Single-Layer Colloid Centrifugation as a Method to Process Urine-Contaminated Stallion Semen After Freezing-Thawing

Urospermia is a major ejaculatory dysfunction affecting stallions. It has been thought that urine-contaminated semen should not be cryopreserved; however, on select cases, urine contamination of semen cannot be avoided. A recent study suggested that urospermic semen can be cryopreserved after cushion centrifugation and extension. Thus, this study aimed to assess the use of single-layer colloid centrifugation (SLC) to process frozen-thawed urine-contaminated stallion semen. Raw ejaculates (n = 55) from eight stallions were split into three groups: no urine, low (20%), or high (50%) urine contamination. Semen was extended 1:1, cushion-centrifuged, and resuspended at 200 million sperm/mL in BotuCrio. Resuspended semen was loaded in 0.5 mL straws and cryopreserved in liquid nitrogen. Samples were thawed (37°C for 30 seconds) and processed by SLC (400 g/30 minutes). Percentages of total motility (TM) and progressive motility (PM) were assessed with computer-assisted semen analyzer. Sperm viability (%VIAB) and yield were assessed with a NucleoCounter before and after gradient centrifugation. Data were analyzed with two-way ANOVA and Tukey’s test. The motility parameters TM before SLC (control: 35 ± 2; low: 33 ± 0.7; high: 22 ± 1.8) after SLC (control: 51 ± 3.6; low: 42 ± 2.2; high: 25 ± 2.8) and PM before SLC (control: 24 ± 1.8; low: 21 ± 1.14; high: 12 ± 1.5) and after SLC (control: 40.3 ± 3.2; low: 31 ± 3.9; high: 14 ± 2) significantly decreased with increasing urine contamination. Urine contamination marginally reduced (P < .05) sperm viability after cryopreservation before SLC (control: 45 ± 0.7; low: 27 ± 0.2; high: 27 ± 0.3) and after SLC (control: 54 ± 0.5; low: 49 ± 0.7; high: 38 ± 0.6). Recovery rates of sperm after centrifugation were not significantly different between groups. In conclusion, urine contamination affects sperm motility parameters in a dose-dependent manner. Post-thaw SLC selected sperm with higher motility and viability in control and low groups but only selected sperm with higher viability in the high group.     

Development of Procedures for Sex-sorting Frozen–Thawed Bovine Spermatozoa

Dairy bull sperm may be sex‐sorted, frozen and used to artificially inseminate heifers with acceptable fertility if the herd is well‐managed. One drawback to the technology is that donor bulls must be located within a short distance of the sorting facility in order to collect semen, which limits the number of bulls from which sorted sperm are available. A successful method used to overcome this limitation in sheep is sex‐sorting from frozen–thawed semen and refreezing for artificial insemination. This technique is attractive to the dairy industry, and therefore a series of three experiments was designed to investigate the optimal methods to prepare, sex‐sort and re‐freeze frozen–thawed bovine sperm. Sperm were prepared for sorting by density gradient separation in either PureSperm^® or BoviPure?, followed by staining in one of three diluents (Androhep^®, Bovine Sheath Fluid + 0.3% BSA or TALP buffer). Sperm were sorted and collected into Test yolk buffer, and frozen in an extender containing 0, 0.25, 0.375 or 0.5% Equex STM Paste. Frozen–thawed sperm were better orientated (p = 0.006) and had fewer damaged membranes (8.7 ± 0.6% vs 19.5 ± 2.4%; p = 0.003) after centrifugation in PureSperm^® rather than BoviPure? gradients. Sperm orientation (p < 0.05) and motility (69.9 ± 3.0 vs 55.6 ± 4.0; p < 0.001) were highest after staining in Androhep^® rather than in TALP buffer. Sperm were more motile (58.2 ± 4.7 vs 38.7 ± 3.5; p < 0.001) and had better acrosome integrity (74.3 ± 2.9 vs 66.8 ± 2.0; p < 0.001) after freezing in an extender containing 0.375% Equex STM Paste than in extender without Equex. Hence, a protocol has been developed to allow frozen–thawed bull sperm to be sex‐sorted with high resolution between the sexes, then re‐frozen and thawed with retention of motility and acrosome integrity.     

Effect of Centrifugation Technique on Post-storage Characteristics of Stallion Spermatozoa

Three ejaculates were collected from four stallions and used to compare the effects of three centrifugation methods on post-storage motility and recovery of available sperm. Two aliquots per ejaculate were diluted with skim milk-glucose (SKMG) extender to 50×10⁶ sperm/mL, placed in 50-mL conical bottom tubes, and centrifuged at either 700g for 15 minutes (700g) or 600g for 12 minutes (600g). A third aliquot was diluted 1:1 with SKMG, placed in 15-mL conical tubes, and centrifuged at 400g for 7 minutes (400g). Subsamples from each pre-treated diluted ejaculate were held at room temperature and evaluated for motility at the same time as the post-centrifugation pre-storage motility evaluation was made for treated aliquots. After centrifugation, samples from each aliquot were stored at 5°C for evaluation after 24 and 48 hours or frozen in liquid nitrogen. Percentage of available sperm harvested was higher (P ≤ .05) for aliquots centrifuged in 15-mL tubes at 400g versus 600g in 50-mL tubes. After centrifugation, total but not progressive motility of aliquots centrifuged at 700g was lower than that for noncentrifuged controls and sperm from aliquots centrifuged at 400g in 15-mL tubes. After cold storage, values for total but not progressive motility or velocity were higher (P ≤ .05) for aliquots centrifuged in 15-mL tubes at 400g compared with those centrifuged in 50-mL tubes at both 600g and 700g. Postthaw motility of frozen sperm was not different between centrifugation treatments. Poststorage percentages of intact acrosomes and detached heads did not differ because of centrifugation treatment.     

Dimethylformamide Improves the In vitro Characteristics of Thawed Stallion Spermatozoa Reducing Sublethal Damage

A total of 42 ejaculates were used in the experiment; six ejaculates per stallion, obtained from seven Pure Spanish stallions (PRE), were split and frozen in freezing media with different concentrations and combinations of cryoprotectant (CPA): (i) Cáceres (skim milk based extender) containing 2.5% glycerol (2.5GL), (ii) Cáceres containing 1.5% glycerol and 1.5% dimethylformamide (1.5%GL–1.5%DMFA), (iii) Cáceres extender supplemented with 1.5% glycerol and 2.5% dimethylformamide (1.5%GL–2.5%DMFA) and (iv) Cáceres extender supplemented with 4% dimethylformamide (4%DMFA). After at least 4 weeks of storage in liquid nitrogen (LN), straws were thawed and semen analysed by computer‐assisted sperm analysis and flow cytometry (membrane lipid architecture (Merocyanine 540), integrity and sublethal damage (YoPro‐1) and mitochondrial membrane potential (JC‐1)). After thawing, better results were observed in samples frozen in 4%DMFA or in combinations of 1.5%GL–2.5%DMFA, in fact total motility increased by 16% in the 4%DMFA group compared to 2.5%GL (P < 0.05). Also, there was an increment in the percentage of progressive motile sperm in the 1.5%GL–2.5%DMFA group (9.8% 2.5GL vs 19% in the 1.5%GL–2.5%DMFA group p < 0.05); also, samples frozen in the 4%DMFA group had more intact (YoPro‐1 negative) sperm post‐thawing, 29.3% in 2.5%GL vs 36.7% in 4%DMFA group (p < 0.05). Membrane lipid architecture was not affected by any of the cryoprotectants tested, while samples frozen in 4%DFMA had a lower percentage of mitochondria with lower membrane potential. It is concluded that DMFA improves the outcome of cryopreservation of stallion spermatozoa mainly reducing sublethal cryodamage.     

Morphology and Chromatin Integrity of Stallion Spermatozoa Prepared by Density Gradient and Single Layer Centrifugation Through Silica Colloids

The objective was to investigate whether it is possible to improve the quality of stallion semen, with respect to sperm morphology and chromatin integrity, both of which have been linked to fertility, using either density gradient centrifugation (DGC) or a new method, hereby named single layer centrifugation (SLC). The two methods of colloidal centrifugation were evaluated using 38 ejaculates from 10 stallions. Sperm morphology, subjective motility and sperm chromatin integrity were compared in uncentrifuged samples and in centrifuged sperm preparations. The proportion of morphologically normal spermatozoa varied between stallions (p < 0.001) and was increased by both methods of colloidal centrifugation (median value before centrifugation 67.5%; after SLC 78%; after DGC 77%; p < 0.001). The incidence of certain abnormalities was reduced, e.g. proximal cytoplasmic droplets were reduced from 12.9% to 8.8% (p < 0.001), and mid-piece defects from 5.3% to 1.4% (p < 0.05). Similarly, sperm motility and chromatin integrity were significantly improved (p < 0.001), with no difference between the two centrifugation methods. Centrifugation through colloids can enrich the proportions of stallion spermatozoa with normal morphology and normal chromatin structure in sperm preparations. The new method, SLC, was as effective as DGC in selecting motile stallion spermatozoa with normal morphology and intact chromatin. SLC, being simpler to use than DGC, would be appropriate for routine use by stud personnel to improve stallion sperm quality in insemination doses.     

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 Different Extenders and Seminal Plasma on the Susceptibility of Equine Spermatozoa to Lipid Peroxidation After Single-Layer Centrifugation, Through Androcoll-E

This study was conducted in an attempt to see whether single-layer centrifugation (SLC) increases the susceptibility of stallion spermatozoa to lipid peroxidation (LPO), in different extenders after removing all seminal plasma (SP). The susceptibility of stallion spermatozoa to LPO was studied before and after SLC. Each ejaculate was split, and aliquots extended with one of the three different extenders: INRA 96, Kenney's, or Equipro, and stored for 24 hours at 5°C (i). From the extended samples, an aliquot was kept as a control and the other was subjected to SLC through Androcoll-E. The selected spermatozoa were re-suspended in the appropriate extenders, without (ii) or with (iii) addition of 50% (v/v) pooled homologous SP for 24 hours at 5°C. Using ferrous sulfate as pro-oxidant, the susceptibility for LPO was flow-cytometrically assessed using the probe Bodipy^581/591-C₁₁. Sperm motility, monitored with a Qualisperm motility analyzer, increased after SLC treatment (P < .001). No significant correlations were found between motility and induced LPO with ferrous sulfate. The SP and extenders, per se, did not have a significant protective effect against LPO, but the interaction between SP and Kenney increased the susceptibility to LPO. However, the selected spermatozoa through Androcoll-E and the subsequent dilution in INRA had a significant protective effect against LPO (P < .05), especially when the oxidative insults were higher (80 μM).     

Colloidal Centrifugation of Stallion Semen Results in a Reduced Rate of Sperm DNA Fragmentation

Stallion spermatozoa recovered and examined immediately after colloidal centrifugation resulted in a higher straight‐line velocity (VSL) than sperm processed using direct conventional centrifugation (p = 0.000), but there was no differences in the progressive motility or sperm DNA fragmentation (SDF) as determined by the sperm chromatin dispersion assay. However, when centrifuged spermatozoa were incubated at 37°C for 24 h to determine the rate of SDF (r‐SDF), a lower r‐SDF (p = 0.0011) was observed in those sperm recovered after colloidal separation (0.5 ± 0.1%/h) compared to direct (1.2 ± 0.4%/h) or no centrifugation (r‐SDF = 1.2 ± 0.3%/h). These results confirm that colloidal separation of stallion spermatozoa results in prolonged sperm DNA longevity, but these differences were only apparent following a period of incubation and dynamic assessment. Consequently, we strongly recommend the use of the dynamic form of the SDF assay for evaluating centrifugation and/or other ex vivo procedures, as a single basal assessment of SDF may inadvertently result in a false‐positive evaluation of DNA quality.     

Stallion Sperm Integrity After Centrifugation to Reduce Seminal Plasma Concentration and Cool Storage for 4 days

The objective of the study was to investigate if reducing the seminal plasma of stallion extended semen by centrifugation once will suffice to maintain acceptable semen quality for insemination after 4 days of cool storage. Collected semen was extended to 25 × 10⁶ sperm/mL and subjected to one of the following treatments: noncentrifuged (control), centrifuged for 10 minutes at 900 × g and 1800 × g. The supernatant was partially removed, and the sperm pellet, reconstituted and re-extended. It was then placed in a passive cooling device overnight and then transferred to a refrigerator for the remainder of the cooling period. At day 0, 2, and 4, total motility (TM), progressive motility (PM), and plasma (PLM) and acrosomal membrane integrity were assessed. Centrifuged groups had higher TM and PM at day 4 than the control group (P < .05). Likewise, centrifuged groups had higher intact PLM in day 4 (P < .05). A single centrifugation cycle to reduce seminal plasma concentration will suffice to preserve sperm integrity acceptable for an artificial insemination dose up to 4 days of cool storage.     

The John Hughes Memorial Lecture: Aspects of Sperm Physiology—Oxidative Stress and the Functionality of Stallion Spermatozoa

Spermatozoa are vulnerable to oxidative attack because they contain an abundance of polyunsaturated fatty acids that are susceptible to lipid peroxidation. In addition, functionally important proteins and DNA are also subject to oxidative modification and adduction by aldehydes, such as 4-hydroxynonenal (4HNE), generated as a consequence of the peroxidative process. The proteins adducted by 4HNE include elements of the mitochondrial electron transport chain, such as succinic acid dehydrogenase. The net result of such electrophilic attack is to stimulate generation of mitochondrial reactive oxygen species (ROS) in a self-perpetuating lipid peroxidation–ROS generation cycle that ultimately triggers the intrinsic apoptotic pathway, leading to a rapid loss of motility and cell death. A major point of difference between apoptosis in spermatozoa and somatic cells is that in the former, nuclear DNA is located in a compartment (the head) separate from the mitochondria and most of the cytoplasm (the midpiece). As a result, nucleases activated and released in the midpiece during apoptosis cannot gain access to the DNA in the sperm head in order to cleave the DNA. However, the ROS generated during apoptosis can readily gain access to the sperm nucleus and generate oxidative base adducts, typically 8-hydroxy, 2′-deoxyguanosine (8OHdG), which are converted into abasic sites by 8-oxoguanine glycosylase (OGG1), the only enzyme of the base excision repair pathway possessed by spermatozoa. These abasic sites subsequently become the foci of DNA fragmentation. Because defective sperm function and DNA damage are frequently associated with oxidative stress, there is a great deal of interest in the use of antioxidants in a therapeutic context. This presentation examines the fundamental relationships between oxidative stress and sperm function and considers the implications of recent findings for the management of sperm function and fertility in stallions.     

Autologous Whole Ram Seminal Plasma and its Vesicle-free Fraction Improve Motility Characteristics and Membrane Status but not In Vivo Fertility of Frozen–Thawed Ram Spermatozoa

Motility characteristics (assessed subjectively and with computer-assisted semen analysis) and membrane status (after staining with chlortetracycline) of washed and non-washed frozen-thawed ram spermatozoa were evaluated after incubation in buffer and buffer containing autologous whole seminal plasma or one of its two fractions: the pellet of membrane vesicles obtained by ultracentrifugation (and used at three times normal protein concentration) or the vesicle-free supernatant fraction. Whole seminal plasma and supernatant, but not membrane vesicles, improved the motility characteristics of spermatozoa after 3 and 6 h of post-thaw incubation compared with the control buffer. Resuspension and incubation with whole seminal plasma, supernatant or membrane vesicles lowered the proportion of acrosome-reacted frozen-thawed spermatozoa compared with the control buffer. Unwashed frozen-thawed semen from three rams, incubated with autologous whole seminal plasma or its fractions and inseminated using cervical or intrauterine artificial insemination, had no effect on pregnancy rates of ewes in synchronized oestrus. However, fertility was higher after laparoscopic than cervical insemination (44.9 vs 12.3%, p < 0.001). In conclusion, resuspension and incubation of frozen-thawed ram spermatozoa in autologous whole seminal plasma or its vesicle-free supernatant fraction improved their motility characteristics and, with membrane vesicles, membrane status, but these benefits were not reflected in improved fertility after cervical or intrauterine insemination.     

Effect of Oxytocin Treatment on Artificial Insemination with Frozen–Thawed Semen in Murciano–Granadina Goats

The site where the semen is deposited appears to be one of the most important factors affecting pregnancy of inseminated goats. In Murciano–Granadina (MG) goats, post-cervical insemination is achieved in a limited number of females. An effective way to increase fertility rate could be by increasing post-cervical inseminations. Effect of exogenous oxytocin application to facilitate the cervical penetration and its effect on kidding rate and prolificacy in MG goats were investigated. Oestrus was synchronized using progesterone-impregnated sponges for 11 days. Females were randomly divided into three groups (n = 190) and received either an i.v. injection of 100 or 200 IU of oxytocin or saline solution 15 min before being inseminated. Data on semen deposition depth were recorded for each animal using a catheter scaled in centimetres (up to 4 cm). Depth of semen deposition was affected by the oxytocin treatment (p < 0.05). Oxytocin enhanced cervical passage only with the dose of 200 IU compared with the control group, increasing the deposition depth (2.9 cm vs 1.9 cm). No significant effect of oxytocin treatment on kidding rate and prolificacy was detected. Depth of semen deposition affected kidding rate (p < 0.01). In conclusion, oxytocin treatment improved the depth of semen deposition in AI of MG goats, but kidding rate and prolificacy was not affected. More studies must be conducted to assess the minimal effective dose required for sufficient cervical dilation, and to determine the effects of such doses of oxytocin on uterine motility, sperm transport and fertility in goats.     

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.     

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.     

Quality and Fertilizing Ability In Vivo of Sex‐Sorted Stallion Spermatozoa

Little information is available on the quality of stallion spermatozoa after sex sorting. The objectives of the present study were to assess the quality of sex‐sorted stallion spermatozoa and determine its fertilizing ability after hysteroscopic low dose insemination. Ejaculates from four stallions were collected and sorted by a MoFlo SX^® flow cytometer/sperm sorter. Before and after sorting, spermatozoa were evaluated for motility by Computer Assisted Sperm Analysis, viability (SYBR 14‐propidium iodide), mitochondrial function (JC‐1) and acrosomal status (fluorescein isothiocyanate Pisum sativum agglutinin conjugated). A fertility trial was carried out on four mares (seven oestrous cycles) by hysteroscopic insemination, depositing 5 × 10⁶ X‐bearing spermatozoa. Sex sorting resulted in a significant decrease (p < 0.001) in all motility characteristics. Sperm viability and percentage of spermatozoa with functional mitochondria were not affected by the sorting process, while the percentage of reacted spermatozoa was higher (p < 0.01) for non‐sorted than sorted spermatozoa. Pregnancy rate was 28.6% (2/7) after low dose hysteroscopic insemination. Only one pregnancy was carried to term with the birth of a healthy filly. In conclusion, despite the reduction in sperm motility, sex sorting did not impair stallion sperm viability and mitochondrial activity immediately post‐thaw; moreover, the sexed spermatozoa retained the ability to fertilize in vivo.     

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.     

Single Layer Centrifugation of Stallion Spermatozoa through Androcoll™‐E does not Adversely Affect their Capacitation‐Like Status,as Measured by CTC Staining

This study was designed to evaluate the effect of single layer centrifugation (SLC) and subsequent cold storage on stallion sperm capacitation‐like status and acrosome reaction. Three stallions were included in the study, with three ejaculates per stallion. The samples were examined 4, 24 and 72 h after collection, extension and SLC, with storage at 6°C. Sperm capacitation‐like status was investigated using the fluorescent dye chlortetracycline (CTC). There was no difference in capacitation‐like status between colloid‐selected and non‐selected spermatozoa. Sperm motility decreased significantly during cold storage, whereas the proportion of apparently capacitated spermatozoa increased. There was no change in the proportion of acrosome‐reacted spermatozoa. In conclusion, SLC through Androcoll?‐E does not adversely affect the capacitation‐like status of stallion spermatozoa, although it did increase with time during cold storage.     

Motility and Fertility Evaluation of Thawed Frozen Stallion Semen After 24 Hours of Cooled Storage

Breeding mares with cryopreserved semen requires specialized equipment for storage and thawing and more intensive mare management. The objectives of this study were (1) evaluate the longevity of frozen stallion semen once it had been thawed, extended, and maintained at 5°C for 48 hours in a passive cooling container, and (2) determine fertility potential of frozen semen that had been thawed, extended, and used to inseminate mares after 24 hours of cooled storage. Eight ejaculates were collected and aliquots were cooled in either INRA96 and CryoMax LE minus cryoprotectant at a concentration of 50 million total sperm/mL. The remainder of the ejaculate was frozen in CryoMax LE extender at a concentration of 200 million total sperm/mL. Semen was thawed using 1 of 3 thawing protocols, and diluted to a concentration of 50 million total sperm/mL in either INRA96 or CryoMax LE minus cryoprotectant and cooled to 5°C. Sperm motility was evaluated at 24 and 48 hours. Eight mares were inseminated over two estrous cycles using frozen semen that had been thawed, extended in INRA96, and cooled for 24 hours. There was no difference in progressive motility at 24 or 48 hours of cooled-storage post-thaw between the 3 thawing protocols. An overall per cycle pregnancy rate of 56% (9/16 cycles) was achieved using frozen-thawed semen that had been extended and cooled for 24 hours. In summary, frozen stallion sperm was thawed, extended, and cooled to 5°C for 24 hours and still maintained adequate (>30%) sperm motility and fertility.     

Studies on the Intracellular Ca2+ Concentration of Frozen–Thawed Dog Spermatozoa: Influence of Equex from Different Sources, Two Thawing Diluents and Post-thaw Incubation in Capacitating Conditions

The addition of 0.5% (v/v) of Equex STM Paste (Nova Chemical Sales, Scituate Inc., MA, USA), whose active ingredient is sodium dodecyl sulphate (SDS), to a Tris–egg yolk extender was demonstrated to improve the longevity of frozen–thawed dog spermatozoa during in vitro incubation at 38°C. The aim of the first experiment was to compare the effects of two SDS‐containing compounds, Equex STM Paste and Equex Pasta (Minitüb, Tiefenbach, Germany), when added to a Tris–egg yolk based extender, on the post‐thaw longevity of dog spermatozoa, as well as on the intracellular Ca²⁺ concentration of spermatozoa, during post‐thaw incubation at 38°C. The post‐thaw sperm survival and longevity, as well as the quality of the sperm movement, were significantly better when using Equex STM Paste. Such prolonged sperm longevity, however, was associated to a higher intracellular Ca²⁺ concentration in a large subpopulation of the live spermatozoa. A second experiment was aimed to evaluate the effects of sperm dilution immediately post‐thaw with a Tris buffer containing glucose or fructose. The two Tris buffers were no different for any of the sperm parameters studied. The aim of a third experiment was to evaluate the sperm longevity, motility patterns and intracellular Ca²⁺ concentration of cryopreserved dog spermatozoa during post‐thaw incubation in capacitating conditions [canine capacitating medium (CCM) with or without 5 μg/ml of heparin]. Heparin had no significant effects on any of the sperm parameters evaluated. During the first 8 h of incubation, the majority of the live spermatozoa had a high intracellular Ca²⁺ content. However, after 8–10 h of incubation, it had significantly declined. The highest proportion of fast motile sperm, and the highest curvilinear velocity, average path velocity and amplitude of lateral head displacement for the total motile sperm were observed during the 2–4‐h incubation period. It was concluded that: (a) the addition of 0.5% (v/v) of Equex STM Paste to a Tris–egg yolk based extender significantly improved the post‐thaw longevity of dog spermatozoa, but the same concentration of Equex Pasta had no significant beneficial effects; (b) sperm dilution after thawing with a Tris buffer containing glucose or fructose made no difference in post‐thaw sperm longevity; (c) the addition of 5 μg/ml of heparin to CCM had no significant capacitating effects on frozen–thawed dog spermatozoa.     

Comparison of DNA Fragmentation Assay in Frozen‐Thawed Cat Epididymal Sperm

DNA fragmentation of frozen‐thawed feline epididymal sperm from corpus and cauda regions was evaluated by three different techniques. The DNA fragmentation index (DFI) was compared between techniques: the sperm chromatin structural assay (SCSA^®), acridine orange staining techniques (AOT) and the sperm chromatin dispersion (SCD). There were significant differences in DFI among the techniques (p < 0.05) with no correlations. Only DFI values obtained from SCD revealed a significantly higher DFI in corpus compared with cauda spermatozoa (p < 0.05). The discrepancy between techniques might be due to the sensitivity of each technique, differences in severity of DNA damaged that can be detected. The difference in DFI between epididymal regions from SCD technique might indicate different maturational stages of spermatozoa, with less chromatin condensation of spermatozoa in corpus compared with cauda epididymis.