The impact of bacteriospermia on boar sperm storage and reproductive performance.

Bacteriospermia is a documented risk to reproductive performance when using extended boar semen for artificial insemination. A substantial list of bacteria have been recovered from boar semen attributed to fecal, preputial, skin, and hair microorganisms, with these and other environmental bacteria from processing areas identified in doses prepared for artificial insemination. Gram-negative bacteria are most commonly recovered from extended doses, including both Enterobacteriaceae and environmental contaminants, such as those that inhabit water purification systems. The method of processing, distributing, and storing fresh liquid boar semen before insemination plays a role in bacterial growth dynamics and the degree to which the bacteria may damage the sperm or affect the sow. Not all bacterial isolates or contamination levels have the same impact on sperm, with multiple factors governing if and when storage longevity will be reduced through sperm-to-sperm agglutination, impaired motility, acrosome disruption, or loss of membrane viability. Suboptimal reproductive performance can occur because of reduced fertilizing capacity of the sperm or induction of a uterine environment hostile to sperm and/or embryonic survival. Effective bacterial control strategies are necessary to minimize the risk of bacteria contaminating extended semen doses, including monitoring programs designed for quick detection and intervention, should the need arise.

Determining sample size for the morphological assessment of sperm.

Morphologic assessment of spermatozoa is an integral component in the analysis of semen. Whether a technician rapidly screening semen quality at a commercial stud, a veterinarian performing breeding soundness examinations, a clinician at a reference andrology laboratory providing auditing or diagnostic services, or a researcher evaluating morphology as a part of a fertility study, it is important to make an informed decision regarding the number of spermatozoa to include in the morphology assessment. Application of basic statistical principles such as the nature of proportions, level of confidence in an observed value, and the interaction of sample size with precision, can and should be used in the decision process. This paper outlines in detail the application of these statistical principles in relation to the morphologic assessment of spermatozoa. Guidelines on how these principles can be utilized in practical situations are discussed. Additionally, methodologies for comparison of results within and between laboratories (an area easily prone to misinterpretation) are reviewed. It is hoped that through the use of these fundamental statistical principles, this paper will bring clarity and delineation to the science of quantifying the morphology of spermatozoa.

A technique for preserving retained distal cytoplasmic droplets in situ for immunofluorescence evaluation of ejaculated porcine spermatozoa.

Cytoplasmic droplets (CD) associated with mammalian sperm have traditionally been investigated after isolation from ejaculated sperm cells, or in fixed tissue sections from the epididymides. Many of the current techniques for preparing spermatozoa for immunofluorescence assay (IFA) induce separation of distal cytoplasmic droplets, particularly when membrane permeabilization is required. This article describes a technique capable of maintaining distal cytoplasmic droplets in situ on ejaculated porcine spermatozoa throughout the process of permeabilization and immunostaining. Key steps in this technique include fixation with 0.2%, glutaraldehyde, permeabilization with 0.05% TX-100, and microtube incubations for IFA. Utilizing glutaraldehyde fixation, this technique yielded a mean retention rate of 88% for distal cytoplasmic droplets on ejaculated porcine spermatozoa.

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

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

The fecundity of porcine semen stored for 2 to 6 days in Androhep and X-CELL extenders.

Extending the raw ejaculate prior to artificial insemination (AI) is beneficial, in part, due to the increased number of females that are bred from an ejaculate, along with prolonged shelf life of the semen. The objective of this study was to examine the affects of storage time on the fecundity of porcine semen diluted in 2 semen extenders, Androhep and X-CELL. A completely randomized design with a factorial arrangement of treatments was utilized in which 429 high quality, gel-free ejaculates from 48 boars were used in a timed, double insemination of 1,431 first-service gilts. The gilts were divided into groups and inseminated with semen stored in Androhep or X-CELL for 2 to 3 d, 3 to 4 d, 4 to 5 d, or 5 to 6 d prior to use (day of collection = Day 0). Sperm age was identical, and both extenders were used concurrently each day of the trial. Farrowing rate and litter size data were recorded. Farrowing rates did not differ between extenders through Days 4 to 5 of storage. Gilts inseminated with Androhep diluted stored semen showed a decrease (P < 0.001) in farrowing rate compared with those inseminated with semen extended in X-CELL stored for 5 to 6 d. Mean litter sizes did not differ between extenders through Days 2 to 3 of storage. Compared with the X-CELL extended semen, gilts inseminated with Androhep extended semen produced smaller litters when semen was stored for 4 to 5 d (P < 0.05). Within the Androhep treatment, smaller mean litter sizes (P < 0.05) were evident when the semen was stored for 3 to 4 and 4 to 5 d. No differences were detected in litter size or farrowing rate for gilts bred with semen stored for 2 to 6 d in the X-CELL extender (P > 0.1). The results of this study indicate that extender type influences the fertility potential of fresh porcine semen stored for 2 to 6 d. For optimal fecundity in gilts, semen extended with Androhep extender should be used for AI within 3 d. The X-CELL extended semen can be used for up to 6 d without significant decrease in litter size or farrowing rate. These recommendations are dependent upon using high quality semen that is properly handled from collection through insemination.