Automatic evaluation of ram sperm morphometry

This study was designed to develop a new method based on fluorescence microscopy and image analysis for the automatic assessment of sperm morphometry and to study separately the effect of drying and fixation on the parameters of head sperm morphometry in the ram. The study was divided into two experiments. In the first experiment, ejaculates from 25 adult males were collected using an artificial vagina, diluted and divided into four sample aliquots. The first was labeled directly with Hoechst 33342 (FRESH), and the others were processed as smears. Between smears, one group was directly labeled with Hoechst after air drying (DRIED), and the other were fixed either with glutaraldehyde (GLUT), or with methanol (MET), and labeled with Hoechst afterward. Digital images of the fluorescence-labeled sperm were recorded with a digital camera, and sperm heads were automatically captured and analyzed using the ImageJ program. The method used allowed a fast and automatic selection of most sperm heads for a given image with high precision. There was a general trend toward significant decrease in head length, width, area and perimeter of air-dried sperm compared with fresh sperm. On average, this decrease was of 4.1% in length, 4.3% in width, 9.1% in area, and 2.8% in perimeter. Between semen smears, fixation with glutaraldehyde significantly increased head sperm dimensions. The smears fixed with glutaraldehyde method is recommended for a more practical use than with fresh samples, providing better quality images than the other methods, and because the morphometric results obtained were more similar to the FRESH group than those of the DRIED and MET. In the second experiment, ejaculates from adult males were used to compare the sperm head morphometric results obtained with the new method developed (using the GLUT treatment as reference) with a more conventional CASMA method (semen smears stained with Hemacolor and processed with the ISAS commercial software, HEM). The GLUT method allowed the analysis of 100% of sperm, whereas only 93% of sperm could be analyzed using HEM. Spermatozoa displayed a bigger size when processed with HEM than with GLUT method in all primary sperm head morphometric parameters. A significant correlation was observed between the two methods used in this experiment for all morphometric size parameters. The new method developed allows automatic determination of sperm head morphometry in a reduced time, which facilitates its use in routine semen analysis. It was concluded that the automation of sperm morphometry is feasible using fluorescence microscopy and image analysis and that the effect of drying and fixation was less important than previously stated.     

The effect of cryopreservation on sperm head morphometry in Florida male goat related to sperm freezability

The Sperm Class Analyzer was used to investigate the effect of freeze-thawing procedure on Florida buck sperm head morphometry, and to relate possible changes in sperm head dimensions to cryopreservation success. Semen samples (n=76) were frozen with tris and milk-based extenders and thawed. Sperm quality samples (motility, morphology, acrosome), and sperm head morphometric values (length, width, area, perimeter, ellipticity) were compared between fresh and frozen-thawed samples. Sperm freezability was judged according to the sperm quality parameters assessed. Fertility data was obtained after artificial insemination with cryopreserved semen. Cryopreservation success was different between freezing methods. Sperm head dimensions were significantly (p<0.05) smaller in cryopreserved tris and milk spermatozoa respectively than in those of the fresh samples. The sperm head morphometric parameters that had changed after cryopreservation were lower in suitable semen samples after thawing and with successful pregnancies after artificial insemination. These data suggest that changes in sperm head morphometry might reflect spermatozoa injury occurred during cryopreservation.     

Computer automated sperm head morphometry analysis (ASMA) of goat spermatozoa

The development of computer automated sperm morphometry analysis (ASMA) allows for the objective analysis of sperm head dimensions. A number of studies have been performed to optimize the efficiency of these systems when analyzing spermatozoa from a variety of species. In this study, frozen semen from 10 fertile goat bucks was thawed and prepared on slides for morphometric analysis to evaluate technical variation and to standardize ASMA procedures for goat spermatozoa. Methods of staining, the number of spermatozoa necessary to sample and optimal microscopic magnification were assessed. Staining for 20 min in hematoxylin (HEM) was found to be optimal. The most efficient method of analyzing goat sperm morphometry was to evaluate 100 sperm cells at x20 objective magnification. Using these techniques, a sample could be analyzed in approximately 2 min. The system properly recognized and digitized spermatozoa 96% of the time with a target recognition error rate of less than 1%. The morphometric measurements of sperm heads for all 10 bucks were the following: length = 7.69microm, width = 3.80microm, width/length ratio = 0.5, area = 22.82microm and perimeter = 20.15microm. The mean coefficients of variation (CV) for all bucks ranged from 3.4% for length to 5.8% for area. Standardized sample preparation techniques and analysis were found to improve the efficiency of ASMA.     

Computer-assisted sperm head morphometry analysis (ASMA) of cryopreserved ram spermatozoa

Normal sperm morphology has been shown to be indicative of male fertility; however, subjective methods of assessing morphology are highly variable. Computer-assisted sperm morphometry analysis (ASMA) has been developed for the objective analysis of sperm head dimensions. Developing applicable protocols for sperm head morphometry analysis increases the efficiency of these systems. The objective of the current study was to develop accurate methods for employing ASMA of ram sperm heads. Staining methods, optimal sperm sample numbers microscopic magnification and sampling variation within and between technicians were assessed. Frozen semen from 10 fertile rams was thawed and prepared on slides for morphometric analysis. Staining spermatozoa with hematoxylin and rose bengal stains yielded the best results. Ram sperm head morphometry was accurately evaluated on at least 100 spermatozoa at x 40 objective magnification. Using these techniques, a sample could be analyzed in approximately 3 min. No significant differences in sperm head measurements were detected between 2 technicians. The system properly recognized and digitized ram spermatozoa 95% of the time. The morphometric measurements of sperm heads for all rams were as follows: length = 8.08 microns, width = 4.80 microns, width:length ratio = 0.59, area = 29.13 micron 2 and perimeter = 23.93 microns. The mean within analysis coefficients of variation for all individual analyses and parameters ranged from 4.8% for length to 6.0% for area. The variation between replicate analysis was 2.4% or less for both technicians. When applying proper sample preparation and analysis procedures no differences in measurements or variation were observed between the 2 system operators.     

The relationship between ram sperm head morphometry and fertility depends on the procedures of acquisition and analysis used

Sperm head morphometry is a parameter in the evaluation of semen that has been associated with fertility in two ways: comparing morphometric measures between predefined groups of fertility; or analyzing morphometric data by multivariate techniques to identify cell populations. We analyzed the morphometry of ram sperm head by three procedures and checked its relationship with male fertility. A Computer-Aided Sperm Morphometric Assessment procedure (CASMA), an image analysis software (NIS-Elements) in combination with an optical microscope (MO-NIS) and this image analysis software in combination with a scanning electron microscope (SEM-NIS) were used. Eight morphometric parameters were assessed: length, width, area, perimeter, ellipticity, form factor, elongation and regularity. We observed significant differences between the morphometric data of sperm head obtained with three study procedures. The CASMA procedure shows the highest values for all parameters and the SEM-NIS procedure the lowest. The analysis of a semen sample, when only the mean of morphometric parameters is used to describe the cell population, is too limited to interpret their fertilizing capacity. It is essential to analyze the complex structure of the samples by defining subpopulations by multivariate methods. With few exceptions, the means of each morphometric parameter differ between the three subpopulations analyzed in each procedure. Only the subpopulations obtained with the MO-NIS procedure showed a significant correlation with male fertility. In short, it is necessary to establish an instrumental standard for the analysis of sperm morphometry to obtain reliable results and we believe that the MO-NIS system presents these basic requirements.     

Computer assisted morphometric analysis of ram sperm heads: evaluation of different fixative techniques

The recent development of automated systems for morphometric sperm head analysis has provided a series of objective parameters which have facilitated the standardization of morphological semen evaluation. This current work attempts to establish the optimum fixing conditions for the morphometric characterization of ram spermatozoa. Ejaculates were obtained from 5 Merino rams used for periodic collection of semen and were diluted at 1:50 with TEST medium. Air-dried smears were fixed either in ethanol-ether (1:1), 50% methanol, 2% glutaraldehyde or SUZA fixative, in which case the smear was pretreated with chloramine. The samples were then stained with commercial kit Hemacolor. Once the preparations had been mounted, they were analyzed with the Sperm Class Analyzer automatic sperm morphometry analysis system (ASMA). The minimum number of sperm cells analyzed per sample was 100. The parameters evaluated were the area, perimeter, length, width, shape factor and mass. The results showed significant differences in sperm head dimensions between the 4 fixation techniques, with the lowest values for all parameters corresponding to the SUZA fixative, followed by glutaraldehyde, methanol, and finally ethanol-ether. In addition, there were significant variations between animals. It can, therefore, be concluded that the working protocol must be defined when performing morphometric analysis of ram semen and that the results obtained under different conditions of fixation cannot be entirely extrapolated. Equally, the high variability among individuals suggests that, in a species like the ram with a low index of teratozoospermia, there is a need for a revision of the classic definition of normality, which should include morphometric data.     

Automated sperm morphometry and morphology analysis of canine semen by the Hamilton-Thorne analyser

Computer-assisted sperm morphometry has the potential to eliminate several drawbacks inherent to the current methods of sperm morphology evaluation, and allows for the identification of subtle sperm characteristics which cannot be detected by visual evaluation. In the present study, the Metrix Oval Head Morphology software implemented in the Hamilton-Thorne CEROS (version 12.1; HTR 12.1 Metrix) computer-aided semen analyser was evaluated for canine sperm morphometry and morphology analysis. Comparison of sperm morphometric measurements of 200 spermatozoa from pooled semen samples (n = 4) at 40x and 60x demonstrated a more accurate identification of the sperm head boundaries at a magnification level 60x. Dilution of pooled semen samples (n = 4) to a sperm concentration of 50 x 10(6) ml(-1) allowed for a correct evaluation of the sperm cell dimensions whereas 100 x 10(6) and 200 x 10(6) ml(-1) resulted in a higher percentage of rejected spermatozoa due to overlapping. No differences in morphometric dimensions were found when 100 or 200 spermatozoa were evaluated for each of 15 dogs. The mean morphometric parameters of canine spermatozoa, based on the fresh ejaculates of 23 dogs, were: major 6.65 +/- 0.20 microm; minor 3.88 +/- 0.14 microm; area 20.66 +/- 1.04 microm2; elongation 58.64 +/- 2.58 %; perimeter 17.57 +/- 0.43 microm and tail length 48.93 +/- 10.16 microm. Large variations in morphometric dimensions were detected among individual dogs. After cryopreservation, significantly lower morphometric dimensions were obtained for all the evaluated sperm samples (n = 12). Finally, a correlation of 0.82 (P < 0.05) was established for the percentage of normal spermatozoa assessed by subjective evaluation and by the HTR 12.1 Metrix (n = 39 semen samples). In conclusion, dilution of the semen samples to approximately 50 x 10(6) spermatozoa/ml and an objective lens magnification of 60x, analysing at least 100 spermatozoa, are the technical settings proposed to obtain reliable and objective sperm morphometric measurements by the HTR 12.1 Metrix in canine.     

Cut-off values for normal sperm morphology and toxicology for automated analysis of rat sperm morphology and morphometry

We used automated sperm morphology analysis to investigate rat sperm morphometry and morphology in Sprague-Dawley and Wistar rats in three research centers to develop normal baseline values for sperm morphometry and to quantify the percentage of morphologically normal sperm in healthy rats. The participating centers were IRSN in Paris, France (Sprague-Dawley rats), University of the Western Cape, South Africa (Wistar rats) and Stellenbosch University (Wistar rats), South Africa. All three centers used identical sperm isolation techniques from the cauda epididymis, the same staining protocols, identical computer-aided sperm morphometry analysis (CASMA) software and microscopes with similar optics. With CASMA, fully automated analysis of the different parts of stained sperm, e.g., head, acrosome, mid-piece, can be performed, many sperm morphometric features can be measured accurately and eventually normal sperm morphology can be defined. We found that it is possible to distinguish sperm morphometric characteristics of Sprague-Dawley and Wistar rats. We also developed cut-off values for evaluating the percentage normal sperm in these two rat strains using the automatic analysis mode. Normal sperm morphology varied between 67 and 74% by contrast with previous findings of > 90%.     

Assessment of the viability and acrosome status of fresh and frozen-thawed human spermatozoa using single-wavelength fluorescence microscopy.

The purpose of this study was to use fluorescence microscopy to determine the viability and acrosome status of fresh and frozen-thawed human spermatozoa. Sperm cells were stained with the viability stains Hoechst 33258 (H33258) alone, or propidium iodide (PI) alone, and PI in combination with FITC-conjugated Pisum sativum agglutinin (PSA). The PSA stains the acrosome contents of permeabilized acrosome-intact sperm. Viability by fluorescence microscopy was compared to conventional eosin nigrosin staining. The overall viability using H33258 was not significantly different from that using PI. Therefore, PI was used in combination with PSA for simultaneous measurement of viability and acrosome status at the same excitation wavelength (488 nm). By combining PI and PSA, four subgroups of cells could be detected: group I, PI-neg/PSA-neg--viable, physiologic acrosome reacted (AR); group II, PI-neg/PSA-pos--viable, non-AR; group III, PI-pos/PSA-neg--nonviable, non-AR; group IV, PI-pos/PSA-neg--nonviable, degenerative AR. The postthaw sperm exhibited a significantly greater percent of sperm that were acrosome reacted (both viable and degenerative) (groups I and IV) than the fresh semen. We conclude that frozen-thawed sperm may undergo premature break-down of the acrosome prior to interaction with the oocyte, thus explaining the reduced fertility potential of cryopreserved semen.     

Morphometrically-distinct sperm subpopulations defined by a multistep statistical procedure in ram ejaculates: intra- and interindividual variation

The existence of sperm subpopulations within the mammalian ejaculate has now been widely recognized. However, to the best of our knowledge, no data exist regarding the existence of sperm morphometric subpopulations within the ovine ejaculate. Computer assisted sperm morphometry analysis (ASMA) data and clustering methods were used in this study to identify sperm-head subpopulations in ram semen. Two experiments were carried out. In Experiment 1, ejaculates from 226 mature rams of the Manchega breed belonging to 36 different herds were used. A minimum of 100 sperm heads were analyzed from each male and eight morphometric characteristics for each individual sperm were recorded. Subpopulation analysis was performed in sequential steps: variable group analysis and correlation analysis to select which morphometric characteristics to use in cluster analyses; nonhierarchical clustering analysis using sperm head length and p2a (also known as roundness) shape factor as initial classificatory variables; and hierarchical clustering analysis to obtain the final number of clusters. The clustering analyses, based on 26 306 individual cells, revealed the existence of four sperm subpopulations (SP1, SP2, SP3 and SP4) with different morphometric characteristics. Significant differences in the proportion of spermatozoa in the SP1 and SP3 were found between rams belonging to different herds. In Experiment 2, the intra- and intermale variability on the distribution of sperm subpopulations was assessed. Three ejaculates from each of 21 rams were collected and the same multistep clustering analysis was performed. For all subpopulations defined, the intermale variability resulted in high values, being the intramale variability much lower. This fact would allow the use of sperm head morphometry to characterize a male and might provide valuable information to asses its fertility. In conclusion, our results show that using computer assisted sperm morphometry analysis and multivariate cluster analyses, four sperm subpopulations with different head phenotype were identified in ram ejaculates.     

Morphometric classification of Spanish thoroughbred stallion sperm heads

This work used semen samples collected from 12 stallions and assessed for sperm morphometry by the Sperm Class Analyzer (SCA) computer-assisted system. A discriminant analysis was performed on the morphometric data from that sperm to obtain a classification matrix for sperm head shape. Thereafter, we defined six types of sperm head shape. Classification of sperm head by this method obtained a globally correct assignment of 90.1%. Moreover, significant differences (p<0.05) were found between animals for all the sperm head morphometric parameters assessed.     

Characterization of ram (Ovis aries) sperm head morphometry using the Sperm-Class Analyzer

Sperm morphology has been identified as a characteristic that can be useful in the prediction of fertilizing capacity. The aim of the current study was to characterize ram sperm heads morphometrically as a basis for future studies on the relationship between sperm quality and male fertility. For this purpose, ejaculates from 241 mature rams (Ovis aries) belonging to 36 different dairy herds were used to evaluate sperm head morphometry by means of the Sperm-Class Analyzer. Sperm samples, collected by artificial vagina, were diluted in phosphate buffered saline (PBS) for the analysis. A microscope slide was prepared from single-diluted fresh sperm samples. Slides were air-dried and stained with Hemacolor. A minimum of 115 sperm heads were analyzed from each male. Each sperm head was measured for four primary parameters (area, perimeter, length, width), and four derived parameters of head shape were obtained. Significant differences in sperm head morphometry were found between rams (CV for morphometric parameters ranging from 0.9 to 10.1), and there were marked differences in the sperm morphometric composition of the ejaculates. For all parameters, within-animal CVs were greater than between-animal CVs. Within-animal CVs ranged from 4.2 to 10.6, showing the high degree of sperm polymorphism present in the sheep ejaculate. Significant differences in sperm head morphometry were found between rams belonging to the different herds (i.e., origin). An important part of the variability observed on morphometric parameters was due to the male itself, with an explained variance ranging from 3.6% for regularity to 34.0% for p2a (perimeter²/[4 × π × area]). The explained variance by the herd of origin of the males ranged from 0.6% for regularity to 10.8% for area. Our results suggest that a genetic component might be responsible for the observed sperm head morphometry differences between herds.     

Objective assessment of goat sperm head size by computer-assisted sperm morphometry analysis (ASMA)

The aim of the present study was to identify different objective categories of sperm head size evaluation, using both morphometric and statistical analyses. For this purpose, semen samples (n = 16) were collected from 4 Florida male goats and assessed using a computer-assisted sperm morphometric analysis (ASMA) to obtain sperm head size measurements. The sperm heads were grouped into categories according to 25th and 75th percentiles (the lower and upper quartile, respectively) of their area values. Thereafter, a discriminant analysis was implemented on all the sperm morphometric parameters assessed, to obtain a classification matrix for sperm head size. Sperm heads by this method were classified into 3 categories depending on their size (small, medium and large), with a globally correct assignment of 95.5%. Moreover, significant differences (p < 0.001) were recorded between individual animals for all the sperm head morphometric parameters assessed. In conclusion, by using both statistical and morphometric analyses, it was possible to recognize the three categories of sperm head size. It is expected that research could be useful in defining the relationship between sperm head size measurements and actual fertility data.     

Mammalian sperm morphometry.

Understanding the adaptive significance of sperm form and function has been a challenge to biologists because sperm are highly specialized cells operating at a microscopic level in a complex environment. A fruitful course of investigation has been to use the comparative approach. This comparative study attempts to address some fundamental questions of the evolution of mammalian sperm morphometry. Data on sperm morphometry for 445 mammalian species were collated from published sources. I use contemporary phylogenetic analysis to control for the inherent non-independence of species and explore relationships between the morphometric dimensions of the three essential spermatozoal components: head, mid-piece and flagellum. Energy for flagellar action is metabolized by the mitochondrial-dense mid-piece and these combine to propel the sperm head, carrying the male haplotype, to the ovum. I therefore search for evolutionary associations between sperm morphometry and body mass, karyotype and the duration of oestrus. In contrast to previous findings, there is no inverse correlation between body weight and sperm length. Sperm mid-piece and flagellum lengths are positively associated with both head length and area, and the slopes of these relationships are discussed. Flagellum length is positively associated with mid-piece length but, in contrast to previous research and after phylogenetic control, I find no relationship between flagellum length and the volume of the mitochondrial sheath. Sperm head dimensions are not related to either genome mass or chromosome number, and there are no relationships between sperm morphometry and the duration of oestrus.     

DNA fragmentation and sperm head morphometry in cat epididymal spermatozoa

Sperm DNA fragmentation is an important parameter to assess sperm quality and can be a putative fertility predictor. Because the sperm head consists almost entirely of DNA, subtle differences in sperm head morphometry might be related to DNA status. Several techniques are available to analyze sperm DNA fragmentation, but they are labor-intensive and require expensive instrumentations. Recently, a kit (Sperm-Halomax) based on the sperm chromatin dispersion test and developed for spermatozoa of different species, but not for cat spermatozoa, became commercially available. The first aim of the present study was to verify the suitability of Sperm-Halomax assay, specifically developed for canine semen, for the evaluation of DNA fragmentation of epididymal cat spermatozoa. For this purpose, DNA fragmentation indexes (DFIs) obtained with Sperm-Halomax and terminal deoxynucleotidyl transferase–mediated nick-end labeling (TUNEL) were compared. The second aim was to investigate whether a correlation between DNA status, sperm head morphology, and morphometry assessed by computer-assisted semen analysis exists in cat epididymal spermatozoa. No differences were observed in DFIs obtained with Sperm-Halomax and TUNEL. This result indicates that Sperm-Halomax assay provides a reliable evaluation of DNA fragmentation of epididymal feline spermatozoa. The DFI seems to be independent from all the measured variables of sperm head morphology and morphometry. Thus, the evaluation of the DNA status of spermatozoa could effectively contribute to the completion of the standard analysis of fresh or frozen semen used in assisted reproductive technologies.     

Seasonal dynamics of sperm morphometric subpopulations and its association with sperm quality parameters in ram ejaculates

Sperm morphologic assessment is considered an irreplaceable part of standard laboratory routine analyses in the diagnosis of male fertility. Thus, in an attempt to quantify the effects of season on sperm morphology and its functional significance in relation to sperm quality parameters, sperm head morphometric traits were analyzed by using an objective computerized analysis combined with principal components analysis (PCA) cluster analysis to establish the relationship between the distribution of the subpopulations found and sperm quality in each season. There were slight variations on sperm motility and sperm membrane integrity indexes (P > 0.05). However, the mean values for sperm concentration substantially changed among seasons in all individuals studied (P < 0.01). There were significant differences in sperm morphometric parameters (P < 0.01) as well as in the distribution of morphometric subpopulations between seasons (P < 0.001). In conclusion, this study confirmed that there was an important seasonal effect on sperm morphometric traits. In addition, the distribution of these subpopulations seems to be related to the season studied and the ejaculate quality which would be a very important indicator of sperm function. The substantial information derived from these morphometric subpopulations has provided new knowledge which can be used in future studies using sperm morphometry as a seasonal indicator in ram ejaculates.     

A triple-stain flow cytometric method to assess plasma- and acrosome-membrane integrity of cryopreserved bovine sperm immediately after thawing in presence of egg-yolk particles

Simultaneously evaluating postthaw viability and acrosome integrity of spermatozoa by flow cytometry would provide a valuable testing tool in both research and routine work. In the present study, a new triple-stain combination was developed for the simultaneous evaluation of viability and acrosome integrity of bovine sperm processed in egg yolk-based extender by flow cytometer. SYBR-14 and propidium iodide (PI) enabled the discrimination of sperm cells from egg yolk and debris particles, which was instrumental for the flow cytometric analyses of frozen-thawed bovine sperm, because it implied that washing steps to remove egg yolk were no longer required. In addition, phycoerythrin-conjugated peanut agglutinin (PE-PNA) was used to discriminate acrosome-damaged/reacted sperm cells from acrosome-intact cells. Repeatability was calculated using two processed ejaculates of 10 bulls. Three straws per batch were analyzed in duplicate measurements. Method-agreement analysis between the SYBR-14/PE-PNA/PI and fluorescein isothiocyanate (FITC)-conjugated PNA was performed, with FITC-PNA/PI staining being carried out on 14 frozen-thawed semen samples immediately after thawing and after a 3-h incubation at 37 degrees C. The British Standards Institution repeatability index of the SYBR-14/PE-PNA/PI combination was 2.6%. On average, the FITC-PNA/PI method showed a 6.3% overestimation of the live and acrosome-intact sperm cell subpopulation. In conclusion, the new triple-stain combination is highly repeatable and easy to use in routine application, and it provides a more precise estimate for the rate of sperm cells with intact head membrane and acrosome compared to the generally used and validated FITC-PNA/PI staining.     

Evaluation of seasonal variations of semen freezability in Leccese ram

The experiment was carried out in Southern Italy (41 degrees N latitude) to examine the effects of seasonal variations of semen freezability in Leccese ram. Semen from five rams, collected every 2 weeks for a whole year, was frozen in straws, using a system based on Tris-fructose egg yolk as extender to constitute semen doses of 100x10(6) spermatozoa. Post-thaw survival and acrosomal status of cells were assessed by dual staining by Hoechst 33258 and FITC-PSA. Three different forms of fluorescence distribution were displayed indicating sperm without acrosome (unstained cells), sperm with damaged acrosome (cells with incomplete fluorescence over the head), sperm with widespread fluorescence (cells completely fluorescent). Motility and kinetic rating at thawing and after 1 and 3h incubation (37 degrees C) were also assessed.Semen frozen in summer and autumn, corresponding to the breeding season, showed the highest (P<0.01) post-thaw survival of spermatozoa (41.7%) and the lowest (P<0.01) incidence of spermatozoa with damaged acrosome. The positive influence of the summer-autumn period was expressed also on motility and kinetic rating of spermatozoa at thawing. The integrity of the acrosomal membrane was positively correlated (P<0.01) with sperm viability before processing (r=0.32) and after thawing (r=0.51).In conclusion, the results show that season exerts a significant influence on semen freezability in Leccese ram, with the best performance occurring the summer and autumn period, corresponding to the reproductive season in temperate zones.     

Evaluation of sperm tail membrane integrity by light microscopy

During routine evaluation of trypan blue-Giemsa stained semen smears, sperm cells can be found with unstained heads and with stained tails. It was hypothesized that these cells were immotile and should not be considered as live. Sperm motility was determined in isoosmotic, and presumably isotonic trypan blue-stained wet preparations. Bull, ram and boar semen smears were stained with hypoosmotic trypan blue-Giemsa to compare the relationship between the percentage of stained sperm tails and the percentage of sperm tails remaining straight under hypoosmotic conditions. Actively moving spermatozoa with unstained heads, but with stained tails were never observed in wet preparations. The correlation coefficient found between the percentage of sperm with stained tails and the percentage with straight tails was 0.81, 0.94 and 0.85 for bull, ram and boar spermatozoa, respectively. Results of this study show that sperm cells with an intact head membrane, but a stained and presumably membrane-damaged tail are not motile. Therefore these cells should be included in the dead category rather than alive in the usual live-dead studies with vital stains.