Changes in the structures of motile sperm subpopulations in dog spermatozoa after both cryopreservation and centrifugation on PureSperm(®) gradient

The aims of the present study were to: (1) determine if discrete motile sperm subpopulations exist and their incidence in fresh dog ejaculates, (2) evaluate the effects of cryopreservation on the distribution of spermatozoa within the different subpopulations, and (3) determine the effect of the discontinuous PureSperm(?) gradient on the sperm subpopulation structure of frozen-thawed dog spermatozoa. Semen from 5 dogs were collected and cryopreserved following a standard protocol. After thawing, semen samples were selected by centrifugation on PureSperm(?). Sperm motility (assessed by computerized-assisted semen analysis, CASA) was assessed before freezing, just after thawing and after preparation on the PureSperm(?) gradients. Cryopreservation had a significant (P<0.001) effect on CASA-derived parameters. PureSperm(?) centrifugation yielded sperm suspensions with improved motility (P<0.01). A multivariate clustering procedure separated 19414 motile spermatozoa into four subpopulations: Subpopulation 1 consisting of poorly active and non-progressive spermatozoa (20.97%), Subpopulation 2 consisting of slow and low-linear spermatozoa (18.24%), Subpopulation 3 consisting of highly active but non-progressive spermatozoa (20.75%), and Subpopulation 4 consisting of high speed and progressive spermatozoa (40.03%). Although, cryopreservation had a significant (P<0.001) effect on both the frequency distribution of spermatozoa within subpopulations and the motion characteristics of each subpopulation, the sperm subpopulation structure was perfectly maintained after freezing and thawing. The selected sperm samples was enrich in Subpopulation 4, reaching a proportion of 31.9% of the present spermatozoa, in contrast with the unselected sperm samples, where this sperm subpopulation accounted for 24.9% of the total. From these results, we concluded that four well-defined motile sperm subpopulations were present either in fresh semen, in unselected sperm samples or in selected preparations from dogs. The discontinuous PureSperm(?) gradient is a simple method to improve the quality of canine frozen-thawed semen samples, since Subpopulation 4 (high-speed and progressive spermatozoa) was more frequently observed after preparation on the gradient. Finally, this study also demonstrated that the general motile sperm structure present in dog remains constant despite the effect caused by either cryopreservation or separation on PureSperm(?) gradient.     

Brown bear sperm double freezing: Effect of elapsed time and use of PureSperm® gradient between freeze–thaw cycles

The use of sexed spermatozoa has great potential to captive population management in endangered wildlife. The problem is that the sex-sorting facility is a long distance from the semen collection place and to overcome this difficulty two freeze–thaw cycles may be necessary. In this study, effects of refreezing on brown bear electroejaculated spermatozoa were analyzed. We carried out two experiments: (1) to assess the effects of the two freezing–thawing cycles on sperm quality and to analyze three different elapsed times between freezing–thawing cycles (30, 90 and 180 min), and (2) to analyze the use of PureSperm between freezing–thawing cycles to select a more motile and viable sperm subpopulation which better survived first freezing. The motility, viability and undamaged acrosomes were significantly reduced after the second thawing respect to first thawing into each elapsed time group, but the elapsed times did not significantly affect the viability and acrosome status although motility was damaged. Our results with the PureSperm gradient showed higher values of viability in freezability of select sample (pellet) respect to the rest of the groups and it also showed a significant decrease in the number of acrosome damaged. In summary, the double freezing of bear semen selected by gradient centrifugation is qualitatively efficient, and thus could be useful to carry out a sex-sorting of frozen–thawed bear spermatozoa before to send the cryopreserved sample to a biobank. Given the low recovery of spermatozoa after applying a selection gradient, further studies will be needed to increase the recovery rate without damaging of the cell quality.     

Brown bear sperm double freezing: Effect of elapsed time and use of PureSperm® gradient between freeze–thaw cycles

The use of sexed spermatozoa has great potential to captive population management in endangered wildlife. The problem is that the sex-sorting facility is a long distance from the semen collection place and to overcome this difficulty two freeze–thaw cycles may be necessary. In this study, effects of refreezing on brown bear electroejaculated spermatozoa were analyzed. We carried out two experiments: (1) to assess the effects of the two freezing–thawing cycles on sperm quality and to analyze three different elapsed times between freezing–thawing cycles (30, 90 and 180 min), and (2) to analyze the use of PureSperm between freezing–thawing cycles to select a more motile and viable sperm subpopulation which better survived first freezing. The motility, viability and undamaged acrosomes were significantly reduced after the second thawing respect to first thawing into each elapsed time group, but the elapsed times did not significantly affect the viability and acrosome status although motility was damaged. Our results with the PureSperm gradient showed higher values of viability in freezability of select sample (pellet) respect to the rest of the groups and it also showed a significant decrease in the number of acrosome damaged. In summary, the double freezing of bear semen selected by gradient centrifugation is qualitatively efficient, and thus could be useful to carry out a sex-sorting of frozen–thawed bear spermatozoa before to send the cryopreserved sample to a biobank. Given the low recovery of spermatozoa after applying a selection gradient, further studies will be needed to increase the recovery rate without damaging of the cell quality.     

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.     

Loss of plasma membrane proteins of bull spermatozoa through the freezing-thawing process

The widespread application of A. I. and realization of its full potential depends largely on the use of frozen semen. However, fertility resulting from A. I. is poorer than that from fresh semen in most species. The objective of this study was to compare the protein composition of fresh and frozen-thawed bull sperm plasma membrane surface. The effect of Tween 20 on protein removal from fresh and frozen sperm plasma membrane surface was studied and compared. The effect of incubation with different detergent concentrations on sperm motility and viability was examined. Approximately 2 x 10(8) frozen-thawed bull spermatozoa washed through a discontinuous Percoll gradient were incubated for 15 min at 20 degrees C with 0.01, 0.03 and 0.05% Tween 20. Sperm motility was completely eliminated at all 3 assayed detergent concentrations, while the initial sperm viability of 52% was decreased to 26, 10 and 5%, respectively, at the 3 concentrations. The removal of sperm plasma membrane proteins also increased from 0.72 mg to 2 mg with 0.05% Tween 20. Similar results were found with fresh semen samples. Although the amount of extracted proteins was significantly lower than that obtained with frozen spermatozoa, fresh sperm motility was likewise eliminated by the detergent treatment, and sperm viability was decreased. A semen sample with an initial sperm viability of 59% had a value of only 8% after treatment with 0.05% Tween 20. Comparative SDS-PAGE analysis of the extracted fractions from fresh and frozen-thawed semen treated with Tween 20 showed that the higher amount of extracted proteins in the frozen semen samples corresponded to the egg yolk lipoproteins in the cryoprotectant medium. However, it is worth noting that 4 more bands were found in the sample obtained from fresh semen than from frozen semen. These results indicate that some cell membrane proteins are lost through the freezing-thawing process.     

Centrifugation on PureSperm(®) density-gradient improved quality of spermatozoa from frozen-thawed dog semen

The main objective of this study was to investigate if centrifugation through PureSperm^® density-gradient can improve the post-thaw semen quality of dog semen. Semen from 5 dogs was collected and cryopreserved following a standard protocol. After thawing, semen samples were selected by centrifugation on PureSperm^®. Assessments 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 performed on aliquots of fresh semen, unselected samples and selected preparations. Cryopreservation had a significant (P < 0.001) effect on all studied semen parameters. PureSperm^® centrifugation yielded sperm suspensions with improved motility and viability (P < 0.001). The washing step significantly reduced (P < 0.001) all of the kinematics parameters evaluated as well as reduced the proportion of viable spermatozoa with intact acrosomes (P < 0.05). We concluded that PureSperm^® centrifugation is a successful method for improving the quality of frozen-thawed dog spermatozoa. However, washing after density-gradient centrifugation dramatically reduces the post-thaw semen quality, indicating that the inclusion of such a washing step is unnecessary.     

Low temperature storage of rhesus monkey spermatozoa and fertility evaluation by intracytoplasmic injection

The objective was to develop a sperm freezing procedure suitable for use in the propagation of valuable founder animals by assisted reproductive technologies. Here, we report a comparison of processing methods by measuring the motility of fresh and frozen-thawed rhesus monkey spermatozoa and fertility via intracytoplasmic spermatozoa injection (ICSI) of sibling oocytes. Washed spermatozoa were frozen in straws or in pellets using different cryoprotective media and processed post-thaw with or without a density gradient centrifugation step. Among the four study series, motility post-thaw was improved with density gradient centrifugation (17-24% versus 75%, P<0.01) achieving levels similar to fresh spermatozoa. Spermatozoa injected oocytes (total n=377) were co-cultured on BRL cells and observed for fertilization and development. With spermatozoa frozen in straws in liquid nitrogen vapors, the fertilization rate after ICSI was lower than with fresh spermatozoa (40-44% versus 77-86%, P<0.05), even with the Percoll-enriched fraction that exhibited robust motility. In contrast, somewhat slower freezing of spermatozoa in pellets on dry ice supported fertilization rates (73%) that were similar to the fresh counterpart. Developmental rates of fertilized eggs were similar in all experiments. A total of 106 embryo transfers has resulted in the first primate born after ICSI with F/T ejaculated spermatozoa plus 22 other infants to date. Additionally, a 3-4 h incubation after thawing improved the fertilization rate with spermatozoa from a male with poor post-thaw recovery of sperm motility. In conclusion, an acceptable fertilization rate after ICSI with motile, frozen-thawed primate spermatozoa was observed comparable to that obtained with fresh spermatozoa allowing small quantities of competent spermatozoa to be used with ICSI to facilitate propagation of desirable primate genotypes.     

Use of single-layer centrifugation with Androcoll-C to enhance sperm quality in frozen-thawed dog semen

The aim of this study was to investigate whether single-layer centrifugation (SLC) with Androcoll-C could select good quality spermatozoa, including those with specific motility patterns, from doses of frozen dog semen. Semen from five dogs was collected and cryopreserved following a standard protocol. After thawing, the semen samples were divided in two aliquots, one of which was used as a control and the other one processed by SLC. Assessment of sperm motility (assessed by computer-assisted semen analysis), morphology (Diff-Quick staining), viability (dual staining with propidium iodine/acridine orange), and acrosome integrity (dual staining with propidium iodine/isothiocyanate-labeled peanut [Arachis hypogaea] agglutinin) were performed on aliquots of fresh semen, frozen-thawed control samples, and frozen-thawed SLC-treated preparations. A multivariate clustering procedure separated 57,577 motile spermatozoa into three subpopulations (sP): sP1 consisted of poorly active and nonprogressive spermatozoa (48.8%), sP2 consisted of moderately slow but progressive spermatozoa (13.3%), and sP3 consisted of highly active and/or progressive spermatozoa (37.8%). SLC with Androcoll-C yielded sperm suspensions with improved motility, viability, and acrosome integrity (P < 0.01). The frozen-thawed SLC-treated samples were enriched in sP3, representing 38.5% of the sperm population. Likewise, sP2 was more frequently observed after SLC, but not significantly so. From these results, we concluded that for dog semen samples selected by SLC with Androcoll-C after thawing, the sperm quality parameters, including motility patterns, are better than in frozen-thawed control samples.     

A short sperm-oocyte incubation time ZBA in the dog

The fertilising capacity of a semen sample can be predicted by evaluation of spermatozoa with in vitro tests. The zona pellucida binding assay (ZBA) accounts for several parameters and interprets the interaction between the spermatozoa and the oocyte. The present study was made in two parts. The aim of the first experiment was to evaluate whether the sperm binding capacity of oocytes varies between different oocyte pools. Each zona binding was made with oocytes from different bitches, using pooled frozen-thawed semen from the same two dogs. The sperm-oocyte complexes were incubated for 1h. There was a significant difference between the six replicates in the number of sperm bound to the zona pellucida (ZP), which indicates that the sperm binding capacity of the ZP differs between oocyte pools. The aims of the second experiment were to evaluate the effects of five different treatments of the spermatozoa on the ZBA, and to evaluate two different incubation times of the sperm-oocyte complexes. ZBAs were made with: fresh semen; semen kept chilled for 1 or 2 days prior to the ZBA; and with semen that had been frozen with or without Equex. The oocytes and spermatozoa were incubated for 1 or 4h. For fresh semen and for semen frozen without Equex, incubation for 1h resulted in a higher number of bound spermatozoa per oocyte than incubation for 4h (P<0.0001). When the effect of the different sperm treatments on the number of spermatozoa bound to the ZP was evaluated, it was found that this number was higher for fresh spermatozoa than for chilled or frozen-thawed spermatozoa both after 1 and 4h of co-incubation (P<0.0001). After 1-h incubation of the sperm-oocyte complexes, spermatozoa chilled for 1 day showed better zona binding capacity than spermatozoa chilled for 2 days, and spermatozoa frozen without Equex had a better zona binding capacity than spermatozoa frozen with Equex. Sperm motility and sperm plasma membrane integrity were higher in fresh than in chilled and frozen-thawed semen. The acrosome integrity was high in all groups of treated semen. In conclusion, 1-h incubation of the sperm-oocyte complexes seems to be sufficient for fresh and chilled semen. Further studies are required to establish the optimal incubation time for sperm-oocyte complexes when frozen-thawed semen is evaluated, as a comparison between semen frozen with Equex and semen frozen without Equex gave different results depending on whether the incubation time was 1 or 4h (in the present study), or 6h [Str?m Holst B, Larsson B, Linde-Forsberg C, Rodriguez-Martinez H. Evaluating chilled and frozen-thawed dog spermatozoa using a zona pellucida binding assay.     

Semen characteristics and their ability to predict sperm cryopreservation potential of Atlantic cod, Gadus morhua L

There is a lack of biomarkers or indices that can be used to predict the quality of fish semen samples following the freezing and thawing cycle. In the present study, a series of semen indices were tested to assess if they could accurately forecast the cryopreservation potential of Atlantic cod (Gadus morhua) semen. Fresh and frozen-thawed sperm activity variables were compared, and relationships between frozen-thawed sperm activity and fertilization success were examined. In comparison with fresh sperm, activity variables of frozen-thawed spermatozoa were reduced. Of the 18 males examined, mean (± SEM) spermatocrit of fresh sperm was 40.72 ± 4.23%, osmolality of the seminal plasma 366.32 ± 4.95 mOsmol/kg, pH 8.32 ± 0.04, protein concentration 1.05 ± 0.08 mg/mL, anti-trypsin activity 153.83 ± 19.25 U/L, and total antioxidant capacity 0.15 ± 0.03 μmol Trolox equivalents/mL. Frozen-thawed fertilization success was highly variable among males with values ranging from 18.5 to 90.2%. Regressions yielded significant positive relationships between frozen-thawed motility, velocity, track crossing frequency, and subsequent fertilization success. Sequential multiple regressions explained up to 95% of the variation in frozen-thawed sperm activity. Spermatocrit and pH of fresh semen were negatively related, whereas osmolality and antioxidant capacity were positively related to frozen-thawed motility and velocity. Each of these indices can be measured within minutes of collecting a fresh sample of semen and are thus early indicators of the capacity of semen samples to withstand cryopreservation. These results have many benefits for conservation of wild stocks, aquaculture production, and for understanding semen biology and cryobiology of fishes.     

Resistance to osmotic stress of horse spermatozoa: the role of ionic pumps and their relationship to cryopreservation success

To study the resistance of horse spermatozoa against hyperosmotic stress, cells were incubated in solutions of 600 to 4000 mOsm(undisturbed media). Then, semen was immediately placed into an iso-osmotic solution (disrupted media). Incubation in undisturbed media decreased sperm viability in an osmolarity- and temperature-dependent manner. Viability was further decreased in disrupted media, with the effect dependent upon the initial osmolarity of the media and on the temperature. Treatment with ouabain or amiloride impaired the resistance of horse spermatozoa to hyperosmotic stress. Very few correlations were strong between viability after hyperosomotic stress and quality parameters of fresh and frozen-thawed horse semen. The results indicate that the usefulness of resistance to hyperosmotic stress in assessing frozen-thawed semen quality is compromised, since other factors are involved in the resistance to freezing-thawing. Both Na (+)K (+) ATP-ase and the Na (+)H (+) antiporter act in the resistance to hyperosmotic stress in horse spermatozoa.     

Effect of cryopreservation of zona-binding capacity of canine spermatozoa in vitro

The hemizona assay (HZA) was used as a functional test for zona pellucida binding capacity of fresh and frozen-thawed canine spermatozoa. We investigated 30 ejaculates from 3 dogs with sperm motility > 70% and sperm concentration > 5.10(8) cells per ejaculate with up to 20% abnormal and dead spermatozoa. Fifteen ejaculates were each divided into 2 portions: one portion was used for analysis of fresh semen, the other for cryopreserved semen. On the day of the experiments, in vitro-matured canine oocytes were bisected into 2 equal hemizonae. One half of the hemizonae were coincubated with fresh capacitated (control) spermatozoa, the other half of the hemizonae were coincubated with frozen-thawed (tested) spermatozoa at final concentration of 1 to 2 x 10(6) cells/mL in 200 microL droplets of BSA-supplemented Toyoda, Yokojama and Hoshi (TYH) medium at 37 degrees C, 5%, CO2 for 1 h. Sperm suspensions were examined kinesigraphically for post capacitation type of movement. The Student's t-test was used to compare differences between semen parameters. The data on HZA binding activity of fresh and frozen-thawed canine semen were analyzed by ANOVA and then by the Newman-Keuls multiple range method. The results showed no differences in the initial semen quality parameters among the 3 dogs. After thawing, the semen from Dog 1 and Dog 2 demonstrated relatively uniform sperm parameters, while in Dog 3 sperm motility, and viability and the percentage of morphologically normal spermatozoa were significantly decreased. The binding activity of frozen-thawed spermatozoa from the 3 dogs was significantly reduced (29.40 +/- 9.02, 18.60 +/- 3.30, 8.20 +/- 4.49) compared with that (107.20 +/- 19.22, 109.80 +/- 20.75, 78.20 +/- 12.47; P < 0.01) of fresh spermatozoa. The results showed that semen samples with similar sperm parameters prior to cryopreservation displayed different sperm zona-binding capacity after freezing. The HZI (value of sperm binding capacity of frozen-thawed vs fresh semen samples) was higher in Dog 1 (27.43) than in Dog 2 (16.90) or Dog 3 (10.40), and thus confirmed the variation of zona binding activity after thawing between dogs. The freezability of individual dog semen is discussed. In conclusion HZA may be a valuable tool for evaluating the post-thaw fertilizing ability of canine spermatozoa.     

Capacitation status of fresh and frozen-thawed buffalo spermatozoa in relation to cholesterol level, membrane fluidity and intracellular calcium

The present study was conducted to assess the capacitation status of fresh and frozen-thawed buffalo spermatozoa and its relationship with sperm cholesterol level, membrane fluidity and intracellular calcium. Semen from seven buffalo bulls (eight ejaculates each) was divided into two parts. Part I was used as fresh semen and part II was extended in Tris–egg yolk extender, equilibrated (4 °C for 4 h) and frozen at −196 °C in LN₂. The fresh and frozen-thawed spermatozoa were assessed for capacitation status using chlortetracycline (CTC) fluorescent assay, membrane fluidity using merocyanine 540/Yo-Pro-1 assay and intracellular calcium using Fluo-3 AM with flowcytometry. Results revealed a significant (P < 0.01) increase in capacitated sperm population in frozen-thawed semen compared to fresh semen (42.21% vs 14.32%). Similarly, a significantly (P < 0.01) higher proportion of frozen-thawed live spermatozoa showed high membrane fluidity (53.62% vs 25.67%) and high intracellular calcium (43.68% vs 11.72%) compared to fresh semen. The sperm cholesterol was significantly (P < 0.01) reduced after freezing–thawing as compared to fresh semen. The proportion of capacitated spermatozoa (CTC pattern B) was positively correlated with the proportion of sperm with high intracellular calcium (r = 0.81) and high membrane fluidity (r = 0.65), and negatively correlated with cholesterol level (r = −0.56) in frozen-thawed semen. The membrane fluidity was also strongly associated with the cholesterol level and intracellular calcium. The study concluded that changes in buffalo spermatozoa and established the relationship among capacitation status, sperm cholesterol level, membrane fluidity and intracellular calcium concentration in frozen-thawed spermatozoa.     

Flow cytometric sorting of fresh and frozen-thawed spermatozoa in the western lowland gorilla (Gorilla gorilla gorilla)

We adapted flow cytometry technology for high-purity sorting of X chromosome-bearing spermatozoa in the western lowland gorilla (Gorilla gorilla gorilla). Our objectives were to develop methodologies for liquid storage of semen prior to sorting, sorting of liquid-stored and frozen-thawed spermatozoa, and assessment of sorting accuracy. In study 1, the in vitro sperm characteristics of gorilla ejaculates from one male were unchanged (P > 0.05) after 8 hr of liquid storage at 15 degrees C in a non-egg yolk diluent (HEPES-buffered modified Tyrode's medium). In study 2, we examined the efficacy of sorting fresh and frozen-thawed spermatozoa using human spermatozoa as a model for gorilla spermatozoa. Ejaculates from one male were split into fresh and frozen aliquots. X-enriched samples derived from both fresh and frozen-thawed human semen were of high purity, as determined by fluorescence in situ hybridization (FISH; 90.7%+/-2.3%, overall), and contained a high proportion of morphologically normal spermatozoa (86.0%+/-1.0%, overall). In study 3, we processed liquid-stored semen from two gorillas for sorting using a modification of methods for human spermatozoa. The sort rate for enrichment of X-bearing spermatozoa was 7.3+/-2.5 spermatozoa per second. The X-enriched samples were of high purity (single-sperm PCR: 83.7%) and normal morphology (79.0%+/-3.9%). In study 4 we examined frozen-thawed gorilla semen, and the sort rate (8.3+/-2.9 X-bearing sperm/sec), purity (89.7%), and normal morphology (81.4%+/-3.4%) were comparable to those of liquid-stored semen. Depending on the male and the type of sample used (fresh or frozen-thawed), 0.8-2.2% of gorilla spermatozoa in the processed ejaculate were present in the X-enriched sample. These results demonstrate that fresh or frozen-thawed gorilla spermatozoa can be flow cytometrically sorted into samples enriched for X-bearing spermatozoa.     

In vitro fertilization of porcine oocytes with fresh and frozen-thawed ejaculated or frozen-thawed epididymal semen obtained from identical boars

The objective of this study was to compare the in vitro fertilizing capacity of porcine spermatozoa from fresh and frozen-thawed semen and frozen-thawed epididymal spermatozoa obtained from identical boars. Prior to IVF, fresh spermatozoa were capacitated in TCM 199. Frozen semen samples were stored in 0.25-ml plastic straws using a lactose/glycerol/orvus-es-paste extender. Cumulus-oocyte-complexes (COC) obtained from superovulated prepuberal gilts were fertilized in vitro within 2 h after aspiration with one of the semen samples. After final dilution for IVF, frozen-thawed epididymal semen samples showed motility rates (72.2 +/- 5.6%) similar to those of spermatozoa in fresh semen (76.4 +/- 4.5%), while sperm motility decreased in frozen-thawed ejaculated semen (40.2 +/- 9.4%). Considerable individual differences in sperm motility between boars were observed for ejaculated semen but not for epididymal semen. Enhanced fertilizing capacity of frozen-thawed epididymal spermatozoa was confirmed by pronucleus formation and cleavage rates, with significantly more embryos developing to the 2- and 4-cell stages compared with the groups fertilized with fresh or with frozen-thawed ejaculated semen (59.7 vs 14.6 and 16%). In conclusion, consistent in vitro fertilization rates with minimal semen variability are obtained using frozen-thawed epididymal semen. Following a modified freezing protocol, epididymal spermatozoa can easily be frozen in small containers for IVF, with higher resultant motility and fertilization rates than with ejaculated semen.     

Evaluation of fresh and frozen-thawed semen of individual ganders by assessment of spermatozoa motility and morphology

Individual differences in gander Anser anser L. reaction to semen collection procedure, quality and quantity of fresh semen and its susceptibility to the freezing process are discussed. Semen was collected individually by dorso-abdominal massage, from 1-year old White Koluda ganders (n = 12) every 2-3 days. Ganders' reactions to massage were observed during the entire reproductive cycle (from 11 February to 13 June, from every male 40 semen collections were performed). For individual evaluation and freezing purpose semen was collected 13 times from every male. In the fresh semen, the following parameters were evaluated: ejaculate volume, color, density, blood or fecal contamination, motility, concentration and morphology of spermatozoa. Motility and spermatozoa morphology were evaluated in the frozen-thawed semen. Semen diluted in 2:1 ratio with EK diluent was frozen with 6% of dimethyl-formamide (DMF) to -140 degrees C at a rate 60 degrees C/min. Semen was thawed by placing the straws in a 60 degrees C water-bath for 4-5 s. Ten out of 12 ganders had from 67.5 to 100.0% positive reactions resulting in semen ejaculation. Significant (P < or = 0.01) differences in fresh semen quality of particular ganders were observed for all evaluated traits. In 1-year-old gander semen morphologically intact spermatozoa constitute only 27.8-45.2% of all cells. Therefore, the sperm quality factor (SQF), proposed by the authors, which includes ejaculate volume, sperm concentration and the percentage of live normal spermatozoa, seems to be a good predictor of gander semen fertilizing ability. The SQF of individual ganders varied from 7.7 to 11.5. The percentage of live normal spermatozoa in the frozen-thawed semen depended mainly on fresh semen quality. In relation to the fresh semen average from 57.2 to 63.2% of spermatozoa survived freezing process and from 23.9 to 38.5% remained morphologically intact.     

Computer-assisted sperm analysis of fresh epididymal cat spermatozoa and the impact of cool storage (4 °C) on sperm quality

Epididymal cat sperm is commonly used for in vitro fertilization. Because of the high variability in preparation protocols and methods of evaluation, sperm quality may vary considerably between experiments and laboratories. The aims of the present study were (1) to describe an epididymal sperm preparation protocol to produce clean, highly motile samples using density gradient centrifugation, (2) to provide reference values of computer-assisted semen analysis (CASA) parameters of fresh epididymal cat sperm after density gradient centrifugation and (3) to investigate the effect of cool storage on various spermatozoa characteristics. After slicing the epididymides, viable and motile sperm cells were isolated using Percoll^® centrifugation. Sperm motility parameters were subsequently assessed using CASA in experiment 1. In experiment 2, fresh (day 0) sperm samples were evaluated for motility parameters (HTR) and stained for assessment of acrosomal status (FITC-PSA), morphology (eosin/nigrosin (E/N)), membrane integrity (E/N and SYBR^®14-PI) and DNA fragmentation (TUNEL). After addition of a Tris–glucose-citrate diluent containing 20% egg yolk, samples were cooled to 4 °C and reassessed on d1, d3, d5, d7 and d10. Cool storage impaired most motility and velocity parameters: MOT, PMOT, VAP, VSL, VCL, BCF, RAPID and the percentage of normal spermatozoa showed a decrease over time (P < 0.05) as compared to fresh samples. In contrast, STR, ALH, membrane integrity, DNA fragmentation and the percentage of acrosome intact spermatozoa were not affected by cool storage. However, the influence of cool storage of cat spermatozoa on subsequent in vitro embryo development and quality after IVF requires further investigation.     

Computer-assisted sperm analysis of fresh epididymal cat spermatozoa and the impact of cool storage (4 degrees C) on sperm quality

Epididymal cat sperm is commonly used for in vitro fertilization. Because of the high variability in preparation protocols and methods of evaluation, sperm quality may vary considerably between experiments and laboratories. The aims of the present study were (1) to describe an epididymal sperm preparation protocol to produce clean, highly motile samples using density gradient centrifugation, (2) to provide reference values of computer-assisted semen analysis (CASA) parameters of fresh epididymal cat sperm after density gradient centrifugation and (3) to investigate the effect of cool storage on various spermatozoa characteristics. After slicing the epididymides, viable and motile sperm cells were isolated using Percoll^® centrifugation. Sperm motility parameters were subsequently assessed using CASA in experiment 1. In experiment 2, fresh (day 0) sperm samples were evaluated for motility parameters (HTR) and stained for assessment of acrosomal status (FITC-PSA), morphology (eosin/nigrosin (E/N)), membrane integrity (E/N and SYBR^®14-PI) and DNA fragmentation (TUNEL). After addition of a Tris–glucose-citrate diluent containing 20% egg yolk, samples were cooled to 4 °C and reassessed on d1, d3, d5, d7 and d10. Cool storage impaired most motility and velocity parameters: MOT, PMOT, VAP, VSL, VCL, BCF, RAPID and the percentage of normal spermatozoa showed a decrease over time (P < 0.05) as compared to fresh samples. In contrast, STR, ALH, membrane integrity, DNA fragmentation and the percentage of acrosome intact spermatozoa were not affected by cool storage. However, the influence of cool storage of cat spermatozoa on subsequent in vitro embryo development and quality after IVF requires further investigation.     

Effects of osmotic pressure on motility, plasma membrane integrity and viability in fresh and frozen-thawed buffalo spermatozoa

In the first experiment, osmotic pressure of semen and seminal plasma in a semen sample from each of the 20 mature Nili-Ravi buffalo bulls was determined. In the second experiment, effects of osmotic pressure on motility (%), plasma membrane integrity (%) and viability (%) in fresh and frozen-thawed semen samples from each of the seven mature Nili-Ravi buffalo bulls was determined. In the first experiment, seminal plasma was harvested by centrifuging semen at 400 × g for 10 min at 37°C and osmotic pressure was determined using an osmometer. In the second experiment, motility (%) was assessed in fresh and frozen-thawed (37°C for 30 s) semen samples using a phase-contrast microscope (×400). Plasma membrane integrity (%) was determined by mixing 50 μl each of fresh and frozen-thawed semen with 500 μl of solution having an osmotic pressure of 50, 100, 150, 190 or 250 mOsm/l (hypotonic treatments of fructose + sodium citrate) and incubating at 37°C for 1 h. Viability (%) of fresh and frozen-thawed spermatozoa before and after challenging them to osmotic pressure (hypotonic treatments) was assessed using supravital stain under a phase-contrast microscope (×400). In the first experiment, the mean ± s.e. osmotic pressures of the buffalo semen and seminal plasma were 268.8 ± 1.17 and 256.0 ± 1.53 mOsm/l, respectively. In the second experiment, motility (%) decreased (P < 0.05) in frozen-thawed semen samples as compared with fresh semen (60.1 ± 1.34 v. 81 ± 1.57, respectively). The plasma membrane integrity (%) and magnitude of osmotic stress in fresh and frozen-thawed semen samples was higher (P < 0.05) at 50, 100, 150 and 190 mOsm/l as compared with 250 mOsm/l. Loss of viability (%) in fresh and frozen-thawed semen samples was higher (P < 0.05) at 50 mOsm/l (59% in fresh, 70% frozen thawed) as compared with other osmotic pressures, while it was lowest at 250 mOsm/l (4.1% for fresh, 9.7% frozen thawed). In conclusion, osmotic pressure of Nili-Ravi buffalo semen and seminal plasma is determined. Furthermore, variation in osmotic pressure below 250 mOsm/l is not favorable to fresh and frozen-thawed buffalo spermatozoa.