Field investigations of bacterial contaminants and their effects on extended porcine semen

Field investigations (n=23) were made over a 3-yr period at North American boar studs and farms in which the primary complaint was sperm agglutination in association with decreased sperm longevity of extended semen, and increased regular returns to estrus and/or vaginal discharges across parity. Microscopic examination of extended semen from these units revealed depressed gross motility (usually <30%), sperm agglutination, and sperm cell death occurring within 2 d of semen collection and processing regardless of the semen extender used. The extended semen exhibited a high number of induced acrosome abnormalities (>20%). Sample pH was acidic (5.7 to 6.4) in 93% of the submitted samples. Aerobic culture yielded a variety of bacteria from different genera. A single bacterial contaminant was obtained from 66% of the submitted samples (n=37 doses); 34% contained 2 or more different bacterial genera. The most frequently isolated contaminant bacteria from porcine extended semen were Alcaligenes xylosoxydans (n=3), Burkholderia cepacia (n=6), Enterobacter cloacae (n=6), Escherichia coli (n=6), Serratia marcescens (n=5), and Stenotrophomonas [Xanthomonas] maltophilia (n=6); these 6 bacteria accounted for 71% of all contaminated samples, and were spermicidal when re-inoculated and incubated in fresh, high quality extended semen. All contaminant bacteria were found to be resistant to the aminoglycoside gentamicin, a common preservative antibiotic used in commercial porcine semen extenders. Eleven genera were spermicidal in conjunction with an acidic environment, while 2 strains (E. coli, S. maltophilia) were spermicidal without this characteristic acidic environment. Bacteria originated from multiple sources at the stud/farm, and were of animal and nonanimal origin. A minimum contamination technique (MCT) protocol was developed to standardize hygiene and sanitation. This protocol focused on MCT's during boar preparation, semen collection, semen processing and laboratory sanitation. Implementation of the MCT, in addition to specific recommendations in stud management, resulted in the control of bacterial contamination in the extended semen.     

An update on North American boar stud practices

This survey included 44 boar studs from Canada and the USA with a total of approximately 10,000 boars. Studs with 51-500 boars accounted for 84% of respondents. More than 90% of boars were housed in stalls. Evaporative and mechanical cooling systems predominated and boars were typically fed based on body condition. The predominant age of boars was 1-2 years with annual culling rates between 20 and 70%. The primary reasons for culling included genetic improvement, semen quality and feet and leg issues. Collection occurred commonly on Mondays and Thursdays and boars were rested 3-7 days between collections. The average sperm produced per boar per week was 51-150 billions and resulted in 21-40 doses per boar per week. Most studs collected boars using double gloves and disposable cups or liners and used pre-warmed containers. Ejaculate pooling was practiced by >60% of studs. Evaluation of semen for motility was performed with 0-5min of warming in extender with viewing at 100-400x magnification. Concentration estimation occurred by photometer and CASA for 88% of studs. Ejaculate discard occurred for reasons of poor motility, abnormal sperm and bacteria. Most studs retained extended samples for 3-7 days for quality control. Discard rates were most common between 1 and 10% and were related to individual boar and season. Doses of semen contained 2-4 billion sperms, with final sperm numbers adjusted for fertile sperm and packaged as doses in tubes and bags with 60-100mL.     

Characterization of lower temperature storage limitations of fresh-extended porcine semen

Irreversible damage caused by cold shock has been assumed to occur when boar semen is exposed to temperatures below 15 degrees C. Identification of the lower critical temperature at which extended boar semen undergoes cold shock, however, has yet to be defined. The aims of this study were to 1) identify the cold-shock critical temperature and time on extended boar semen as assessed by sperm motility and morphology, and 2) determine the effects on fertility of using extended porcine semen exposed to this critical temperature and time. For Objective 1, ejaculates from 18 boars were collected, analyzed and extended in Androhep to 50 x 10(6) sperm/mL. Doses (4 x 10(9) sperm) from each ejaculate were exposed to 5 storage temperatures (8, 10, 12, 14 and 17 degrees C). Sperm motility and morphology (including acrosomes) were assessed following collection and at 12-h intervals for 48-h. Decreases in sperm motility occurred within the first 12-h at all temperatures. Sample motility dropped below 70% within 12-h in the 8 degrees C group and by 48-h in the 10 degrees C group. Sample motility was > 75% in the 12, 14 and 17 degrees C (control) groups throughout the trial. The percentage of morphologically abnormal sperm cells, including acrosomes, did not change within or between treatment groups over the 48-h storage period. In Objective 2, boar ejaculates (n = 9) were handled as in the first objective and were equally divided into treated (12 degrees C for < or = 60-h) and control (17 degrees C for < or = 60-h) groups. Using a timed, double insemination technique, 135 sows were bred by AI using either 12 degrees C (n = 74) or 17 degrees C (n = 61) extended, stored semen. No differences were observed in the farrowing rate (93 vs 95%), total offspring born (11.58 vs 11.61) or number live born (10.68 vs 10.63) between 12 and 17 degrees C groups, respectively. The results demonstrate that acceptable fertility can be obtained with Androhep extended boar semen exposed to temperatures as low as 12 degrees C for up to 60-h, and that cold shock appears to occur in vitro when extended boar semen is exposed to storage temperatures below 12 degrees C.     

Prevalence of chlamydiae in boars and semen used for artificial insemination

Although there are indications for venereal transmission of chlamydiae in pigs, direct diagnostic evidence on the presence of these bacteria in boars and boar semen in particular is still incomplete. We investigated boars from two studs (A, B) in semen (A: n = 174; B: n = 100) and faeces (A: n = 174; B: n = 24) for chlamydiae using ompA-PCR and partial ompA gene sequencing. Additionally, blood serum was examined for chlamydial antibodies using an indirect ELISA (A: n = 171; B: n = 62). Chlamydiae were found in 9 (5.2%) and 24 (24.0%) semen specimens, and in 71 (40.1%) and 2 (8.3%) faecal samples from boars of stud A and B, respectively. Regarding individual chlamydial species, Chlamydophila psittaci and Chlamydia suis were identified most frequently, with the former predominating in semen (in 23 out of 33 positive samples) and the latter in faeces (68/73). In contrast, Chlamydophila pecorum was found only sporadically. Chlamydial antibodies were detected in 80 (46.8%) and 6 (9.7%) boars of stud A and B, respectively. No correlation was observed between the data from serology and PCR of semen or faeces in either of the studs. In conclusion, detection of chlamydiae in semen of boars suggests a potential for venereal transmission. Whether the high overall prevalence of chlamydial infections reflects a general situation in boars needs to be investigated. Serological testing failed to identify boars shedding chlamydiae in their semen.     

Adverse effects of members of the Enterobacteriaceae family on boar sperm quality

Semen samples collected in 2012 from 1785 boars belonging to five different breeds were recruited from the quality control laboratory of Magapor SL, Spain. These samples came from 43 boar studs and resulted from diluting the ejaculates in commercial semen extenders. Evaluation of the semen sample characteristics (color, smell, pH, osmolality, concentration, motility of sperm cells, agglutination, acrosome integrity, short hypoosmotic swelling test, and abnormal forms) revealed that they met the international standards. The samples were also tested for the presence of aerobic bacterial contamination. In the present study, 14.73% (n = 263) of the semen samples were contaminated above 3 × 10² colony-forming units/mL with at least one type of bacteria. The Enterobacteriaceae family was by far the major contaminant, being present in 40.68% of the contaminated samples (n = 107). Bacterial strains of the Enterobacteriaceae family isolated from boar semen samples were in order of incidence (percentage of the contaminated samples): Serratia marcescens (12.55%), Klebsiella oxytoca (11.79%), Providencia stuartii (9.12%), Morganella morganii (3.80%), Proteus mirabilis (1.90%), and Escherichia coli (1.52%). We have seen that the presence in semen samples of S. marcescens, K. oxytoca, M. morganii, or P. mirabilis, but not P. stuartii or E. coli, was negatively associated with sperm motility (P < 0.05). The mean sperm concentration (P < 0.05), the mean percentage of spermatozoa with curled tails after the short hypoosmotic swelling test (P < 0.01), and the incidence of morphologically normal acrosomes (P < 0.05) were also lower in semen samples infected with M. morganii compared with uninfected ones. Moreover, P. mirabilis was negatively associated with the presence of abnormal forms. Thus, on the basis of the pathological effects that some of these strains may have on boar sperm quality, bacterial contamination should always be examined in semen samples prepared for artificial insemination.     

Examination of some processing methods for freezing boar semen.

Five experiments were conducted to examine the effect of processing methods and diluents on survival and morphology of boar spermatozoa after freezing. Post-thawing survival of spermatozoa was better for Beltsville-F3 (BF3) than for tris-fructose-EDTA freezing diluent when the seminal plasma and glycerol were removed prior to freezing (method A). Both freezing diluents yielded similar viability results when the spermatozoa were frozen in the presence of siminal plasma and glycerol (method B). Viability of spermatozoa after thawing was better when glycerol concentration in the prefreezing diluent (method A) or in the freezing medium (method B) was 2-5 and 5-0 rather than 7-5%. Cooling of diluted semen to 5 degrees C beyond 4 h decreased the post-thawing survival of spermatozoa. The proportion of spermatozoa with undamaged acrosomes after processing and thawing by different methods was indistinguishable and relatively low. When the semen was frozen at cell concentrations ranging from 0-25 to 2-0 X 10(9)/ml, the viability of spermatozoa declined with increasing concentration following freezing in BF3, and S-1 diluents. Viability results were very similar for all cell concentrations examined when tris-fructose-EDTA diluent was used, indicating the possibility of freezing boar semen in a concentrated state.     

Fertility test of frozen boar semen.

The fertility results of two experiments are presented. In experiment 1, the semen was frozen in tris-fructose-EDTA or BF3 diluents at 0-25 X 10(9)/ml sperm concentration and extended after thawing with either seminal plasma (SP) or the freezing medium (FM) containing no cryoprotective agent. In the second experiment the semen was glycerolated by two methods, frozen at 1-0 X 10(9)/ml sperm concentration, and extended wtih FM before insemination. Fertility after double insemination within one oestrus with semen frozen in tris-fructose-EDTA or BF3 diluents varied depending on the medium used for extension of thawed semen. The farrowing rates for semen frozen in the former diluent with FM and SP post-thawing media were 4/8 and 1/8 respectively, and for semen frozen BF3 diluent with FM and SP post-thawing extenders 1/8 and 5/8. The mean farrowing for the 32 animals inseminasted was 34-4%. Pregnancies for semen frozen in tris-fructose-EDTA and glycerolated at 30 or 5 degrees C were 5/12 and 4/12 respectively, and for single and double inseminations 6/12 and 3/12 respectively. Of 24 animals inseminated 37-5% farrowed.     

Concentrations of endogenous prostaglandin F2alpha in boar semen and effect of a 72-h incubation period on exogenous prostaglandin F2alpha concentration in extended boar semen

PGF2alpha in semen has been shown to induce uterine contractions, thereby, facilitating sperm transport during fertilization. Previously, we demonstrated that extended boar semen used in artificial insemination does not increase myometrial contractility, but PGF2alpha supplementation did. In this study, we determined the concentrations of endogenous PGF2alpha in pre-sperm and sperm-rich fractions of the boar ejaculate and examined whether changes in the concentration of exogenous PGF2alpha occurred when added to extended boar semen after 72-h incubation at a 17 degrees C storage temperature. Concentrations of endogenous PGF2alpha (n = 10 boars) in pre-sperm and sperm-rich fractions were 69.6 +/- 7.6 and 58.9 +/- 4.4 pg/ml, respectively. No differences were observed in the concentrations of exogenous PGF2alpha in the extended boar semen at 0 h (59.3 +/- 3.3 microg/ml) and after a 72-h incubation period (52.0 +/- 2.1 microg/ml). These results suggest that the concentration of endogenous PGF2alpha in boar semen used for artificial insemination is < 100 pg/ml. The concentration of exogenous PGF2alpha in the extended boar semen did not differ after 72 h, which indicates that it is not metabolized during this period of time.     

Motility and fertility of alginate encapsulated boar spermatozoa

Ejaculated boar spermatozoa are vulnerable to cold shock. Prolonged storage of boar spermatozoa at low temperatures reduces survival rate, resulting in a bottleneck for the extension of artificial insemination in pig husbandry. This study evaluated whether alginate microencapsulization processing can improve the longevity of boar spermatozoa stored at 5 degrees C and the fertility of microencapsulated spermatozoa in vivo. Sperm-rich fraction semen from three purebred boars were concentrated and microencapsulated using alginate at 16-18 degrees C, and then were stored at 5 degrees C. Following storage for 1, 3 and 7 days, the microcapsule was taken out to assess sperm release under 37 degrees C incubation with or without 110 rpm stirring. The percentage of sperm released from microcapsules with 110 rpm stirring was higher than without stirring (81 versus 60%) after 24h of incubation. In another experiment, semen was also microencapsulated to evaluate the sperm motility. The motility of spermatozoa was assessed at 10 min, 8, 24, 32, 48, 56 and 72 h following incubation at 37 degrees C for nine consecutive days. The fertility of the free and microencapsulated semen was assessed by inseminating sows, and the reproductive traits (conception rate, farrowing rate, and litter size) were recorded. The motility of encapsulated spermatozoa was significantly higher than that of free semen after 8h incubation at 37 degrees C after storing for over three days (P<0.05). No significant difference existed in conception rate, farrowing rate, and litter size between the microencapsulated and non-encapsulated semen after four days of storage. In conclusion, microencapsulation can increase the longevity of boar spermatozoa and may sustain in vivo ova fertilization ability.     

Assessment of sperm viability,mitochondrial activity,capacitation and acrosome intactness in extended boar semen during long-term storage

The purpose of this study was to assess sperm quality in extended boar semen during in vitro storage in order to determine which extender should be used and how long boar semen can be stored. Freshly ejaculated boar semen was diluted with equal volumes of Beltsville thaw solution (BTS), Androhep, KIEV or Zorlesco extenders and stored at 17 degrees C for up to 15 days. Sperm quality was evaluated by examining viability using SYBR-14/PI and Hoechst 33258 staining, mitochondrial activity using 5,5',6,6'-tetrachloro-1,1',3,3'-tetraethylbenzimidazolyl-carbocyanine iodide (JC-1) staining, acrosome intactness by Coomassie blue staining, and capacitation status by chlortetracycline (CTC) staining. There were over 50% viable spermatozoa in boar semen extended with Zorlesco and Androhep extenders on Day 13 of storage. The percentage of JC-1-stained spermatozoa was 53.8 +/- 2.1% for Zorlesco and 57.7 +/- 1.60% for Androhep extenders on Day 13 of storage. The percentage of acrosome-intact spermatozoa detected by Coomassie blue staining was higher than that in the SYBR-14PI-, Hoechst 33258-, and JC-1-stained samples in our study. The results from SYBR-14/PI, Hoechst 33258, JC-1, and Coomassie blue staining were highly correlated (r > or = 0.9461). There were less than 15% capacitated spermatozoa in the semen extended with BTS, Androhep and Zorlesco extenders during 9 days of storage. However, most viable boar spermatozoa became capacitated by Day 13 of storage. The rank order of four extenders for maintaining sperm viability and mitochondrial activity was as follows: Androhep, Zorlesco, BTS, KIEV.     

Studies on liquefaction and storage of ejaculated dromedary camel (Camelus dromedarius) semen

The purpose of this study was to evaluate seminal liquefaction and quality of ejaculated camel semen during storage in different extenders at room (23 degrees C) and refrigeration (4 degrees C) temperature. Semen was collected using an artificial vagina and diluted immediately (1:1), using a split-sample technique, in five extenders [(1) Tris-tes egg yolk, (2) Tris-lactose egg yolk, (3) citrate egg yolk, (4) sucrose egg yolk and (5) Tris-fructose egg yolk], while one fraction was kept without an extender to act as control. The semen was transported to the lab at 37 degrees C, in a portable incubator within half an hour, and thereafter liquefaction of semen was monitored every 15 min. After complete liquefaction of the semen it was evaluated for sperm concentration and morphology and then was extended to a final ratio of 1:3. Aliquots of each semen sample were then stored at refrigeration and room temperature. The average volume of an ejaculate was 4.3+/-0.4 mL and it had a very viscous consistency. The average concentration of spermatozoa was 230.4+/-10.7 x 10(6)mL(-1) and the proportion of spermatozoa with protoplasmic droplets averaged 1.02+/-0.2, while 2.7+/-0.6 and 9.7+/-2.9% had mid-piece and tail abnormalities, respectively. All extended semen samples liquefied within 1.5h at 37 degrees C, however, there was slow liquefaction in the sample without an added extender (control). Best liquefaction was observed in Tris-lactose extender followed by Tris-fructose and citrate egg yolk diluents whereas in the other two extenders there was head-to-head agglutination of the spermatozoa. There was no difference in the initial motility of the spermatozoa in extenders 1-5 after its liquefaction, however, after 24 and 48 h of storage a higher proportion of spermatozoa were motile in extenders 1, 2 and 4 (P<0.05) at both the temperatures. There was a gradual decline in viability of the spermatozoa in all extenders at both the temperatures, although, a high portion of the spermatozoa had intact acrosomes throughout the storage period. It may be concluded that dromedary semen, when added to an extender (1:1) immediately after collection, liquefies within 60-90 min at 37 degrees C. It maintains a high proportion of motile and viable spermatozoa that can survive storage up to 48 h in Tris-lactose egg yolk, Tris-tes egg yolk and sucrose egg yolk diluents. However, best liquefaction and progressive sperm motility is achieved in Tris-lactose egg yolk extender.     

Assay of frozen boar semen with Sephadex filtration

The suitability of filtration of frozen boar semen through Sephadex G-15-120 as a viability assay was investigated. Semen thawed on a hot plate at 38 degrees C was counted with a Coulter Counter before and after filtering through Sephadex columns with 0.1 M sodium citrate as flushing medium. More spermatozoa passed through the column when the temperature of the flushing medium was elevated from room temperature to 37 degrees C and added with 5 mM caffeine (12.3 vs. 22.8% p<0.01). The use of caffeine and 37 degrees C flushings produced a filtrate containing spermatozoa with 89+/-4% motility and 97.6+/-1.6% normal acrosome ridges with the use of frozen semen from 5 different boars. The repeatability was +/-7.3%. The unfiltered samples were judged to contain 45 +/- 8% motile spermatozoa and 66.6 +/- 7.1% spermatozoa with normal acrosome ridges. Filtering of frozen boar semen through Sephadex is proposed as a rapid, objective assay combining the benefits of differential counting of normal acrosome ridges and motility determination.     

Acrosomal damage and progressive motility of stallion semen forzen by two methods in 0.5-milliliter straws

Post centrifugation and postthaw progressive motility and postthaw acrosomal damage were used to evaluate two different freezing methods (A and B) on 11 ejaculates of one stallion and 6 of another. In Method A, extended semen was centrifuged in 50-ml centrifugation tubes in which 0.25 ml hyperosmotic, glucose-based medium were layered in the apex of the tubes to serve as a cushion. Spermatozoa were resuspended in freezing medium, packaged in 0.5-ml PVC straws and frozen at - 60 degrees C/min. Method B differed only in that the hyperosmotic cushion was omitted during centrifugation. Straws were thawed at 75 degrees C for 6 sec and then transferred into a waterbath at 37 degrees C. The postcentrifugation and postthaw progressive motility and postthaw acrosomal damage were similar for Methods A and B. Method B, however, was found to be technically easier to carry out. It also offers less chance of error or contamination because only two diluents are admixed to the semen as opposed to the three diluents used in Method A. Method B is regarded as more practical and thus preferable to Method A.     

Prevalence of PCV2 in Austrian and German boars and semen used for artificial insemination

Since epidemiologically-based science on PCV2 in porcine semen is patchy, we investigated 806 Austrian (A) and German (G) AI boars from five studs, and boars from Austrian farms used for on-farm semen collection, for the presence for IgG/IgM in blood by ELISA (n=754) as well as for PCV2 DNA in semen (n=472) and if positive, also in blood of a few boars by nested PCR and sequencing. A total of 420 boars were tested for both PCV2 in semen and antibodies in blood. Boars were aged between 8 and 82 months at sampling. None of the boars tested positive for IgM but 60.1% did for IgG. PCV2 DNA was detected in 86 (18.2%) semen samples. Minor differences were found between boar populations with respect to the number of antibody positive boars and no differences for DNA in semen. Phylogenetic analysis of 28 sequences revealed a genetic diversity of PCV2 in semen within and between boar populations, with sequences belonging to both PCV2 genotypes 1 and 2. Mean nucleotide sequence identity was 95.7%, with maximum pairwise difference of 8.8%. Boars < or =16 months were tested more frequently positive for IgG (P<0.001) and for PCV2 DNA in semen (P<0.05) than older boars. Of 80 boars tested positive in semen, 34 (42.5%) were antibody negative. A total of 58 semen positive boars with (n=33) and without (n=25) IgG were all tested negative for PCV2 DNA in serum. In conclusion, this study demonstrated the ubiquity of PCV2 in the Austrian and German boar population. Genetically diverse PCV2 can be encountered in boar semen. Shedder boars cannot be detected on the basis of serology. There is an apparent possibility of PCV2 being transmitted through semen.     

Influence of cryoprotective diluent on post-thaw viability and acrosomal integrity of spermatozoa of the African elephant (Loxodonta africana)

Electroejaculates from free-ranging, African elephants were frozen to test various seminal diluents, freezing methods and thawing media on post-thaw sperm viability and structural integrity. In Study I, each ejaculate was tested with each of 7 cryoprotective diluents. After cooling to 5 degrees C and equilibration on ice (4 degrees C) for 120 min, each aliquant was pellet frozen on solid CO2, stored in liquid nitrogen and thawed (37 degrees C) in saline or tissue culture solution. Amongst all diluents, post-thaw sperm motility, motility duration in vitro (37 degrees C) and acrosomal integrity were greatest (P less than 0.05) when diluent BF5F was used. Thawing medium had no effect on results. In Study II, the optimal diluent from Study I (BF5F) was compared with the diluent SGI. Results were not affected by a 90- or a 150-min cooling-equilibration interval in an electronic cooler (5 degrees C); however, post-thaw sperm motility rating and duration of motility in vitro were greater (P less than 0.01) with the pellet than the straw container freezing method. When the pelleting method was used, diluents BF5F and SGI provided comparable cryoprotection. Duration of post-thaw motility was enhanced 2-fold and up to 12 h by maintaining thawed semen at 21 rather than 37 degrees C (P less than 0.05). All diluents provided some protection on acrosomal integrity, but the overall proportion of intact acrosomes after thawing was markedly less in Study II, apparently as a result of the slower initial cooling rate (approximately 1.5 degrees C/min) compared to that of Study I (approximately 6.5 degrees C/min). This study demonstrates the feasibility of cryopreserving semen from free-ranging African elephants and indicates that spermatozoa must effectively survive freezing when the BF5F or SGI diluent is used in conjunction with the pelleting method.     

Prostaglandin F2alpha added to extended boar semen at processing elicits in vitro myometrial contractility after 72 hours of storage.

Improved fertility will maximize productivity of the swine industry. Myometrial contractility is an essential component in the fertilization process because it is the mechanism by which spermatozoa are transported to the site of fertilization. In the present study, we evaluated the potential use of PGF2alpha supplementation to the extended pig semen in regard to inducing myometrial contractility of sows. Extended boar semen (80 mL) was supplemented with PGF2alpha (5 mg) for 72 h at 17 +/- 1 degrees C. Cumulative doses of 0.1, 1, 10 and 100 microL of the mixture were tested on uterine strips obtained from diestrus sows. An increase in myometrial contractility was recorded with PGF2alpha supplementation when compared to extended semen or extender treatment alone after 72 h of incubation. Addition of PGF2alpha to the extended boar semen at the time of the experiment did not differ from the 72 h treated group. The results from this study support that PGF2alpha preparations can be added to extended doses of boar semen at processing to enhance myometrial contractility at the time of insemination for up to 72 h.     

Effects of solid storage of sheep spermatozoa at 15 degrees C on their survival and penetrating capacity

This study was designed to evaluate the possible benefits of adding gelatin to a standard milk extender, for solid storage of sheep semen at 15 degrees C. Solid storage was assessed in terms of effects on sperm motility and membrane integrity up to 2 days (Study 1), and on in vitro penetration capacity after storage for 24h (Study 2). In both studies, semen was diluted in CONTROL (standard milk extender) and GEL (1.5 g gelatin/100ml extender) diluents to a final concentration of 400 x 10(6)sperm/ml. In Study 1, semen samples were stored at 15 degrees C, and sperm quality variables analyzed after 2, 24 and 48 h of storage. Motility and viability values were significantly lowered using the liquid compared to the gel extender for all storage periods, except for motility after 2h of storage, whose values were similar. After 2h of incubation at 37 degrees C, motile cell percentages and membrane integrity were significantly lower in the CONTROL group than in the GEL group for all storage periods. In Study 2, in vitro matured lamb oocytes were randomly divided into three groups and fertilized with CONTROL diluted semen stored for 2h or 24h, or with GEL diluted semen stored for 24h. After co-incubation, oocytes were evaluated for signs of penetration. Storage of semen in the GEL diluent for 24h gave rise to increased in vitro fertilization rates in comparison with the CONTROL diluent. Our findings indicate that the solid storage at 15 degrees C of ram spermatozoa by adding gelatin to the extender leads to improved survival and in vitro penetrating ability over the use of the normal liquid extender. A solid diluent could thus be a useful option for the preservation of fresh ovine semen for extended periods.     

Liquid storage of miniature boar semen.

The effects of liquid storage at 15 degrees C on the fertilizing ability of miniature pig semen were investigated. Characterization of ejaculated semen from 3 miniature boars was carried out. Semen volume and pH were similar among these boars. In one of the boars, sperm motility was slightly low, and sperm concentration and total number of sperm were significantly lower than in the others (P < 0.01). Seminal plasma of the semen was substituted with various extenders (Kiev, Androhep, BTS and Modena) by centrifugation and semen was stored for 7 days at 15 degrees C. Sperm motility was estimated daily at 37 degrees C. For complete substitution of seminal plasma, Modena was significantly more efficient than the other extenders (P < 0.001) in retaining sperm motility. Semen from each of the 3 miniature boars that had been stored for 5 to 7 days at 15 degrees C in Modena was used for artificial insemination of 15 miniature sows. The farrowing rates were 100, 100 and 60%, and litter sizes were 6.4 +/- 1.5, 5.8 +/- 0.8 and 5.0 +/- 1.0 for each boar semen, respectively. The boar that sired the smallest farrowing rate was the same one that showed lower seminal quality with respect to sperm motility, sperm concentration and total number of sperm. These results suggest that miniature boar semen can be stored for at least 5 days at 15 degrees C by the substitution of seminal plasma with Modena extender.     

The predictive value of routine semen evaluation and IVF technology for determining relative boar fertility

Practical techniques for assessing semen quality in order to predict male fertility are still needed. The principal objective of this experiment was to evaluate routine laboratory evaluation and in vitro fertilization (IVF) techniques as predictors of relative boar fertility using a low-dose AI protocol. Nine boars were evaluated during a 6.5+/-1 mo period, beginning at 29-32 wk of age. Ejaculates were evaluated for motility, morphology and concentration, diluted to 1.5 billion sperm in 50 mL extender, and used to breed 50+/-5 gilts over the same period. On nine occasions, a specific aliquot of the ejaculate's first sperm-rich fraction was evaluated using IVF procedures. Boars differed (P<0.001) consistently for pregnancy rate (from 73 to 98%), farrowing rate (71-98%) and total born (8.8-12.0). Routine semen evaluation and IVF parameters that presented significant differences between boars, but no differences in time and no boar by time interaction, were used to correlate in vivo fertility. A multiple regression model based on routine semen evaluation parameters accounted for up to 27 and 22% of the variation of fertility index and total piglets born, respectively, whereas male pronuclear formation rate was the IVF variable that accounted for 17 and 12% of the variation in farrowing rate and fertility index, respectively. Collectively, we inferred that the use of low sperm numbers for AI, determination of pregnancy rate at Day 30, motility of extended semen after 7 and 10d, and specific IVF parameters may be useful for identifying relatively infertile boars that are not currently excluded from use in existing commercial boar studs.     

Use of two freezing extenders to cool stallion spermatozoa to 5 degrees C with and without seminal plasma

Motion characteristics of cooled stallion spermatozoa in 2 freezing extenders were studied. Ejaculates from 8 stallions were split into treatments and cooled in thermoelectric cooling units at each of 2 rates. Cooling started at 37 degrees C for Experiments 1 and 3 and at 23 degrees C for Experiments 2 and 4, at a rate of -0.7 degrees C/min to 20 degrees C and from 20 to 5 degrees C, at either -0.05 degrees C/min (Rate I) or -0.5 degrees C/min (Rate II). Percentages of motile (MOT) and progressively motile spermatozoa (PMOT) were determined at 6, 24 and 48 h. Treatments in Experiment 1 were modified skim milk extender (SM); SM + 4% egg yolk (EY); SM + 4% glycerol (GL); and SM + 4% egg yolk + 4% glycerol (EY + GL). At 24 and 48 h, MOT and PMOT were lowest (P < 0.05) for spermatozoa extended in SM + EY; spermatozoa in SM + GL had the highest MOT and PMOT. Thus, glycerol partially protected spermatozoa against the effects of cooling after long-term storage. Treatments in Experiment 2 were SM, semen centrifuged and pellet resuspended in SM (SMc), SM + EY, and semen centrifuged and pellet resuspended in SM + EY (EYc). Spermatozoa in SM + EYc had the highest (P < 0.05) PMOT at 24 h and MOT and PMOT at 48 hours. Spermatozoa in SM + EY (not centrifuged) had the lowest MOT and PMOT at 24 and 48 h, respectively. There was a detrimental interaction between egg yolk and seminal plasma. Extenders in Experiment 3 were Colorado extender (CO3), CO3 + 4% egg yolk (EY), CO3 + 4% glycerol (GL), and CO3 + 4% egg yolk + 4% glycerol (EY + GL). Spermatozoa in CO3 + EY had the lowest (P < 0.05) PMOT at 24 and 48 h. CO3 did not protect spermatozoa cooled in the presence of seminal plasma. Therefore, in Experiment 4 we tested CO3 with seminal plasma present (control) and semen centrifuged and pellet resuspended in CO3 (CO3c), CO3 + EY (EYc), CO3 + GL (GLc) and CO3 + EY + GL (EY + GLc). Spermatozoa in CO3 had the lowest (P < 0.05) MOT and PMOT at all time periods, which suggested a detrimental interaction of this extender with seminal plasma.