A Comparison of the Ability of Three Commercially Available Diluents to Maintain the Motility of Cold Stored Stallion Semen

The objective of this study was to compare the ability of three commercially available extenders to promote poststorage motility of stallion spermatozoa stored at 5°C with and without centrifugation to remove the seminal plasma. Diluents tested included skim milk glucose (SKMG), INRA 96, and VMD-Z. All diluents were tested with (-SP) and without (+SP) centrifugation to remove most of the seminal plasma. In experiment I, after 48 and 72 hours of storage, total (TM) and progressive (PM) motility values were higher (P ≤.05) for those aliquots subjected to the INRA 96-SP as compared with either SKMG treatment. After 72 hours of storage, PM of spermatozoa stored in VMD-Z-SP was superior to that of spermatozoa stored in SKMG regardless of the presence of seminal plasma (P ≤.05). In the second experiment, after 48 hours of storage, PM of spermatozoa subjected to the INRA 96-SP and VMD-Z-SP treatments were superior (P ≤.05) to those for all treatments that had been stored without removal of seminal plasma. Removal of the seminal plasma and resuspension of the sperm pellet with either INRA 96 or VMD-Z resulted in TM after 48 hours of storage that were similar to those obtained after 24 hours of storage.     

Comparison of Various Extenders for Storage of Cooled Stallion Spermatozoa for 72 Hours

Multiple extenders have been developed to preserve cooled stallion semen. Comparisons of some extenders have been made but there is need for further research in this area. Extenders tested included EZ Mixin (Animal Reproduction Systems, Chino, CA), Kenney's, Universal (NASCO, Fort Atkinson, WI), EquiPro, EquiPro CellGuard (Minitube of America, Verona, WI), and INRA 96 (IMV, Maple Grove, MN). Semen was collected and each ejaculate was divided and extended in each of the aforementioned extenders and stored at 4°C. Motility measures were determined using computer-assisted sperm analysis at 0, 24, 48, and 72 hours after collection. Samples were evaluated for total motility, progressive motility (PM), straight-line velocity, curvilinear velocity, straight-line distance, and curvilinear distance. Total motility and PM decreased over time in storage (P < .05). Sperm stored in INRA 96, EquiPro, and EquiPro Cell Guard retained the most total motility and PM over the 72 hour period (P < .05). Universal, EquiPro, and EquiPro Cell Guard had the highest measurements for curvilinear velocity, straight-line velocity, and curvilinear distance (P < .05). There were no significant differences among the extenders for straight-line distance.     

Preliminary Results: The Advantages of Low-Density Lipoproteins for the Cryopreservation of Equine Semen

The aim of this study was to determine the best concentration of low-density lipoproteins (LDL) in a semen extender to improve the percentage of motile spermatozoa in equine sperm after freezing and thawing in comparison with standard extenders. Ten extenders were compared: 1 with 2% egg yolk (EY), 8 with different concentrations of LDL (0.25%, 0.50%, 0.75%, 1%, 2%, 3%, 4%, and 5%), and INRA 96; all of the extenders contained 2.5% glycerol. Fourteen ejaculates were collected from four different stallions. The first dilution was made with equal parts at +37°C, centrifuged (600 × g/10 min), and resuspended in the corresponding extenders to obtain a final concentration of 100 × 10⁶ spermatozoa/ml. The resulting mixture was cooled to 4°C over 1 hour, packed into four 0.5-ml straws, and left for a further 30 minutes at +4°C. Finally, the straws were frozen in nitrogen vapors 4 cm over liquid nitrogen for 10 minutes before being immersed in liquid nitrogen at −196°C and stored. Two straws per extender and per ejaculate were thawed in a water bath at +37°C for 30 seconds. The contents of each straw were recovered into a cryotube and placed in a water bath at +37°C for 10 minutes before being examined with an image analyzer. The best post-thaw motility results were obtained with the extenders made with 0.5%, 2%, and 3% LDL and with the control extender made with egg yolk; no significant difference was observed between these extenders. The last two straws were thawed to perform four sperm function tests. The hypo-osmotic test was used to assess the integrity of the plasma membrane; the 2% and 3% LDL treatments were the most suitable and were comparable to that with whole egg yolk for protecting stallion sperm during cryopreservation (32.3%, 32.4%, and 31.3%, respectively). The Pisum sativum agglutinin-fluorescein isothiocyanate test was used to verify the integrity of the acrosomes; the best results were obtained with the 0.5%, 0.75%, and 3% LDL and INRA96 extenders; no significant differences were observed among the 85.8%, 85.0%, 84.7%, and 84.8% extenders. The acridine orange test was used to assess DNA integrity; there were no significant differences among the various extenders: the DNA was preserved in 98% of the spermatozoa. Finally, spermatozoal morphology was examined using Spermac stain; 78% of the spermatozoa did not present any anomalies in the 0.25% and 2% LDL extenders. In conclusion, the 2% LDL extender gave the best post-thaw percentage of motile spermatozoa. The results of the sperm function test were also superior for this extender.     

Quality of Raw and of Cold-Stored Semen in Icelandic Stallions

The aim of the present study was to evaluate the quality of raw and cooled semen in Icelandic stallions. Experiments were performed using seven stallions aged between 3 and 19 years. From each stallion, six ejaculates were collected, and semen quality was determined. Thereafter, the semen was split into eight equal parts and processed with and without centrifugation using the extenders INRA 82-egg yolk, INRA 96, GENT, and Equi-Pro to a final concentration of 30 × 10⁶ sperm/mL. The extended semen was then cooled in an Equitainer, where it was stored for 24 hours, and subsequently refrigerated for another 24 hours at 5°C. Immediately after dilution as well as after 24 and 48 hours storage, sperm motility was analyzed using computer-assisted sperm analyzer, and viability was assessed after dual DNA staining with SYBR-14 in combination with propidium iodide. The results show that the stallion had a significant (P < .05) influence on all variables evaluated in raw semen, and mean (±SEM) values of 43.4 ± 4.3 mL for the volume, 193.0 ± 17.0 × 10⁶ sperm/mL for the concentration, 6.7 ± 0.5 × 10⁹ for total sperm and 73.5 ± 2.1% for total sperm motility, 48.7 ± 2.0% for progressive motility, and 65.3 ± 2.0% for rapid cells were measured. In the cold-stored semen, all variables were significantly (P < .05) influenced by the stallion, extender, and storage time (48 hours). Except for Equi-Pro, all extenders examined were suitable for cooled semen preservation. For storage of more than 24 hours, centrifugation and removal of the seminal plasma were advantageous for all extenders with the exception of Equi-Pro.     

Cryopreservation of Stallion Spermatozoa with INRA96 and Glycerol

The aim of the present study was to improve success of cryopreservation of stallion spermatozoa. Semen from eleven stallions was collected and frozen in INRA 96 with two different concentrations of glycerol (3.5% and 6.0%) and compared with a control freezing process. The mean post-thaw motility for the eleven stallions of 57.93% (3.5% glycerol) and 66.50% (6.0% glycerol), which was statistically higher (P < 0.05) when compared with the mean post-thaw motility (39.7%) for semen in a control egg-yolk extender (Equipro^® CryoGuard™ Complete, Minitube). The Equipro^® CryoGuard™ Complete is a commercial semen freezing protocol that has been one of the standard processes used in our laboratory for freezing equine spermatozoa. INRA 96 with 6% added glycerol was used in the fertility trial as it provided the highest spermatozoa survival. To evaluate fertility of the frozen semen, eight mares were bred over two cycles with both fresh and frozen semen. The pregnancy rate of mares bred with frozen semen (55.6%) was not statistically different (P > 0.05) from the pregnancy rate of mares bred with fresh semen (55.6%). INRA 96 with 6.0% glycerol improved the survivability of stallion spermatozoa through the cryopreservation process, and subsequent fertility was not different (P > 0.05) from fresh, extended semen.     

Effect of Glutathione-Supplemented INRA82 Extender on Miniature Caspian Stallion Sperm Quality during Storage at 5°C

This study was conducted to investigate the effect of glutathione-supplemented INRA82 extender on miniature Caspian stallion sperm quality during storage at 5°C. A total of 12 ejaculates from three stallions (four ejaculates from each stallion) were collected and diluted with INRA82 extender that included different concentrations of glutathione (0 [INRA-G0], 5 [INRA-G5], and 10 mM [INRA-G10]) and stored for 48 hours at 5°C. Sperm motility (computer-assisted sperm analysis), plasma membrane integrity (eosin–nigrosin staining) and functionality (hypo-osmotic swelling test), and malondialdehyde (MDA) level were determined during storage at 5°C. The results showed that the sperm total and progressive motility and plasma membrane integrity and functionality in all extenders were significantly decreased with increasing storage time. However, the MDA level in all extenders was significantly increased with increasing storage time. Also, the results showed that most of the evaluated sperm quality parameters in the present study, with the exception of MDA, were significantly greater in INRA-G5 than in INRA-G0 and INRA-G10 after 24 and 48 hours of storage at 5°C. We have concluded that supplementation of INRA82 with 5 mM glutathione can improve miniature Caspian stallion sperm quality during storage at 5°C by increasing total and progressive motility, plasma membrane integrity and functionality, and decreasing the MDA level compared with INRA-G0 and INRA-G10. More advanced in vitro evaluations and artificial insemination are required to reveal the exact effects of INRA-G5 on miniature Caspian stallion sperm quality and its fertilizing ability.     

Studies on Motility and Fertility of Cooled Stallion Spermatozoa

This study on extended, cooled stallion spermatozoa aimed to compare the ability of three extenders to maintain sperm motility during 24 h of preservation, and to describe pregnancy and foaling rates after artificial insemination (AI) of stallion spermatozoa stored and transported in the extender chosen from the in vitro study. After 6 and 24 h of preservation, motility, both subjective and evaluated by the motility analyzer (total, progressive and rapid), was lower in non-fat, dried skim milk-glucose than in both other extenders: dried skim milk-glucose added to 2% centrifuged egg yolk, and ultra high temperature treated skim milk-sugar-saline solution added to 2% centrifuged egg yolk (INRA82-Y). Rapid spermatozoa and sperm velocity parameters, after 24 h, were significantly higher in INRA82-Y. In the fertility trial, semen collected from three Maremmano stallions, diluted in INRA82-Y, and transported in a refrigerated Styrofoam box, was used to inseminate 56 mares of the same breed. Pregnancy rates after the first cycle and per breeding season were significantly higher for the 31 mares inseminated in three AI centres (54.8 and 80.6%, respectively) than for the 25 mares inseminated at the breeder's facilities (28.0 and 52.0%). Foaling rates were not significantly different between the AI centres mares (54.8%) and the other mares (44.0%). In conclusion, INRA82-Y yielded satisfactory pregnancy and foaling rates, especially when employed in the more controlled situation of an AI centre, and can therefore be included among those available for cooled stallion semen preservation.     

New Methods for Selecting Stallion Spermatozoa for Assisted Reproduction

Improved sperm selection techniques are needed to increase the efficiency of equine-assisted reproduction. Single layer centrifugation (SLC) of spermatozoa has been shown to improve the quality of stallion sperm samples. In this study, the functionality of selected stallion spermatozoa was tested by intracytoplasmic sperm injection of equine oocytes after selection by SLC through Androcoll-E or by discontinuous density gradient centrifugation (DGC) through Redigrad and Tyrode's medium with added albumin, lactate, and pyruvate. The mean cleavage rates of the injected oocytes from SLC- and DGC-selected spermatozoa were 67% and 66%, respectively, whereas the proportion of blastocysts developing from cleaved oocytes was 28% and 22%, respectively (P > .05, not significant). An incidental finding was that there was a tendency for SLC-selected spermatozoa to have a higher percentage of spermatozoa with normal morphology than DGC (70% ± 22% vs. 58% ± 38%) and for more blastocysts to be obtained from subfertile ejaculates (21 [19.6%] vs. 15 [14.4%], respectively). In further experiments, stallion spermatozoa bound to hyaluronan, although binding may depend on the semen extender and sperm treatment as well as incubation time. In conclusion, SLC-selected stallion spermatozoa function normally when injected into oocytes. SLC may potentially be better than DGC at selecting spermatozoa from subfertile ejaculates, but this effect needs rigorous investigation with a much larger sample size. Use of the hyaluronan-binding assay for assessing the potential fertility of stallion spermatozoa may be useful but requires further evaluation.     

The Effect of 2-Hydroxypropyl-β-Cyclodextrin on Post-Thaw Parameters of Cryopreserved Jack and Stallion Semen

Cyclodextrins improve post-thaw viability and motility of semen as well as mediate cholesterol efflux and subsequent acrosome reaction in spermatozoa from several species. The objectives of this study were: (a) to assess the effect of prefreeze addition of 60 mM hydroxypropyl-β-cyclodextrin (β-CD) on post-thaw viability and motility of jack and stallion semen cryopreserved in ethylene glycol-based freezing extenders containing 5% or 20% (v/v) egg yolk (LEY and HEY, respectively), and (b) to evaluate the ability of 1 μM calcium ionophore A23187 and/or 60 mM β-CD to induce acrosome reaction in thawed jack and stallion spermatozoa. Post-thaw motility of spermatozoa cryopreserved in HEY was higher (P < .05) for jack but lower (P < .05) for stallion spermatozoa when compared with LEY. Jack and stallion spermatozoa both exhibited higher (P < .05) motility when cryopreserved in 60 mM β-CD than without β-CD. Curvilinear velocity was faster (P < .05) for jack and stallion spermatozoa cryopreserved in LEY than in HEY. A treatment × time interaction affected (P < .05) the proportion of spermatozoa that underwent acrosome reaction. Post-thaw incubation of jack and stallion spermatozoa with β-CD for 90 minutes induced acrosome reaction in 85% and 22% of viable sperm cells, respectively; however, only 32% of jack and 8% of stallion spermatozoa incubated with calcium ionophore underwent acrosome reaction. This study is the first to evaluate the effect of β-CD (not loaded with cholesterol) on jack semen cryopreservation, and results reveal that β-CD may be a useful tool to enhance semen cryopreservation and to induce post-thaw acrosome reaction in jack spermatozoa.     

Freezing equine semen: the effect of combinations of semen extenders and glycerol on post-thaw motility

Objective   We evaluated combinations of two commercial semen extenders and three concentrations of glycerol to determine the combination that yielded the highest post-thaw sperm motility.
Design   A randomised 2 × 3 block design was used.
Procedure   Semen was collected from four stallions (6 collections per stallion). The sample was diluted with either a dried skim-milk glucose extender (EZ Mixin Original Formula) or a chemically defined, milk-free diluent (INRA 96), and each was used in combination with 2%, 3% or 4% glycerol in standard commercial freezing medium. Sperm motility was assessed by microscopy in fresh and post-thaw semen.
Results   There was a significant difference between the two extenders in the motility of spermatozoa after cryopreservation (48.9% for INRA 96; 38.6% for EZ Mixin OF; P < 0.0001). Glycerol at 4% in freezing medium yielded the highest post-thaw motility, significantly better than 2% ( P < 0.05). Three of four stallions had significantly higher post-thaw motility using INRA 96 relative to EZ Mixin OF ( P < 0.01), and two of four stallions had significantly higher post-thaw motility using 4% glycerol ( P < 0.05). The combination of INRA 96 and 4% glycerol in freezing medium gave the highest average post-thaw motility of 51.5%.
Conclusion   In this study, INRA 96 combined with 4% glycerol yielded an average recovery of progressively motile sperm consistently above the 35% target.     

Colloidal Centrifugation of Stallion Semen: Changes in Sperm Motility,Velocity, and Chromatin Integrity during Storage

The current study investigated the changes in sperm quality (motility, velocity, and chromatin integrity) occurring during storage at room temperature or 5°C for up to 48 hours in spermatozoa after extension or single-layer centrifugation (SLC) through Androcoll-E. In unselected samples, all parameters of sperm quality deteriorated significantly during storage (P < .01), although the deterioration was faster at room temperature (22–30°C) than for cool storage (P < .01). The SLC-selected spermatozoa had higher motility, velocity, and chromatin integrity than the overall unselected population (motility: selected 85 ± 10%, unselected 56 ± 13%; P < .001; velocity: selected 85.1 ± 13 μm/second, unselected 63.5 ± 15 μm/second; P < .001; and DFI selected 12.2 ± 4.8 μm/second, unselected 23.6 ± 7.4 μm/second; P < .001). Furthermore, sperm quality did not deteriorate with storage in the SLC-selected samples, either at room temperature (22–30°C for 24 hours) or cooled to 4°C (for at least 48 hours), whereas a significant deterioration in sperm quality was observed in the unselected sperm samples (P < .01). Thus, room temperature storage of SLC-selected spermatozoa may be an option for insemination doses from stallions whose spermatozoa do not tolerate cooling. In addition, a new sperm analyzer, the Qualisperm, showed good correlation with subjective motility assessment (r = 0.8, P < .001), was user-friendly, and provided a reasonable volume of data. This instrument may be a useful adjunct to sperm quality assessment at the stud.     

Stallion Semen Cooling Using Native Phosphocaseinate-based Extender and Sodium Caseinate Cholesterol-loaded Cyclodextrin-based Extender

The objective of this study was to compare semen parameters and embryo recovery rates of cooled stallion semen extended with INRA 96 or BotuSemen Gold. In experiment 1, 45 ejaculates from nine mature stallions were collected, assessed, and equally split between both extenders and then extended to 50 million sperm/mL. Then, the extended semen was stored in three passive cooling containers (Equitainer, Equine Express II, and BotuFlex) for 48 hours. In experiment 2, the same ejaculates extended in experiment 1 were cushion-centrifuged, the supernatant was discarded, and the pellets were resuspended at 100 million sperm/mL with their respective extender. Semen was then cooled and stored as in experiment 1. In both experiments, sperm motility parameters, plasma membrane integrity, and high mitochondrial membrane potential were assessed at 0, 24, and 48 hours post cooling. For experiment 3, 12 mares (n = 24 cycles) were bred with 48 hour–cooled semen from one stallion. Semen was processed as described in experiment 1. Mares had embryo flushing performed by 8-day post-ovulation. In experiment 1, BotuSemen Gold displayed superior total and progressive motility relative to INRA 96 (P < .05). There were no significant differences between the types of containers in any experiment. In experiment 2, INRA 96 and BotuSemen Gold extenders had similar total and progressive motility, but BotuSemen Gold had superior sperm velocity parameters at all timepoints. Embryo recovery was identical for both extenders (50%). Finally, the results obtained herein suggest that BotuSemen Gold is a suitable alternative to be included in semen cooling tests against INRA 96 in clinical practice.     

The Effects of Centrifuged Egg Yolk Used with INRA Plus Soybean Lecithin Extender on Semen Quality to Freeze Miniature Caspian Horse Semen

The aim of this study was to determine the synergistic effects of centrifuged egg yolk (EY) and soybean lecithin on post-thaw Caspian horse sperm motility, morphological abnormalities, and assessment of membrane integrity. The centrifuged EY (CEY) was added at concentrations of 2% and 4% to a defined INRA plus 1.25% soybean lecithin extender used to freeze Caspian horse semen. In this experiment, ejaculates collected from each Caspian horse (n = 4) were divided into three equal aliquots and diluted in CEY 2% (INRA2), 4% (INRA4) supplemented, and without any CEY (INRA0) in INRA plus 1.25% soybean lecithin extender, respectively. Thereafter, samples were frozen and thawed following a standard protocol. Sperm cryosurvival was evaluated in vitro by microscopy assessments of post-thaw sperm motility (by means of computer-assisted semen motility analysis [CASA]), acrosomal and other abnormalities (head, mid-pieces, and tail) and plasma membrane integrity (evaluated by HOST). In Caspian stallion, semen extended with INRA2 had significantly higher CASA motility and CASA progressive motility than those extended with the rest of extenders after freezing and thawing (P < .001). There was no significant difference in path velocity (VAP), VCL, and ALH among three groups (P > .05). For straight line velocity (P < .01) and LIN (P < .001), the highest values were obtained from the INRA4 group. The highest percentages of acrosomal and other abnormalities were found in semen diluted in INRA4 (P < .001). In the group frozen INRA2, the percentage of membrane integrity was significantly higher than that of the other groups (P < .001). The use of CEY 2% in combination with soybean lecithin significantly improved Caspian horse semen freezability.     

Effect of BAPTA-AM on Thawed Stallion Spermatozoa Extended in INRA 96 or Tyrode's Medium

We studied the effect of 1,2-bis-(o-aminophenoxy)-ethane-N,N,N′,N′-tetraacetic acid, tetraacetoxymethyl ester (BAPTA-AM) on the outcome of cryopreservation of stallion spermatozoa and whether reextension of thawed sperm in a more physiological and Ca²⁺-containing medium might improve the characteristics of thawed stallion spermatozoa. Individual ejaculates from six stallions were collected and split into three subsamples. The first two samples were supplemented with the membrane-permeable Ca²⁺ chelator BAPTA-AM at final concentrations of 5 and 10 μM, respectively, while the third subsample served as control. After 4 weeks of storage, samples were thawed in a water bath at 37°C and evaluated using flow cytometry and computer-assisted sperm analysis (CASA). In a second experiment, in order to determine whether restoring Ca²⁺ could improve sperm quality after cryopreservation, thawed semen was washed by centrifugation and resuspended in Tyrode's complete medium. BAPTA-AM supplementation did not modify the outcome of cryopreservation; however, changing the spermatozoa from INRA 96 to Tyrode's complete medium resulted in significant improvements in the percentages of live sperm and total motility post thaw.     

Effect of Freezing Rates and Supplementation of α-Tocopherol in the Freezing Extender in Equine Sperm Cryosurvival

This study was conducted to determine the impact of antioxidant (α-tocopherol) supplementation in the cryopreservation extender and three different freezing rates (FRs) on quality of post-thaw semen to elaborate a new protocol for stallion semen cryopreservation. Six ejaculates from each of four stallions were subjected to cryopreservation with a commercial extender (Gent, Minitub Iberia, Spain), without any supplementation (control) or supplemented with 2 mM α-tocopherol. The semen was exposed to three different freezing rates between 5°C and −15°C: slow (5°C/min), moderate (10°C/min), and fast (20°C/min). After thawing, the sperm viability (Sybr-14 and propidium iodide [PI]), mitochondrial membrane potential (MMP) (5,5′,6,6′-tetrachloro-1,1′,3,3′tetraethylbenzimidazolyl carbocyanine iodine), lipid membrane peroxidation (LPO; C₁₁-BODIPY^581/591), and apoptosis status (fluorescein isothiocyanate–conjugated annexin V and PI) of the plasmatic membrane of each sample were determined by flow cytometry. For both extenders, the percentage of viable cells was higher for spermatozoa cooled at 5°C/min than at 10°C/min and 20°C/min (P ≤ .05). The FR of 20°C/min demonstrated a lower value of MMP than the FR of 5°C/min and 10°C/min (P ≤ .05). The α-tocopherol extender improved (P ≤ .05) post-thaw membrane LPO; however, it did not improved viability and the apoptosis status of the sperm plasmatic membrane after thawing. In conclusion, results clearly indicate that the cryosurvival of stallion spermatozoa is improved when FR of 5°C/min is used from 5°C to −15°C.     

Fertility of Mares Inseminated With Frozen-Thawed Semen Processed by Single Layer Centrifugation Through a Colloid

The aim of this study was to determine whether there was an increase in pregnancy rates when frozen-thawed stallion semen was processed by single layer centrifugation (SLC) through a colloid before insemination. In addition, changes in semen parameters, including motility, were determined before and after SLC. Twenty light-horse mares (aged 3-16 years) and one Thoroughbred stallion (aged 16 years) having average fertility with fresh and cooled semen (>50% per cycle) and displaying a postthaw motility of >35% were used. Control mares were inseminated using 4- × 0.5-mL straws (200 × 10⁶/mL) of frozen-thawed semen. Treatment mares were inseminated with 4 × 0.5 mL of frozen-thawed semen after processing by SLC. Pregnancy rates were compared using Fisher exact test, and continuous parameters were evaluated by a Student t test. The pregnancy rates at day 14 were not different for the mares inseminated with control versus SLC-processed semen, despite the difference in sperm number (171 × 10⁶ ± 21, 59 × 10⁶ ± 25 progressively motile sperm). After frozen-thawed semen was processed by SLC, the percentage progressively motile sperm improved (P < .05), and SLC processing resulted in a 21.8% recovery of spermatozoa. In summary, centrifugation of frozen-thawed semen through a single layer of colloid increased the percentage of motile spermatozoa, but did not improve pregnancy rates after deep horn insemination.     

Effects of Egg Yolk Source on the Cryopreservation of Stallion Spermatozoa

Three experiments were conducted to determine whether replacement of chicken egg yolk, as a component of freezing extenders, with egg yolk from other avian species would improve the post-thaw motility and percentage of intact acrosomes of stallion spermatozoa. In the first experiment, substitution of chicken egg yolk with chukar egg yolk, as a component of the lactose-ethylenediaminetetraacetic acid extender, improved (P ≤ .05) the post-thaw motility of stallion spermatozoa. These results were not replicated in (IMV Technologies, Maple Grove, MN, USA) a more expansive study comparing 2%, 4%, 6%, or 8% egg yolk combined with INRA 96 when a “slow freeze” method was used, or the same substitution at levels ranging from 13% to 22% when egg yolk was combined with lactose-ethylenediaminetetraacetic acid for diluents used for a “fast freeze” method of cryopreservation. In the third study, egg yolks from regular and high omega-3 chicken eggs as well as from turkey, chukar, and mallard duck eggs were analyzed for lipid content and fatty acid profile. The yolk from the turkey eggs was higher (1,300 mg/100 g) and that from mallard ducks was lower (560 mg/100 g) in cholesterol as compared with the two types of chicken eggs and chukar egg yolk (range, 1,046-1,094 mg/100 g). In addition, the high omega-3 eggs did test higher for fatty acids (4.51 g/100 g) than other types of eggs (range, 0.28-0.73 g/100 g). Substitution of chicken egg yolk with turkey, but not duck, egg yolk resulted in higher post-thaw total motility (P ≤ .05) for spermatozoa obtained from two of the three stallions used in the third experiment.     

Cryopreservation of Cooled Semen and Evaluation of Sperm Holding Media for Potential Use in Equine-Assisted Reproduction Procedures

Processing stallion semen for assisted reproductive procedures, such as intracytoplasmic sperm injection (ICSI), requires special considerations regarding cooling, concentrating, and handling of sperm. The aim of experiment 1 was to determine whether cooled semen could be frozen without removal of seminal plasma and at a low sperm concentration while maintaining motile sperm for ICSI selection procedures. In experiment 2, five media for holding stallion sperm were compared to evaluate sperm motility for an interval of time sufficient for ICSI sperm selection procedures. In experiment 1, semen samples from eight stallions were cooled for 24 hours in two extenders, CST (E-Z Mixin-CST “Cool-Store/Transport” Animal Reproduction Systems) and INRA96 (Institut National de la Recherche Agronomique, IMV International Corporation), before being frozen in four freezing diluents, and were evaluated at 0, 45, and 75 minutes after thawing. The cooling extender did not significantly affect sperm motility, but modified French and glycerol egg yolk diluents provided the best sperm motility for frozen–thawed groups. In experiment 2, semen samples from seven stallions were used to test five media for holding sperm. Samples were analyzed for total and progressive motility at hourly intervals. Mean total and progressive motility were not different (P > .05) among groups from 1 through 4 hours. At 5 hours, groups differed (P = .004), with sperm held in Tyrode’s with albumin, lactate, and pyruvate having higher (P < .05) total and progressive motility than all other samples. In conclusion, motile stallion sperm can be obtained after the sperm are cooled for 24 hours, frozen, and thawed; various media are available to maintain sperm motility during equine ICSI selection procedures.     

The Effect of Coenzyme Q10 and α-Tocopherol in Skim Milk–Based Extender for Preservation of Caspian Stallion Semen in Cool Condition

The purpose of this study was to determine the effects of different concentrations of coenzyme Q₁₀ (CoQ₁₀) and α-tocopherol (T) along with their interaction effects on the quality of preserved stallion semen at 5°C for a period of 48 hours. Semen was collected and diluted with skim milk–based extender that was supplemented with different antioxidants: no antioxidant (negative control [NC]), 0.9% (vol/vol) dimethyl sulfoxide (positive control [PC]), α-tocopherol (5 [T5] or 10 [T10] mM), CoQ₁₀ (1 [C1] or 2 [C2] μM), 1 μM CoQ₁₀ + 5 mM α-tocopherol (C1T5), 1 μM CoQ₁₀ + 10 mM α-tocopherol (C1T10), 2 μM CoQ₁₀ + 5 mM α-tocopherol (C2T5), and 2 μM CoQ₁₀ + 10 mM α-tocopherol (C2T10), then kept at 5°C. The results showed that C1 extender resulted in higher total motility (62.44 ± 3.82) and plasma membrane integrity (65.16 ± 3.63%) compared with NC after 48 hours of storage (P < .05). Different concentrations of α-tocopherol had no significant effects on sperm quality, with the exception of plasma membrane integrity, compared with NC and PC extenders (P > .05). Also, C1T5 extender improved total and progressive motility, plasma membrane integrity and functionality, and decreased lipid peroxidation compared with NC and C2T10 extenders over 48 hours of storage at 5°C (P < .05). The C1T5 extender was similar to C1 and T5 extenders in all semen parameters evaluated during storage time. In conclusion, between previously mentioned extenders, C1T5 could improve stallion sperm quality during 48 hours of storage. In the present study, none of extenders had effect on sperm quality until 24-hour storage.     

Preservation of Epididymal Stallion Sperm in Liquid and Frozen States: Effects of Seminal Plasma on Sperm Function and Fertility

Three separate experiments were conducted to improve preservation of stallion epididymal sperm. In the first one, two different cooling extenders (Kenney and Gent) were compared. Sperm viability and motility patterns were assessed in 10 different epididymal sperm samples after 0 hours, 24 hours, 48 hours, 72 hours, and 96 hours of preservation at 4°C. No significant differences were observed in any of the evaluated parameters either between extenders or throughout the storage period. The second set of experiments was designed to determine whether supplementing thawing medium (INRA Freeze) with seminal plasma had any impact on the quality of frozen-thawed epididymal sperm. Ten epididymal frozen-thawed sperm samples coming from separate stallions were used and different functional parameters (sperm membrane integrity and lipid disorder, motility, intracellular Ca²⁺ levels, and intracellular concentrations of peroxides and superoxides) were evaluated after incubation with or without 50% seminal plasma. Supplementing thawing medium with seminal plasma had no impact on sperm function and survival. The third experiment was an in vivo study. Twenty-five mares were inseminated with epididymal frozen-thawed sperm and seminal plasma, and 21 were bred with epididymal frozen-thawed sperm only. Pregnancy rates obtained for mares artificially inseminated with epididymal frozen-thawed sperm and seminal plasma were significantly (P < .05) higher than those observed when seminal plasma was not infused (64% vs. 19%). Taken together, our data indicate that the quality of epididymal stallion sperm can be maintained at 4°C for up to 96 hours. In addition, not only does supplementing frozen-thawed epididymal sperm with seminal plasma have any damaging effect on their quality but it may also improve pregnancy rates after artificial insemination.