Effect of centrifugal fractionation protocols on quality and recovery rate of equine sperm

Centrifugal fractionation of semen is commonly done to improve quality of human semen in assisted-reproduction laboratories, allowing sperm separation based on their isopycnic points. Sperm with morphologic abnormalities are often more buoyant, promoting their retention above defined density media, with structurally normal sperm passing through the media following centrifugation. Three experiments were conducted to evaluate the effects of density-medium type, centrifuge-tube size, sperm number, and density-medium volume (column height) on stallion sperm quality and recovery rate in sperm pellets following centrifugation. In all three experiments, equine semen was initially centrifuged to increase sperm concentration. In Experiment 1, semen was layered over continuous or discontinuous gradients. For Experiment 2, semen was layered over three column heights of continuous gradients in 15- or 50-ml conical-bottom tubes. For Experiment 3, increasing sperm numbers were layered over continuous gradient in 15- or 50-ml conical-bottom tubes. Following centrifugation, sperm pellets were evaluated for sperm morphologic quality, motility, DNA integrity, and recovery rate. Centrifugal fractionation improved (P < 0.05) sperm morphology, motility, and DNA integrity, as compared to controls. The continuous gradient increased (P < 0.05) sperm recovery rate relative to the discontinuous gradient, whereas sperm processed in 15-ml tubes yielded higher velocity and higher recovery rates (P < 0.05 for each) than that processed in 50-ml tubes. Sperm recovery rate was not affected (P > 0.05) by column height of gradient. Increasing sperm number subjected to gradient centrifugation decreased (P < 0.05) sperm recovery rate when 15-ml tubes were used.     

Factors impacting equine sperm recovery rate and quality following cushioned centrifugation

Two experiments were conducted to investigate modifications in cushioned centrifugation of stallion semen. Specifically, the effects of tube type, centrifugation medium, cushion type, and centrifugation force on post-centrifugation sperm recovery rate and quality were evaluated. In Experiment 1, sperm recovery rate was higher (P<0.05) in conventional plastic conical-bottom tubes (103%) than in newly developed glass nipple-bottom tubes (96%) following cushioned centrifugation; however, several measures of semen quality (i.e., % total motility [MOT], % progressive motility [PMOT], curvilinear velocity, and average-path velocity) yielded higher values following centrifugation in nipple-bottom tubes (P<0.05). Sperm recovery rate following cushioned centrifugation was similar between semen previously diluted in optically clear centrifugation extender (100%) and semen diluted in opaque centrifugation extender (100%); however, MOT and PMOT were higher in semen subjected to cushioned centrifugation in opaque extender (P<0.05). An extender by tube-type interaction was not detected for recovery rate or post-centrifugation semen quality. In Experiment 2, sperm recovery rate following cushioned centrifugation in nipple-bottom tubes was similar when forces of 400xg or 600xg were applied (90 and 90%, respectively; P>0.05), and no resulting differences in semen quality were detected between these treatment groups (P>0.05). The type of iodixanol cushion medium used (i.e., OptiPrep, Eqcellsire Component B, or Cushion Fluid did not impact post-centrifugation semen quality, based on the laboratory values measured (P>0.05). In conclusion, cushioned centrifugation of stallion semen in either conical-bottom or nipple-bottom tubes yielded a high sperm harvest, while maintaining sperm function. An optically opaque extender, commonly used in the equine breeding industry, can be used to achieve this goal.     

Semen preservation in Macaca fascicularis.

Semen was collected from adult male Macaca fascicularis using a rectal probe for electro-ejaculation. The effect on sperm motility of varying semen extender egg yolk concentration, pH, glycerol concentration, and equilibration times of sperm with glycerol was examined. No significant difference was observed between motilities at extender egg yolk concentrations of 10% to 40%. Progressive motility was significantly greater at pH 7.2 and 8.0 than at 5.8, 6.5, and 8.7 (p less than 0.05). Glycerol concentrations of 7% and 10% yielded optimum progressive motility after freezing. A 1-minute equilibration of semen in extender containing glycerol resulted in greater sperm motility after freezing than did equilibration for 25 or 45 minutes.     

In vitro survival of bovine spermatozoa stored at room temperature under epididymal conditions

In this study, environmental conditions mimicking those prevailing in the epididymis were used for storing ejaculated bull spermatozoa in vitro during 4 days at ambient temperature. These conditions were low pH, high osmolarity, high sperm concentration and low oxygen tension. Hepes-TALP was used as basic storage medium. Fresh spermatozoa were stored at a concentration of 10 x 10(6)spermatozoa/ml in Hepes-TALP of different pH (pH 4, 5, 6, 7 or 8), and osmolarity (100, 300, 400, 500, 600 or 800 mOsm/kg), and under different atmospheric conditions (nitrogen gassed or aerobic). Spermatozoa were also stored undiluted or at different concentrations: 10x 10(6), 100 x 10(6), 500 x 10(6) or 1 x 10(9)spermatozoa/ml. Sperm parameters such as membrane integrity, motility, mitochondrial membrane potential or DNA fragmentation were used to assess semen quality after storage. Adjustment of the pH of Hepes-TALP to pH 6 yielded significantly better results than storage at all other pH values. Isotonic Hepes-TALP (300 mOsm/kg) had a less detrimental effect on spermatozoa than hypo- and hyperosmotic versions. No differences in sperm parameters were observed when spermatozoa were incubated under aerobic or under nitrogen gassed storage conditions. Optimal sperm concentration in vitro is 10 x 10(6)spermatozoa/ml. This is in contrast with the in vivo situation, where spermatozoa are stored at high concentration. However, better results at high sperm concentrations were obtained when spermatozoa were diluted for less than 5 min in Triladyl-egg yolk-glycerol diluent immediately after ejaculation.     

Spermatozoa recovery and post-thawing quality of brown bear ejaculates is affected for centrifugation regimes

Sperm cryopreservation protocols for brown bear (Ursus arctos) require the centrifugation of semen samples to increase sperm concentration and to clean urine in contaminated samples. We evaluated the effect of centrifugation regimes (time and relative centrifugal force—RCF) on the quantity of sperm recovered and the quality of post-thawed sperm. Thirteen brown bears were electroejaculated. The ejaculates were diluted 1:1 in Tris–citric acid–glucose (TCG) extender and centrifuged with different RCF/time combinations: 600×g, 1,200×g and 2,400×g, for 3, 6 or 12 min. After centrifugation, spermatozoa were diluted in TES–Tris–fructose extender with egg yolk and glycerol (final glycerol concentration of 8%) and frozen in 0.25-mL straws. In the post-thawed semen, motility was assessed by CASA, and acrosomal status (PNA-FITC), viability (SYBR-14 with propidium iodide) and chromatin status (SCSA) were determined by flow cytometry. The longest centrifugation time (12 min) significantly decreased some motility parameters. Sperm recovery significantly decreased in brown bear at 600×g. Our results suggest that brown bear spermatozoa are more sensitive to long centrifugation times than to high RCF. Centrifugation regimes showed no effects on the post-thawing chromatin status. We recommend preparing the brown bear semen for freezing by centrifugation 1,200×g or 2,400×g for 6 min, after electroejaculation and dilution 1:1 in TCG extender, since these procedures increase the spermatozoa recovery without harmful effects on the post-thawed quality of brown bear spermatozoa.     

Reversal of motility loss in bongo antelope (Tragelaphus eurycerus isaaci) spermatozoa contaminated with hyposmotic urine during electroejaculation

Semen collected by a combination of ampullary (rectal) massage and electroejaculation of a bongo bull was incidentally contaminated with urine (1:3.7). At 1.5h post-collection, progressive motility was 0% but some spermatozoa had intermittently twitching tails. Subsequent dilution with media and processing improved the progressive motility (up to 50%) and intact membranes (up to 71%) of spermatozoa. After thawing, the respective values were 35 and 70%. The osmolarity and pH of the contaminated supernatant was 151 mOsm and 7.45, respectively. Initial progressive motility in a non-contaminated portion of semen collected during the same procedure was 80%, and, after thawing, 60 and 90%, of the spermatozoa showed progressive motility and intact membranes, respectively. In conclusion, urine-contaminated bongo spermatozoa can regain progressive motility after dilution with isosmotic solutions and survive cryopreservation.     

Effects of centrifugation, glycerol level, cooling to 5 degrees C, freezing rate and thawing rate on the post-thaw motility of equine sperm

Five experiments evaluated the effects of processing, freezing and thawing techniques on post-thaw motility of equine sperm. Post-thaw motility was similar for sperm frozen using two cooling rates. Inclusion of 4% glycerol extender was superior to 2 or 6%. Thawing in 75 degrees C water for 7 sec was superior to thawing in 37 degrees C water for 30 sec. The best procedure for concentrating sperm, based on sperm motility, was diluting semen to 50 x 10(6) sperm/ml with a citrate-based centrifugation medium at 20 degrees C and centrifuging at 400 x g for 15 min. There was no difference in sperm motility between semen cooled slowly in extender with or without glycerol to 5 degrees C prior to freezing to -120 degrees C and semen cooled continuously from 20 degrees C to -120 degrees C. From these experiments, a new procedure for processing, freezing and thawing semen evolved. The new procedure involved dilution of semen to 50 x 10(6) sperm/ml in centrifugation medium and centrifugation at 400 x g for 15 min, resuspension of sperm in lactose-EDTA-egg yolk extender containing 4% glycerol, packaging in 0.5-ml polyvinyl chloride straws, freezing at 10 degrees C/min from 20 degrees C to -15 degrees C and 25 degrees C/min from -15 degrees C to -120 degrees C, storage at -196 degrees C, and thawing at 75 degrees C for 7 sec. Post-thaw motility of sperm averaged 34% for the new method as compared to 22% for the old method (P<0.01).     

Quantification of damage at different stages of cryopreservation of endangered North American bison (Bison bison) semen and the effects of extender and freeze rate on post-thaw sperm quality

Semen cryopreservation is an important technique for the banking of animal germplasm from endangered species and exploitation of genetically superior sires through artificial insemination. Being a member of bovidae family, bison semen has poor freezing ability as compared to dairy and beef bulls' semen. This study was designed to quantify the damage to bison sperm at different stages of cryopreservation, and to determine the effects of extender (commercial Triladyl(?) vs. custom made tris-citric acid [TCA]) and freeze rate (-10, -25 and -40°C/min) on post-thaw quality of bison semen. Semen was collected from five bison bulls (three woods and two plains) via electroejaculation. In Experiment 1, semen was diluted in Triladyl? extender and frozen with freeze rate -10°C/min. Sperm motility characteristics were recorded in fresh, diluted, cooled (4°C) and freeze-thawed semen using computer-assisted sperm analyzer (CASA). In Experiment 2, semen was diluted in Triladyl? or TCA extender, and frozen with three different freeze rates, i.e. -10, -25 or -40°C/min. Thawing was performed at 37°C for 60s. Post-thaw sperm motility characteristics were assessed using CASA, and sperm structural characteristics (plasma membrane, mitochondrial membrane potential and acrosomes) were evaluated using flow cytometer, at 0 and 3h while incubating semen at 37°C. In Experiment 1, total and progressive motilities did not differ among pre-freeze stages of cryopreservation (P>0.05). However, sperm total and progressive motilities declined (P<0.001) in freeze-thawed semen by 35% and 42%, respectively, compared to after cooling (pre-freeze) semen. In Experiment 2, Triladyl?, as compared to TCA, yielded greater (P<0.05) post-thaw sperm total motility (41% compared to 36%) and progressive motility (34% compared to 29%) at 0h, respectively. The percent change in post-thaw sperm total and progressive motilities, VAP, VCL, VSL, IPM-high ΔΨm and IPM-IACR during 3h incubation at 37°C, was less (P<0.05) in TCA than in Triladyl?. There was an effect of freeze rate on post-thaw sperm average path velocity at 0h, and total motility, progressive motility, VCL, IPM and IPM-IACR at 3h were the greatest (P<0.05) when bison semen was frozen at -40°C/min. Likewise, the percent change in post-thaw sperm total and progressive motilities, during 3h incubation at 37°C, was less (P<0.05) in bison semen frozen at -40°C/min. All post-thaw bison sperm characteristics decreased (P<0.05) from 0h to 3h, during incubation at 37°C. In conclusion, the maximum damage to bison sperm occurred during freeze-thaw processes. Post-thaw total and progressive motilities of bison sperm were greater in Triladyl? at 0h whereas sperm survival was greater in TCA extender during 3h post-thaw incubation. Bison sperm had greater survival (P<0.05) when frozen at -40°C/min freeze rate.     

Effects of dietary L-carnitine supplementation on semen characteristics in boars

In some species, dietary supplementation with L-carnitine has been reported to increase sperm concentration and sperm motility. The objective of these experiments was to test the hypothesis that L-carnitine supplementation improves the semen characteristics of boars. In Experiment 1, boars (258 days of age) were fed daily a control diet (n = 9) or the control diet plus L-carnitine (500mg per day; n = 9 ). Semen was collected weekly from Weeks 0 to 15 and on 4 consecutive days during Week 16. Experiment 2 was similar to Experiment 1 except boars ( n = 10 per treatment) were 504 days of age. For the weekly and intensive collections there were no consistently positive effects of treatment on semen volume, sperm concentration, total spermatozoa, or sperm motility. Spermatozoa from L-carnitine-treated boars did not display an enhanced ability to maintain motility during 7-day liquid storage. In conclusion, indicators of semen quality were not enhanced by dietary supplementation of L-carnitine in boars.     

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 motility of human spermatozoa as influenced by prostasomes at various pH levels.

Human semen contains several components among which spermatozoa, membranous vesicles called 'prostasomes', secreted by the prostate gland and unorganized material. Prostasomes possess an unusual lipid composition, contain a number of proteins and small molecules and have been claimed to take a part in the immune response, in seminal fluid liquefaction and in sperm motility. Since sperm may come in contact with an acidic environment in the vagina, it may be of some interest to know whether prostasomes may affect spermatozoon motility or may protect spermatozoa upon the exposure to an acidic milieu. Human semen was supplied by donors. From whole semen we collected spermatozoa by centrifugation and used the supernatant to prepare prostasomes (centrifugation at 105,000 g for 120 min, followed by purification step on Sephadex G 200); spermatozoa were then collected by a swim-up procedure and exposed to an acidic pH medium (from 5 to 7) in the presence or absence of prostasomes. Spermatozoa motility was subsequently assessed with a superimposed image analysis system (SIAS). Results indicate that the motility of spermatozoa was affected by the pH value of the medium. Acidic media reduced the percentage of motile cells and decreased the straight line velocity of spermatozoa (VLS). Prostasomes had a protective effect and increased the percentage of motile cells. However, they did not change the characteristics of motility (curvilinear and straight). Prostasomes may be considered as a system for counteracting the negative effects of acidic pH values that may be present in the vagina after coitus.     

Role of sperm motility and acrosome integrity in the filtration of bovine semen

In this study, the role of sperm motility and acrosome integrity in filtration of bovine semen was investigated. In Experiment 1, the treatment of semen with formaldehyde, hyperosmotic buffer, heating and direct freezing immobilized the spermatozoa completely but their acrosomal status varied significantly (P < 0.01). The immotile spermatozoa, of any kind, did not pass through the Sephadex ion-exchange column at room temperature. In Experiment 2, semen samples possessing different percentages of immobilized spermatozoa (0, 50, 75 and 100%) were filtered through the Sephadex ion-exchange column. The immotile/dead spermatozoa were removed proportionately to their number in the semen by Sephadex ion-exchange column. The type and number of immotile spermatozoa in semen had no effect (P > 0.05) on the post-filtration recovery rate of motile spermatozoa. Filtered spermatozoa exhibited higher (P < 0.01) motility (> 90%), progressive motility (> 70%) and normal acrosomes (> 95%) than non-filtered spermatozoa. In conclusion, sperm motility seems to be more important than acrosome integrity for semen filtration, and the Sephadex ion-exchange column can remove the known quantities of different kinds dead/immotile spermatozoa.     

The impact of cushioned centrifugation protocols on semen quality of stallions

The objective was to determine if decreased cushion-fluid volume and increased sperm number during centrifugation, or if sperm concentration of extended semen following centrifugation, affected stallion sperm quality. Three ejaculates from each of three stallions were subjected to cushioned centrifugation (1,000g for 20 min). Cushion-fluid volume was set at 1 or 3.5 ml, and sperm number per centrifuge tube was set 1 billion or 3 billion. Following centrifugation, sperm pellets were resuspended in semen extender containing 20% seminal plasma (v/v) with sperm concentrations of 25 or 250 million/mL. Sperm recovery rate among centrifugation treatment groups was compared. Motion characteristics, plasma membrane intactness (SMI), and DNA quality (COMPαt) of sperm were compared among treatment groups and uncentrifuged controls immediately following centrifugation (Time 0 h) and following 24 h of cooled storage (Time 24 h). Centrifugation treatment did not affect sperm recovery rate (P > 0.05). At Time 0 h, no differences in experimental end points were detected between cushion-fluid volumes tested (P > 0.05). Values for percent total sperm motility, percent progressive sperm motility, and track straightness were similar between sperm-number treatments subjected to centrifugation (P > 0.05). At Time 24 h, values for all experimental endpoints were similar between centrifugation treatments for cushion volume per tube, and between centrifugation treatments for sperm number per tube (P > 0.05). Centrifugation treatments and control treatments were similar for five of six variables tested (P > 0.05). Sperm storage concentrations of 25 × 10⁶ and 250 × 10⁶/mL yielded similar values for percent total sperm motility, percent progressive sperm motility, percent SMI, and percent COMPαt (P > 0.05). A storage concentration of 250 × 10⁶ sperm/ml yielded higher values for curvilinear velocity, and lower values for straightness, than all other groups (P < 0.05). In conclusion, centrifugation with as little as 1 ml of cushion fluid and a sperm number of up to 3 × 10⁹ sperm in 50-ml conical-bottom centrifuge tubes had no detrimental effect on initial or cool-stored sperm quality. Additionally, storage of centrifuged sperm at a concentration of 250 × 10⁶/mL with 20% seminal plasma (v/v) did not have a detrimental effect on percentages of motile or progressively motile sperm, or sperm DNA quality.     

Implications of the pH and temperature of diluted, cooled boar semen on fresh and frozen-thawed sperm motility characteristics

Boar semen is typically collected, diluted and cooled for AI use over numerous days, or frozen immediately after shipping to capable laboratories. The storage temperature and pH of the diluted, cooled boar semen could influence the fertility of boar sperm. Therefore, the purpose of this study was to determine the effects of pH and storage temperature on fresh and frozen-thawed boar sperm motility end points. Semen samples (n = 199) were collected, diluted, cooled and shipped overnight to the National Animal Germplasm Program laboratory for freezing and analysis from four boar stud facilities. The temperature, pH and motility characteristics, determined using computer automated semen analysis, were measured at arrival. Samples were then cryopreserved and post-thaw motility determined. The commercial stud was a significant source of variation for mean semen temperature and pH, as well as total and progressive motility, and numerous other sperm motility characteristics. Based on multiple regression analysis, pH was not a significant source of variation for fresh or frozen-thawed boar sperm motility end points. However, significant models were derived which demonstrated that storage temperature, boar, and the commercial stud influenced sperm motility end points and the potential success for surviving cryopreservation. We inferred that maintaining cooled boar semen at approximately 16 °C during storage will result in higher fresh and frozen-thawed boar sperm quality, which should result in greater fertility.     

Response of spermatozoa from the emu (Dromaius novaehollandiae) to rapid cooling, hyperosmotic conditions and dimethylacetamide (DMA)

Three experiments conducted to improve the survival of emu sperm during cryopreservation aimed to: (1) minimize chilling injury during the cooling phase; (2) determine the osmotic effects of dimethylacetamide (DMA), sucrose and trehalose; and (3) investigate the timing and nature of cryoprotectant toxicity. We measured sperm membrane integrity, motility, morphology and egg membrane penetration. In Experiment 1, semen diluted 1:1 with a pre-cooled diluent (5°C) prevented chilling injury. In Experiment 2, semen was diluted with DMA, trehalose or sucrose (300-2400mOsm/L) in deionized water. Only added DMA decreased the percentage of morphologically normal sperm. The percentage of motile sperm was higher with DMA than with the sugars, but membrane intact sperm were comparable amongst all cryoprotectants. As for the osmotic effects, the percentage of membrane intact sperm decreased with 2400mOsm/L and sperm motility decreased with 1200-2400mOsm/L, but sperm morphology was similar at all osmolarities. In Experiment 3, sperm membrane integrity, motility and morphology were comparable at all DMA osmolarities between sperm equilibrated for 0 and 15min, and remained unchanged after removal of DMA. We conclude that: (a) loss of sperm function during the cooling phase can be avoided by using a diluent maintained at 5°C; (b) emu spermatozoa tolerate upto 1400mOsm/L; (c) DMA results in a permanent change in sperm morphology when it is dissolved in deionized water, but does not alter sperm membrane integrity and motility; and (d) equilibration time of sperm with DMA can be less than 10min.     

Development of a chemically defined ram semen diluent (RSD-1)

A chemically defined ram semen diluent (RSD-1) has been developed. RSD-1 maintained spermatozoal motility of diluted semen containing approximately 800 million spermatozoa ml⁻¹ during cooling to 15°C and its storage for 1 h. Motility was further maintained when the cooled semen was diluted to 100 million spermatozoa ml⁻¹ and incubated at 38°C for about 24 h. In contrast, a conventional milk-based diluent supported motility for less than 6 h at 38°C. Spermatozoal motility was influenced by the buffering capacity, osmolarity and the presence or absence of macromolecules and calcium in the chemically defined diluent. Among the organic buffers tested, MOPS (3-(N-morpholino)propanesulphonic acid) had a marked influence on the maintenance of spermatozoal motility. The presence of MOPS also overcame the detrimental effects of 2 mM calcium in Krebs Ringer improved (KR-I) buffer.     

Factors affecting sperm recovery rates and survival after centrifugation of equine semen

Conventional centrifugation protocols result in important sperm losses during removal of the supernatant. In this study, the effect of centrifugation force (400 or 900 × g), duration (5 or 10 min), and column height (20 or 40 mL; Experiment 1); sperm concentration (25, 50, and 100 × 10⁶/mL; Experiment 2), and centrifugation medium (EZ-Mixin CST [Animal Reproduction Systems, Chino, CA, USA], INRA96 [IMV Technologies, Maple Grove, MN, USA], or VMDZ [Partnar Animal Health, Port Huron, MI, USA]; Experiment 3) on sperm recovery and survival after centrifugation and cooling and storage were evaluated. Overall, sperm survival was not affected by the combination of centrifugation protocol and cooling. Total sperm yield was highest after centrifugation for 10 min at 400 × g in 20-mL columns (95.6 ± 5%, mean ± SD) or 900 × g in 20-mL (99.2 ± 0.8%) or 40-mL (91.4 ± 4.5%) columns, and at 900 × g for 5 min in 20-mL columns (93.8 ± 8.9%; P < 0.0001). Total (TMY) and progressively motile sperm yield followed a similar pattern (P < 0.0001). Sperm yields were not significantly different among samples centrifuged at various sperm concentrations. However, centrifugation at 100 × 10⁶/mL resulted in significantly lower total sperm yield (83.8 ± 10.7%) and TMY (81.7 ± 6.8%) compared with noncentrifuged semen. Centrifugation in VMDZ resulted in significantly lower TMY (69.3 ± 22.6%), progressively motile sperm yield (63.5 ± 18.2%), viable yield (60.9 ± 36.5%), and survival of progressively motile sperm after cooling (21 ± 10.8%) compared with noncentrifuged semen. In conclusion, centrifuging volumes of ≤ 20 mL minimized sperm losses with conventional protocols. With 40-mL columns, it may be recommended to increase the centrifugal force to 900 × g for 10 min and dilute the semen to a sperm concentration of 25 to 50 × 10⁶/mL in a milk- or fractionated milk-based medium. The semen extender VMDZ did not seem well suited for centrifugation of equine semen.     

Biophysical and biochemical characteristics of bactrian camel semen collected by artificial vagina

Seminal characteristics were investigated in Bactrian camel in this study. Semen samples from ten mature Bactrian camel bulls were collected using a modified bovine artificial vagina. The biophysical parameters including volume, color, sperm concentration and fast forward progressive motility, percentage of live sperm and the biochemical parameters including osmolarity, pH, glucose, calcium, phosphorus, chloride, triglycerides, phospholipids, total protein, albumin and non-protein nitrogen concentrations in seminal plasma were measured. The mean time for semen collection was 5.3 +/- 0.29 min. The volume of semen varies from 1.2 to 26 (8.2 +/- 0.7 mls). The majority of semen samples (83.6%) were milky in color and consistency. The average osmolarity of semen was 316.1 +/- 1.48 mOsm/kg H(2)O. The pH of semen was slightly alkaline (7.4 +/- 0.03). The mean concentration of spermatozoa was 414.8 +/- 25.04 x 10(6)cells/ml. The fast forward progressive motility of spermatozoa was 62.4 +/- 1.57%. The percentage of live spermatozoa was 85.6 +/- 1.15. Seminal plasma concentration of glucose was 35.8 +/- 0.9 mg/dl. Non-protein nitrogen, total protein and albumin were 32.5 +/- 2.5, 2200 +/- 100 and 1100 +/- 100mg/dl, respectively. The average concentrations of phospholipids and triglycerides in seminal plasma were 36.4 +/- 2.1 and 101.6 +/- 5.5mg/dl, respectively. The concentrations of calcium, phosphorus and chloride were 8.2 +/- 0.1, 2.9 +/- 1.7 mg/dl and 97.9 +/- 2.9 mEq./l, respectively.     

Evaluation of a cushioned method for centrifugation and processing for freezing boar semen

The purpose of this investigation was to evaluate the use of an iodixanol cushion during centrifugation on sperm recovery and yield after centrifugation (sperm recovery, sperm motility, viability, membrane lipid disorder, acrosome reaction and ROS generation); and to investigate how this procedure affects sperm function after freezing-thawing (sperm motility, membrane lipid disorder, acrosomal status and homologous in vitro penetration test). The sperm-rich fractions from fertile boars were centrifuged under two centrifugation régimes: 800xg for 10min (standard method) and 1000xg for 20min with an iodixanol (60% w/v) cushion at the bottom of the centrifuge tubes (Cushion method). The highest recovery was achieved using the cushion method (sperm loss for cushion method was 0.50%+/-0.18 versus 2.97%+/-0.43 for standard method, P<0.01) and sperm quality was not significantly affected by the centrifugation régime. The motion parameters (% progressive motility, % motility, VCL, VSL, VAP, ALH, BCF, P<0.05) of frozen-thawed samples showed higher values using the standard method. However, a higher number of viable spermatozoa with lower lipid disorders were found in spermatozoa processed with the cushion method. The in vitro penetration assay showed that the individual boar influenced the parameters studied but there were no differences between the two centrifugation régimes used. Our results support the hypothesis that the proportion of sperm loss in frozen-thawed semen was significantly influenced by the centrifugation régime. Therefore, the iodixanol cushion method is a suitable tool for cryopreservation of boar semen in order to reduce sperm loss without affecting sperm quality.     

Dialysis of bovine semen and its effect on fresh and freeze-thawed spermatozoa

The effect of the removal of the low-molecular-weight fraction (LMWF, less than 12,000-14,000 Da) from the seminal plasma present in extended semen by dialysis and by centrifugation (1,376g for 20 min at 5 degrees C) were compared with the current methods of freezing bovine semen. Significantly higher sperm post-thaw motility (P less than 0.05) was obtained in the dialyzed samples than with the other two methods. The appropriate time and temperature for dialysis of semen was also studied. Semen aliquots were dialyzed (1:50, retentate:dialysate) for 30 min, 1 or 2 hr at 5 degrees C, and during the cooling process from 37 to 5 degrees C over a 2-hr period. Superior sperm motility (P less than 0.05) in prefreeze and post-thawed samples was observed when semen was dialyzed for 1 or 2 hr during the cooling process as compared with that of semen dialyzed at 5 degrees C. A third experiment was conducted to establish the effect of the use of dialysis bags of different molecular weight cutoffs (MWCO) on sperm motility. Semen samples were dialyzed (1:50) during the cooling process in dialysis bags of 1,000, 3,500, 6,000-8,000, 12,000-14,000, 25,000, and 50,000 MWCO. No statistical differences (P greater than 0.05) in sperm post-thaw motility were found after evaluation of the number of cells that passed through the Sephadex filter and all the dialyzed values obtained were significantly (P less than 0.05) superior to the results obtained with no dialysis.(ABSTRACT TRUNCATED AT 250 WORDS)