Brushing rams before and during electroejaculation improves sperm motility and kinetics with slight changes in stress biomarkers.

The aim of this study was to determine whether brushing rams before and during electroejaculation (EE) reduces their stress response and improves the characteristics of the ejaculate. A single person brushed each ram for 5 min daily, for 15 days, in an individual pen. Semen was collected from five rams brushed before and during EE by the same brusher, while the other five were electroejaculated without being brushed. The treatments were exchanged three days later, so semen was collected from all the rams with both treatments. Brushing increased mass motility (P = 0.05), and curvilinear (P = 0.001), linear (P = 0.02), and average path (P = 0.01) velocities of sperm, as well as the average amplitude of lateral displacement of the sperm head (P = 0.05), and tended to increase sperm concentration (P = 0.09). Brushing tended to reduce the cortisol concentration (P = 0.06) and the duration of head movements when 2 V pulse series V was applied (P = 0.1). Brushing increased creatine kinase concentration (P = 0.04) and tended to increase rectal (P = 0.06) and maximum eye surface temperatures (P = 0.1), total time, and number of electrical pulses administered (P = 0.07 for both variables), as well as the sum of pulses per voltage applied during EE (P = 0.06). In rams accustomed to being brushed by the same person, brushing them before and during EE improved semen quality, with slight changes in the stress responses.

Time of day modified the time required for semen collection with electroejaculation and slightly affected the quality of fresh semen in rams.

The aim was to compare some stress responses to electroejaculation (EE), and the quality of fresh semen, when ram semen is collected at dawn (06:00 h), noon (12:00 h), or evening (18:00 h). Twelve Corriedale rams were used, and semen was collected from four rams at each study time on three different days, with a Latin-square design. The time required for EE, the number of vocalizations emitted, heart rate, and rectal temperature were recorded, and fresh semen was evaluated. The time required for EE was shorter at evening than at dawn and noon (399.3 s, 480.6 s, and 460.2 s respectively; pooled SEM = 72.1; P = 0.03). The percentage of sperm with progressive motility was greater at noon than dawn (59.7% and 50.3%; pooled SEM = 5.8; P = 0.05). Curvilinear velocity was greater at dawn than evening (117.0 µm/s and 95.5 µm/s; pooled SEM = 7.1; P = 0.04), slow linear velocity was greater at evening than at dawn and noon (13.1 µm/s, 9.3 µm/s, and 8.5 µm/s respectively; pooled SEM = 1.7, P = 0.05), and the slow average path velocity was greater at evening than dawn and noon (16.2 µm/s, 11.7 µm/s, and 10.8 µm/s respectively; pooled SEM = 1.9, P = 0.05). In conclusion, the collection time modified the time required for electroejaculation and had only slight effects on the quality of fresh semen. Overall, the time of the day appears to have only slight effects on semen collection and quality.

Relationship between the seasonal changes in plasma testosterone and thyroxine concentrations with sperm cryoresistance in Gabon bucks.

Gabon buck is a breed with little marked seasonality in our latitude (Uruguay, 35° SL). The role of thyroid hormones on the regulation of their seasonal reproductive activity and sperm cryoresistance is unknown. Seasonal changes in testosterone concentration can affect sperm variables, but the influence of testosterone changes on sperm cryoresistance in other species determines that the recommended time for freezing sperm does not coincide with the period with greater sperm fresh quality. The objectives of the present work were to (i) describe the thyroxine seasonal pattern in bucks in a subtropical area, and its association with annual changes in sperm variables; (ii) relate the seasonal changes of testosterone and thyroxine concentrations with the sperm cryoresistance. For one year, semen of 10 adult Gabon bucks was collected by electroejaculation every two weeks. After sperm selection, the sample was frozen. Testosterone and thyroxine concentrations varied according to the month (P < 0.0001). Testosterone reached the greatest values in April (P < 0.0001) and May (P < 0.0001) and thyroxine reached minimum values (P < 0.0001) in the same months. During these months, a negative correlation ratio (CR) was found between testosterone concentration and CR-functional membrane (R = - 0.50; P < 0.0001). CR values for most sperm variables decreased during March-May, coinciding with the presence of maximum testosterone concentrations. In conclusion, high testosterone levels are associated with the worst sperm response to freezing-thawing process. Thyroxine concentrations have a strong seasonal pattern, but there was no relationship to sperm cryoresistance.

Comparison of the Conventional and Ultra-Rapid Freezing Techniques in Gabon Bucks Throughout the Year.

The aim of this work was to compare the effectiveness of ultra-rapid freezing (UF) and conventional slow freezing (CF) to cryopreserve buck sperm throughout the year. During 1 year, semen from 10 adult Gabon bucks was collected by electroejaculation every 2 weeks. Before and after freezing, samples were selected by density gradient centrifugation, and after sperm selection, the sample was divided into two aliquots. One aliquot was CF with an extender based on Tris, citric acid, and glucose (TCG) +6% yolk +5% glycerol, and maintained at 5°C for 3 hours of equilibration before freezing. The other aliquot was frozen using an UF method with an extender based on TCG +6% yolk +100 mM sucrose, and maintained at 5°C for 30 minutes. The evaluations included the percentages of motile sperm, sperm with progressive motility, quality of sperm motility, and the percentages of sperm with functional membrane, live sperm, sperm with morphoabnormalities, and sperm with intact acrosome. The percentage of sperm with intact acrosome was higher using the conventional freezing method (p < 0.05). After thawing and at pre- and postselection stages, the quality of motility, and the percentages of motile sperm, progressive motile sperm, sperm with functional membrane, and with intact acrosome were greater using CF than UF (p < 0.005). Conventional freezing was more effective than UF to cryopreserve sperm from Gabon bucks, at least in our experimental conditions. Most differences in favor of CF were observed in the quality of motility, and the percentages of motile sperm, progressive motile sperm, sperm with functional membrane, and with intact acrosome during long periods of the year, or even remained throughout it.

Seasonality of the stress response in goat bucks when there is use of electroejaculation for semen collection.

Electroejaculation (EE) is frequently used to collect semen, but this procedure is both stressful and painful. In seasonal-breeding species the sensitivity to stressors might vary with season of the year when semen collection occurs, therefore, the present study was conducted to compare the responses when imposing the EE procedure, stress response to EE and fresh semen characteristics in goat bucks throughout the year. Semen was collected using EE from goat bucks once in autumn (mid-breeding season), winter (transition to the non-breeding season), spring (non-breeding season), and summer (beginning of the breeding season). The number of pulses applied during ejaculation was larger in the autumn and spring than winter and summer months. The number of vocalizations/pulse while bucks were ejaculating was greater in the summer than winter and spring months. The increase in heart rate was greater in spring than summer months. Cortisol concentration was least in the autumn, and concentration of creatine kinase (CK) was greatest in summer. Sperm mass motility was greater in autumn than spring months. Spermatozoa concentration, total number of spermatozoa ejaculated, motile spermatozoa ejaculated, and progressively motile spermatozoa were greater in the autumn and spring than in the winter and summer months. The bucks were less stressed by imposing EE procedures in the autumn, and buck responses were greater in the spring-summer period. Bucks had a greater incremental increase in serum CK and number of vocalizations in the summer months, indicating there was a greater muscular damage and quite likely pain associated with lesser semen quality.

Treatment of male goats with equine chorionic gonadotrophin during the non-breeding season does not affect their sperm characteristics during the subsequent breeding season.

Equine chorionic gonadotrophin (eCG) is a hormone having FSH/LH effects. It can be used to enhance sperm quality in male goats (bucks) during the non-breeding season. In a previous study carried out during the non-breeding season, we treated ten bucks with eCG (leaving nine untreated animals as control). Over a 20-day period, the treated bucks received an initial dose of 800 IU of eCG, followed by four doses of 500 IU. We found eCG enhanced semen quality, however, as also happens in female goats (does), eCG also induced a high titer of anti-eCG antibodies. In does, this lowers fertility. The aim of the present study was to determine if the eCG treatment carried out on bucks during the non-breeding season had any negative effects on their reproductive status during the following breeding season. We measured serum concentration of testosterone and anti-eCG antibody, as well as key testicular and seminal characteristics. This study commenced 91 days after the final dose of eCG in the previous study. The anti-eCG titer was higher in the treatment bucks than in untreated ones (181.7 ± 61.3 ng/µL vs 31.1 ± 10.7 ng/µL; P < 0.05). However, there were no significant differences between treated and untreated bucks in testosterone concentration, scrotal circumference, testes pixel intensity, fresh and thawed semen characteristics, or sperm cryoresistance. So, although the eCG-treated bucks had greater titers of anti-eCG antibodies, their reproductive pattern was unaffected.

Equine Chorionic Gonadotropin (eCG) improves bucks' semen quality during the nonbreeding season.

In most goat breeds, testosterone serum concentration and semen quality decrease during the nonbreeding season. However, bucks reproductive activity may be stimulated with the administration of equine chorionic gonadotropin (eCG). Therefore, the aim of this study was to determine whether the repeated administration of eCG stimulates the reproductive status of bucks during the nonbreeding season. The study was performed with 19 bucks that were assigned to a group that was treated with eCG (GeCG) and an untreated control group (GCon). The GeCG bucks received an initial dose of 800 IU of eCG (Day 0), followed by four doses of 500 IU administered every 5 days beginning on Day 5. Serum testosterone and anti-eCG antibody concentrations, testicular and seminal traits were determined until Day 60. Testosterone concentration (from Day 3 to 21: p < 0.0001), anti-eCG titre (from Day 12 to 44: p ≤ 0.01), percentage of motile spermatozoa (Day 6: p = 0.006 and 14: p = 0.001) and of spermatozoa with progressive motility (Day 6: p = 0.01 and 14: p = 0.002) and the percentage of spermatozoa with functional membrane (Day 6: p = 0.02 and 22: p = 0.008) were higher in GeCG than in GCon bucks. Also in frozen-thawed samples, the percentage of motile spermatozoa tended to be higher in GeCG than that of GCon bucks (p = 0.07). In conclusion, the administration of eCG during the nonbreeding season stimulated the secretion of testosterone and improved fresh and possibly frozen-thawed semen quality. However, it also resulted in an increase in anti-eCG antibody titre.