Littérature scientifique sur le sujet « PURESPERM »

Density gradient centrifugation with PureSperm® (PureSperm® 40 + PureSperm® 80; Nidacon International, Mölndal, Sweden) has been satisfactorily used to enhance the quality of dog semen samples; however, no studies have been performed on the effect of single layer centrifugation (SLC) with PureSperm® on frozen–thawed dog semen. The aim of this study was to investigate if SLC with PureSperm® 80 can improve the post-thaw semen quality of dog. Semen from 5 dogs was collected by digital manipulation. Two ejaculates from each dog were centrifuged with Tris-based extender, supernatant was removed, and sperm pellet was suspended to a final concentration of 300–400 × 106 sperm mL–1 with CaniPROTM Freeze A plus 20% egg yolk at 22°C. Extended semen was cooled to 5°C within an hour and then diluted to a final concentration of 150–200 × 106 sperm mL–1 in CaniPROTM Freeze B plus 20% egg yolk at 5°C, loaded in 0.5-mL plastic straws and frozen horizontally in ranks placed 4 cm above the surface of liquid nitrogen vapors for 10 min, after which they were directly placed in liquid nitrogen. After 24 to 48 h of storage, straws were thawed in a water bath at 37°C for 30 s. After thawing, semen samples were divided in 2 aliquots: one of them was used as control and the other one was processed by SLC PureSperm® 80. Assessment of sperm motility (assessed by computerized-assisted semen analysis), morphology (Diff-Quick staining), and viability [triple fluorescent stain of propidium iodine/isothiocyanate-labeled peanut (Arachis hypogaea) agglutinin/Rhodamine 123] were evaluated in control and treated semen samples. Data were studied by ANOVA. Results are expressed as mean ± SEM. Significant (P < 0.001) differences were found between SLC-treated and control semen for sperm motility (percentage of total motile spermatozoa: 93.65 ± 0.05 v. 83.79 ± 0.13; percentage of progressive motile spermatozoa: 79.38 ± 6.66 v. 54.61 ± 16.11), morphology (86.45 ± 0.01 v. 83.51 ± 0.01), and viability (percentage of viable sperm with an intact acrosome: 58.32 ± 0.04 v. 36.50 ± 0.17; percentage of viable sperm with an acrosome reaction: 2.81 ± 0.01 v. 9.74 ± 0.21). Based on our results, we can conclude that SLC with PureSperm® 80 is an alternative and successful method for improving the quality of frozen–thawed dog spermatozoa, selecting good-quality spermatozoa (motile, morphologically normal, viable, and acrosome intact spermatozoa) from the rest of the semen sample.

Density gradient centrifugation with PureSperm® (PureSperm® 40+PureSperm® 80; Nidacon International, Mölndal, Sweden) has been satisfactorily used to enhance the quality of dog semen samples; however, no studies have been performed on the effect of single layer centrifugation (SLC) with PureSperm® on frozen–thawed dog semen. The aim of this study was to investigate if SLC with PureSperm® 80 can improve the post-thaw semen quality of dog. Semen from 5 dogs was collected by digital manipulation. Two ejaculates from each dog were centrifuged with Tris-based extender, supernatant was removed, and sperm pellet was suspended to a final concentration of 300–400×106spermmL–1 with CaniPROTM Freeze A plus 20% egg yolk at 22°C. Extended semen was cooled to 5°C within an hour and then diluted to a final concentration of 150–200×106spermmL–1 in CaniPROTM Freeze B plus 20% egg yolk at 5°C, loaded in 0.5-mL plastic straws and frozen horizontally in ranks placed 4cm above the surface of liquid nitrogen vapors for 10min, after which they were directly placed in liquid nitrogen. After 24 to 48h of storage, straws were thawed in a water bath at 37°C for 30s. After thawing, semen samples were divided in 2 aliquots: one of them was used as control and the other one was processed by SLC PureSperm® 80. Assessment of sperm motility (assessed by computerized-assisted semen analysis), morphology (Diff-Quick staining), and viability [triple fluorescent stain of propidium iodine/isothiocyanate-labeled peanut (Arachis hypogaea) agglutinin/Rhodamine 123] were evaluated in control and treated semen samples. Data were studied by ANOVA. Results are expressed as mean ± SEM. Significant (P&lt;0.001) differences were found between SLC-treated and control semen for sperm motility (percentage of total motile spermatozoa: 93.65±0.05 v. 83.79±0.13; percentage of progressive motile spermatozoa: 79.38±6.66 v. 54.61±16.11), morphology (86.45±0.01 v. 83.51±0.01), and viability (percentage of viable sperm with an intact acrosome: 58.32±0.04 v. 36.50±0.17; percentage of viable sperm with an acrosome reaction: 2.81±0.01 v. 9.74±0.21). Based on our results, we can conclude that SLC with PureSperm® 80 is an alternative and successful method for improving the quality of frozen–thawed dog spermatozoa, selecting good-quality spermatozoa (motile, morphologically normal, viable, and acrosome intact spermatozoa) from the rest of the semen sample.

The goal of this research was to investigate the effect of a novel density gradient centrifugation (DGC) treatment on the fertilizing capability of bovine sperm as compared to a standard method. Domestic bull (Bos taurus) semen was used for AI and the production of embryos from in vivo-matured bovine oocytes. In 2004, a preliminary study compared the novel semen treatment using a trypsinized PVP-coated silica particle suspension (Percoll; Sigma, St. Louis, MO, USA) to a standard method (4� dilution with an egg yolk diluent) on the fertilizing capacity in vivo of bovine sperm (de la Rey et al. 2005 J. Reprod. Fertil. 17, 242 abst). Although not statistically significant (P = 0.69), there were more transferable quality embryos recovered from cows inseminated using the treated sperm method v. control (58.9 v. 43%, respectively). In this report we provide the results of two additional trials utilizing the novel semen treatment and substituting Percoll with a silane-coated silica particle medium containing a recombinant trypsin (r-protease). In the second trial (2005), semen samples collected from three bulls were processed by DGC: 2 mL of 40% PureSperm (NidaCon International AB, M�lndal, Sweden) containing recombinant trypsin (TrypLE Select, Gibco/Invitrogen, Carlsbad, CA, USA), which overlaid 2 mL of 80% PureSperm containing 10 µg mL–1 soy-based protease inhibitor (Sigma), was overlaid with the semen sample using a novel centrifuge tube insert (ProInsert, Nidacon) and then centrifuged at 300g for 20 min. The sperm pellets were recovered and washed (500g for 10 min) in 10 mL pre-warmed TL-HEPES medium (Cambrex Corp., East Rutherford, NJ, USA). The washed sperm pellets were then resuspended in the same total volume of pre-warmed Biladyl� A (Minit�b, Tiefenbach, Germany) as the standard method and used to AI a total of 42 (control) and 47 (treatment) superovulated cows three times at 12 h intervals. Day 7 embryos were recovered and assessed for stage and morphological quality. In Trial 3 (2006), semen samples collected from three bulls were processed by DGC containing r-protease and a soybean protease inhibitor (BoviPure Pro, NidaCon), media specifically formulated for domestic bull semen. Sperm pellets were washed in 10 mL BoviWash medium (NidaCon). The washed sperm pellet was resuspended in the same total volume of pre-warmed Biladyl A as the standard method and used to AI a total of 23 (control) and 25 (treatment) superovulated cows and embryos evaluated as in Trial 2. The results between control and treated groups were compared using the Mann-Whitney (Wixcoxon rank sum) test. Trial 2 using PureSperm tended to result in higher fertilization rates than for cows inseminated using the standard method (75.2% v. 67%, respectively) but the results were not statistically significant (P = 0.63). Results for Trial 3 indicated that cows inseminated with BoviPure Pro-treated sperm had significantly increased fertilization rates as compared to the standard method (88.4% v. 63.1%, respectively; P = 0.02) and had higher numbers of transferable quality embryos (70.3% v. 51.8%, respectively; P = 0.38). In summary, BoviPure Pro sperm treatment before AI significantly increases fertilization rates and can result in as much as an 18.5% increase in transferable quality embryos as compared to standard methods.

Boars can be classified as good or bad sperm freezers according to their sperm cryosurvival. Different sperm selection techniques, such as PureSperm� (PS; MidAtlantic Diagnostics, Inc., Mount Laurel, NJ, USA), have been developed to improve functional competence of spermatozoa. The aim of this experimental study was to assess the ability of PS for improving the in vitro penetrating ability of frozen–thawed boar spermatozoa from good and bad sperm freezers. The sperm-rich fractions from two boars, good (Boar A) and bad (Boar B) freezers, were extended in a lactose/eggyolk/ glycerol/Equex Stem (Noba Chemical Sales, Inc., Scituate, ME, USA) mixture (1 � 109 sperm mL–1), dispensed into 0.5-mL straws, and frozen using a programmable cell freezer. After thawing (1.200�C min–1), semen from each boar was split into two aliquots of 500 µL. One aliquot was used as the control. The second was placed into a tube of PS gradient (90%/45%) and centrifuged at 425g for 20 min; the pellet re-suspended in 1 mL of BTS and re-centrifuged at 320g for 10 min (PS sample). Control and PS samples were diluted in supplemented TCM-199 (TCMm; Roca et al. 1998 Reprod. Fertil. Dev. 10, 479–485) at 200 � 106 sperm mL–1. Sperm survival (SV) was assessed afterTCMm dilution according to progressive sperm motility (PSM, %) using a computer-assisted sperm analysis (CASA) system (ISAS�), and plasma and acrosome membrane integrity (PMI; %) by flow cytometry (SYBR�-14/PE-PNA/PI; Molecular Probes, Leiden, The Netherlands). A homologous in vitro penetration (hIVP) assay, using immature oocytes (20 oocytes/2 mL TCMm supplemented with caffeine and calcium lactate), was used to assess sperm penetrating ability (Martinez et al. 1993 Theriogenology 40, 547–557). A total of 960 immature oocytes were inseminated (200 � 103 sperm/oocyte) in 3 batches. After 18 h of co-incubation at 39�C under 5% CO2 in air, the oocytes were washed, mounted on slides, fixed with ethanol:acetic acid (3:1, v/v) for 48 h, stained with 1% lacmoid, and examined under a phase contrast microscope (�400). Oocytes with swollen or unswollen heads of sperm found in the vitellus were considered as penetrated. Sperm penetrability ability (SPA) was assessed according to penetration rate (PR) and the mean number of sperm per oocyte (S/O). Data were analyzed using a PROMIXED model and expressed as mean � SEM. Boar A showed better (P ≤ 0.01) results for both SV and SPA parameters than boar B, independent of sperm treatment. PureSperm improved (P ≤ 0.05) PSM and PMI in both boar A (control v. PS: 48.0 � 5.8 v. 66.5 � 3.6 and 63.1 � 7.7 v. 88.4 � 1.3, respectively) and boar B (12.3 � 1.2 v. 22.2 � 3.7 and 44.3 � 3.5 v. 58.7 � 7.0, respectively). However, no differences (P ≥ 0.05) were observed in PR and S/O in either boar A (71.2 � 3.4 v. 78.3 � 3.1 and 5.0 � 0.4 v. 5.2 � 0.4, respectively) or boar B (34.3 � 3.6 v. 37.3 � 3.9 and 1.5 � 0.1 v. 1.5 � 0.1, respectively). In conclusion, under our laboratory conditions, PureSperm selection improves sperm quality but not in vitro penetrating ability of frozen–thawed spermatozoa of both good and bad sperm freezers. This work was supported by CICYT (AGF2005-00760), Madrid, Spain.