquots for dilution (1:1) and storage at 4 degrees C with a skim milk- glucose or a N-tris(hydroxymethyl)methyl-2-aminoethane sulfonic acid (TES)-TRIS egg yolk solution and at 21 degrees C with a Hepes-Tyrode balanced salt solution (containing bovine albumin and HEPES) (TALP) medium or no dilution. After 24 h, samples were frozen and thawed (CM3, 0.5-ml straws, fast thawing rate) at 20 x 10(6) spermatozoa ml(-1) (low concentration) or at 100 x 10(6) spermatozoa ml(-1) (standard concentration). The SMI at 0-h postthaw was higher for samples stored at 4 degrees C than for samples stored at 21 degrees C (P < 0.001), and at 6-h postthaw, the SMI was higher for samples frozen at the standard concentration than for samples frozen at the low concentration (P < 0.05). For both experiments, acrosome integrity was similar across treatments. In summary, a semen cryopreservation protocol applied to fresh or liquid-stored semen maintained high levels of initial ejaculate sperm characteristics.     

Effect of spermatozoal concentration and number on fertility of frozen equine semen

Information on the number of motile spermatozoa needed to maximize pregnancy rates for frozen-thawed stallion semen is limited. Furthermore, concentration of spermatozoa per 0.5-mL straw has been shown to affect post-thaw motility (7). The objectives of this study were 1) to compare the effect of increasing the concentration of spermatozoa in 0.5-mL straws from 400 to 1,600 x 10(6) spermatozoa/mL on pregnancy rate of mares, and 2) to determine whether increasing the insemination dose from approximately 320 to 800 million progressively motile spermatozoa after thawing would increase pregnancy rates. Several ejaculates from each of 5 stallions were frozen in a skim milk-egg yolk based freezing medium at 2 spermatozoal concentrations in 0.5-mL polyvinyl-chloride straws. Half of each ejaculate was frozen at 400 x 10(6) cells/mL and half at 1,600 x 10(6) cells/mL. Insemination doses were based on post-thaw spermatozoal motility and contained approximately 320 x 10(6) (320 to 400) motile spermatozoa or approximately 800 x 10(6) (800 to 900) motile spermatozoa. Sixty-three mares were assigned to 1 of 4 spermatozoal treatments (1--low spermatozoal number, low concentration; 2--low spermatozoal number, high concentration; 3--high spermatozoal number, low concentration; 4--high spermatozoal number, high concentration) and were inseminated daily. Post-thaw spermatozoal motility was similar for cells frozen at both spermatozoal concentrations (P > 0.1). One-cycle pregnancy rates were 15, 40, 28 and 33%, respectively, for Treatments 1, 2, 3 and 4. Packaging spermatozoa at the high concentration tended to increase pregnancy rates vs packaging at the low concentration (37 vs 22%; P = 0.095). Furthermore, when the lower spermatozoal number was used, there tended (P < 0.1) to be a higher pregnancy rate if spermatozoa were packaged at the higher concentration. There was no increase in pregnancy rates when higher numbers of motile spermatozoa were inseminated (27 vs 31%; P > 0.1). Based on these results, a single 0.5-mL straw dose containing 800 x 10(6) spermatozoa should be used and each insemination dose should contain approximately 320 x 10(6) motile spermatozoa. Fertility trials utilizing other freezing extenders are necessary before recommending a single 0.5-mL insemination dose for all freezing extenders.