Effect of season on fertility of frozen buffalo semen

Twenty double ejaculates from each of ten water-buffalo bulls were collected in June (non-breeding season) and again in November (breeding season). Fresh semen was screened for sperm quantity, motility, eosin uptake, and sperm morphology and was frozen using lactose, skim-milk, and Tris extenders. Thawed semen was checked for motility and Sephadex filtration. Half of each semen batch was used for artificial insemination in the breeding season and the other half during the non-breeding season.Laboratory screening revealed that June semen had a significantly lower Sephadex filtration rate and a higher percentage of abnormal sperm cells, and three June ejaculates were excluded from further processing due to poor sperm motility. In the remaining ejaculates the motility before freezing and the sperm cell quantity were higher in June semen than in November semen. Eosin uptake, mass motility, and post-freeze-motility did not vary with season. November semen produced significantly higher pregnancy rates than June semen over a total of 3220 inseminations in both seasons. Forty percent of the observed seasonality of buffalo fertility was attributable to the male. No fertility differences appeared between extenders used. When November semen was used, the fertility in adult buffaloes in both seasons was higher than in heifers.     

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

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

Microbial quality of equine frozen semen

Bacteriological surveillance is little applied in management of equine frozen semen but it is quite important to verify the microbial contamination in order to find out the chance of transmission of pathology to the mare in AI. Authors describe a qualitative and quantitative analysis for bacterial contamination on long time (3–17 years) equine frozen semen stored in liquid nitrogen. The semen checked, produced in Italy and in another Europe country, was cryopreserved in liquid nitrogen inside sealed plastic straws. One hundred and ten straws were checked out for pathogenic and no pathogenic bacteria, aerobes and anaerobes and fungi (moulds and yeasts). The Total Microbial Charge was quite variable with an average of about 1.4 × 10⁵ CFU/ml. Mostly the microbial agents identified were fungi (17.5%), Enterobacter-coccus spp. (15%), Pseudomonas spp. (6.25%), Stenothophomonas maltophila (6.25%) and anaerobic bacteria like Propionibacterium granulosum (7.5%) and Clostridium spp. (3.75%). 3.75% were unidentified Gram-negative rod and cocci. Streptococcus spp., Staph. aureus, E. coli, Th. equigenitalis and Mycoplasma spp. were not detected. The most represented species were Enterobacter-coccus spp. (1.1 × 10⁵ CFU/ml), St. maltophila (8 × 10⁴ CFU/ml) and Pr. granulosum (7 × 10⁴ CFU/ml) while yeast and even more moulds were little abundant (4.7 × 10⁴ and 3.4 × 10⁴ CFU/ml respectively). The knowledge of equine frozen semen microbial quality is essential to check out transmission of venereal disease and improve the quality of cryopreserved germplasm.     

The equine frozen semen industry.

Recent acceptance of frozen semen as a method to produce registered foals by two of the worlds largest breed associations, the American Quarter Horse and American Paint Horse, has stimulated new interest in frozen semen technology. This review will: (a) attempt to identify the major impediments to the development of the frozen semen industry, (b) suggest alternative methods for marketing and application of frozen semen, and (c) present the results of a recent study in our laboratory. The objective of which was to compare pregnancy rates of insemination with cooled and frozen semen. Major impediments to the development of the frozen semen industry include 1. Lower fertility with frozen semen as compared to cooled semen for many stallions. 2. Increased costs associated with management of mares for AI with frozen semen using current insemination protocols. 3. Unfavorable marketing practices for frozen semen. Reports of fertility with cooled transported semen in commercial breeding programs indicate seasonal pregnancy rates ranging from 60 to 90%. We compiled data from three commercial transported cooled semen programs in which semen from 16 stallions was used for insemination of 850 mares throughout North America by local veterinarians. During the 1999 and 2000 breeding seasons, first cycle and seasonal pregnancy rates of 59.4 and 74.7% were obtained. During that same period, first cycle and seasonal pregnancy rates of 51.3 and 75.6% were obtained following insemination of 876 mares with frozen semen from 106 different stallions processed by our laboratory and distributed through our commercial distribution program. First cycle and seasonal pregnancy rates were higher for mares bred outside of North America than for mares bred within North America (53.5 and 81.9 versus 49.4 and 65.6%, respectively). Seasonal pregnancy rates were higher presumably because of the better mare management employed for mares bred with exported semen and the fact that some of the domestic mares were switched to cooled semen insemination after a failed first cycle attempt with frozen semen. These data support the position that comparable seasonal pregnancy rates may be obtained using frozen and liquid cooled semen in a commercial setting.     

Equine frozen semen: freezability and fertility field results

The freezability of stallion semen defined as the number of selected ejaculates/total number of ejaculates frozen from 161 different stallions was analyzed. Of the stallions, 19, 30, 27 and 24% had a freezability of 0%, 0 to 33%, 33 to 66%, over 66%, respectively In 85 different stallions, the correlation of freezability between first and second year was 0.60 (P < 0.001). The relationship between fertility with fresh and frozen semen and freezability was analyzed in 40 stallions whose freezability and fertility information was recorded during 5 years. There was a strong relationship between fertility of fresh semen and semen freezability (P < 0.001). However, the relationship between fertility of frozen semen and freezability was not as marked (P < 0.05). Analysis of the field fertility per cycle results when mares were bred with 300 or 150 x 10(6) total spermatozoa at different frequencies until ovulation indicated that mares that were inseminated 2 times or more per estrus show an improved fertility in comparison with mares inseminated only once (34%, n = 1576 vs 26%, n = 626; P < 0.001). Foaling rate when mares were inseminated with frozen semen (1858 mares during 8 breeding seasons) was mainly influenced by mare age (< 16 years: 54% vs >/= 16 years 42% p < 0.001). Date of first insemination (before May 15: 58% vs after May 15: 37%) also had a significant effect on foaling rate (P < 0.001).     

Effect of time of insemination relative to ovulation on fertility with liquid and frozen boar semen

Precise data on fertility results following peri- and postovulatory insemination in spontaneously ovulating gilts is lacking. Using transcutaneous sonography every 4 h during estrus as a tool for diagnosis of ovulation, the effects of different time intervals of insemination relative to ovulation were investigated with liquid semen (Experiment 1, n=76 gilts) and frozen semen (Experiment 2, n=80 gilts). In Experiment 3 (n=24 gilts) the number of Day-28 embryos related to the various intervals between insemination and ovulation was determined after the use of liquid semen. Using liquid semen the fertilization rates based on Day-2 to Day-5 embryos and the number of accessory spermatozoa decreased significantly in gilts inseminated with 2 x 10(9) spermatozoa per dosage in intervals of more than 12 h before or more than 4 h after ovulation. In the time interval 4 to 0 h before ovulation, comparable fertilization rates were obtained using frozen semen (88.1%) and liquid semen (92.5%). Fertilization rates and numbers of accessory spermatozoa decreased significantly when gilts were inseminated with frozen semen more than 4 h before or 0 to 4 h after the detection of ovulation. The percentage of Day-28 embryos was significantly higher following preovulatory insemination compared to inseminations 0 to 4 h and 4 to 8 h after ovulation. It is concluded that the optimal time of insemination using liquid semen is 12 to 0 h before ovulation, and 4 to 0 h before ovulation using frozen semen. The results stress the importance of further research on sperm transport and ovulation stimulating mechanisms, as well as studies on the time of ovulation relative to estrus-weaning intervals and estrus duration.     

Management and fertility of mares bred with frozen semen.

Semen quality, mare status and mare management during estrus will have the greatest impact on pregnancy rates when breeding mares with frozen semen. If semen quality is not optimal, mare selection and reproductive management are crucial in determining the outcome. In addition to mare selection, client communication is a key factor in a frozen semen program. Old maiden mares and problem mares should be monitored for normal cyclicity and all, except young maidens, should have at least a uterine culture and cytology performed. Mares with positive bacterial cultures and cytologies should be treated at least three consecutive days when in estrus with the proper antibiotic. With frozen semen, timing the ovulation is highly desirable in order to reduce the interval between breeding and ovulation. The use of ovulation inducing agents such as human chorionic gonadotropin (hCG) or the GnRH analogue, deslorelin, are critical components to accurately time the insemination with frozen semen. Most hCG treated mares ovulate 48h post-treatment (12-72h) while most deslorelin (Ovuplant) treated mares ovulate 36-42h post-treatment. However, mares bred more than once during the breeding cycle appear to have a slight but consistent increase in pregnancy rate compared to mares bred only once pre- or post-ovulation. In addition, the "capacitation-like" changes inflicted on the sperm during the process of freezing and thawing appear to be responsible for the shorter longevity of cryopreserved sperm. Therefore, breeding closer to ovulation should increase the fertility for most stallions with frozen semen. Recent evidence would suggest that breeding close to the uterotubal junction increases the sperm numbers in the oviduct increasing the chances of pregnancy. Post-breeding examinations aid in determining ovulation and uterine fluid accumulations so that post-breeding therapies can be instituted if needed. Average pregnancy rates per cycle of mares bred with frozen semen are between 30 and 40% with a wide range between sires. Stallion and mare status are major factors in determining the success of frozen semen inseminations. Pregnancy rates are lower for barren and old maiden mares as well as those mares treated for uterine infections during the same cycle of the insemination. To maximize fertility with frozen semen, a careful selection of the stallions and mares, with proper client communication is critical. Dedication and commitment of mare owner and inseminator will have the most significant impact on the pregnancy rates.     

A field study of the fertility of transported equine semen

A field trial of artificial insemination in horses with transproted, chilled semen was conducted using a specially designed container which permitted a controlled, slow initial rate of cooling (-0.3 degrees C/min) and maintenance of a final temperature of 4 degrees -6 degrees C for more than 36 hrs. Forty-six mares in 23 states were inseminated with semen from three German Warmblood stallions standing at stud in Hamilton, Massachusetts. A third-cycle conception rate of 91% was obtained.     

Intrauterine insemination enhances fertility of frozen semen in superovulated ewes

Superovulated ewes were inseminated with fresh or frozen semen in a factorial experiment which compared two techniques of artificial insemination; i.e. conventional cervical deposition and intrauterine deposition at laparoscopy. Similar fertilization rates resulted from insemination with fresh semen at cervical (81% of ova from 11/11 ewes) and intrauterine (83% of ova from 10/12 ewes) sites. These results approached those observed in a naturally-mated group (95% of ova from 5/5 ewes). In ewes inseminated with frozen semen, fertilization rate was markedly reduced (P less than 0.05) after cervical insemination (11% of ova from 3/11 ewes) and partly restored (P less than 0.05) after intrauterine insemination (50% of ova from 8/11 ewes).     

Effect of sperm number and frequency of insemination on fertility of mares inseminated with cooled semen

In this study, we tested the hypothesis that insemination of mares with twice the recommended dose of cooled semen (2 x 10(9) spermatozoa) would result in higher pregnancy rates than insemination with a single dose (1 x 10(9) spermatozoa) or with 1 x 10(9) spermatozoa on each of 2 consecutive days. A total of 83 cycles from 61 mares was used. Mares were randomly assigned to 1 of 3 treatment groups when a 40-mm follicle was detected by palpation and ultrasonography. Mares in Group 1 were inseminated with 1 x 10(9) progressively motile spermatozoa that had been cooled in a passive cooling unit to 5 degrees C and stored for 24 h. A second aliquot of semen from the same collection was stored for an additional 24 h and inseminated at 48 h after collection. Mares in Group 2 were inseminated once with 1 x 10(9) progressively motile spermatozoa that had been cooled to 5 degrees C and stored for 24 h. Group 3 mares were inseminated once with 2 x 10(9) progressively motile spermatozoa that had been cooled to 5 degrees C and stored for 24 h. All mares were given 2500 IU i.v. hCG at the first insemination. Pregnancy was determined by ultrasonography 12, 14 and 16 d after ovulation. On Day 16, mares were administered i.m. 10 mg of PGF2 alpha and, upon returning to estrus, were randomly reassigned to a group for repeated treatment. Semen was collected from one of 3 stallions every 3 d; mares with a 40-mm ovarian follicle were inseminated with semen from the stallion collected on the preceding day. Semen was allocated into doses containing 1 x 10(9) progressively motile spermatozoa, diluted with dried skim milk-glucose extender to a concentration of 25 x 10(6) motile spermatozoa/ml (total volume 40 ml), placed in a passive cooling unit and cooled to 5 degrees C for 24 or 48 h. Response was measured by number of mares showing pregnancy. Data were analyzed by Chi square. Mares inseminated twice with 1 x 10(9) progressively motile spermatozoa on each of two consecutive days had a higher pregnancy rate (16/25, 64%; P < 0.05) than mares inseminated once with 1 x 10(9) progressively motile spermatozoa (9/29, 31%) or those inseminated once with 2 x 10(9) progressively motile spermatozoa (12/29, 41%). Pregnancy rates did not differ significantly (P > 0.10) among stallions (69, 34 and 32%). Interval from last insemination to ovulation was 0.9, 2.0 and 2.0 d for mares in Groups 1, 2 and 3, respectively. Based on these results, the optimal insemination regimen is a dose of 1 x 10(9) progressively motile spermatozoa given on two consecutive days. However, a shorter interval (< or = 24 h rather than > 0.9 d) between insemination and ovulation may affect pregnancy rates, and needs to be investigated.     

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

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

Cryopreservation and post-thawed fertility of ram semen frozen in different trehalose concentrations

We evaluated freeze-thawing tolerance of heterospermic ram spermatozoa (Pampinta breed) in a base diluent (Tris, citric acid, fructose, egg yolk, glycerol) with the addition of different trehalose concentrations (0-400 mOsm). We chose sperm motility, acrosome integrity and hypo-osmotic swelling test as parameters to evaluate cryopreservation capacity. We obtained the best results for 50 and 100 mOsm trehalose-supplemented extenders, with values (referred to fresh semen values) of 65% for motility, 75% for acrosome integrity and 50% for hypo-osmotic swelling test, while freeze-thawing tolerance diminished significantly for 200 and 400 mOsm of the disaccharide. Fertility values measured at lambing were 47.1 and 44.6% (2 consecutive years), using semen cryopreserved in 100 mOsm trehalose-containing diluent, which is 2.5 times greater than those obtained with the base diluent (18.5 and 14.5%). We conclude that the membrane-protecting disaccharide trehalose confers a greater cryoprotective capacity to the base extender, when added up to 100 mOsm. This action is reflected in the different sperm membranes, the motile activity and in vivo fertility.