R.L. Nebel

RELATIONSHIP OF SEMINAL TRAITS AND INSEMINATION TIME TO FERTILIZATION RATE AND EMBRYO QUALITY

The nature of subfertility due to the male or inseminate is as complex as that of the female. Fertilization failure or failure in embryogenesis are both documented to be of seminal origin. Males also differ in the numbers of sperm required to reach their maximum fertilization rate. Males requiring more sperm would be considered to have compensable seminal deficiencies. These include a number of known (viability and morphology) and unknown factors (functional or molecular traits) precluding sperm access to the ovum or ability to engage the ovum sufficiently to initiate fertilization and the block to polyspermy. Differences in fertility among males or inseminates independent of sperm dosage are considered uncompensable. These deficiencies would be associated with fertilizing sperm that are incompetent to maintain the fertilization process or subsequent embryogenesis once initiated, with most failures occurring prior to maternal recognition of pregnancy. Such sperm would preempt fertilization by competent sperm. Chromatin aberrations in morphologically normal or near normal spermatozoa from abnormal semen samples appear to be the best candidates for the uncompensable deficiency. However, recognition of uncompensable or incompetent fertilizing sperm has not been achieved. Six-day-old non-surgically recovered bovine ova/embryos have been used to evaluate compensable and uncompensable seminal deficiencies as well as to test reproductive strategies. These ova/embryos provide information on fertilization status and embryo quality as well as quantitative and qualitative data regarding associated accessory sperm. Thus, they permit the separation of reproductive failure by fertilization from that by embryonic development. Accessory sperm number is positively associated with both fertilization rate and embryonic quality. Early insemination results in low fertilization rates (low accessory sperm number), but good embryo quality, whereas, late insemination results in high fertilization rates (high accessory sperm number), but poor embryo quality. Additional studies will be necessary to substantiate this model; however, if true, future research designed to improve results to artificial insemination should be tested by breeding early in estrus where sperm viability is most limiting and embryo quality is best.

Relationship of semen quality to sperm transport, fertilization, and embryo quality in ruminants

Abstract Success of a mating is dependent upon both quality and quantity of semen delivered to the female. Males differ not only in fertility at all inseminate dosages, but also in the minimum number of sperm per inseminate required to reach maximum fertility. Thus, two aspects of a males semen quality become important — that which is compensable, where increasing sperm dosage to the female results in a response in fertility, and that which is uncompensable, where differences in fertility among males can no longer be removed by increasing sperm dosage. Compensable traits of semen are those believed to be associated with the inability of sperm to reach the site of fertilization or to initiate the block to polyspermy by penetration of the ovum vestments. Uncompensable traits appear to be associated with the inability of fertilizing sperm to sustain the fertilization process and/or development of the early embryo. It is now important in the evaluation of semen and the male that these two aspects of reproductive deficiency be considered independently. There is also accumulating evidence that low sperm numbers at the site of fertilization (low competition among sperm), due either to problems of male (inseminator) or female origin, may favor fertilization by less competent sperm that may be unable to complete the fertilization process or sustain the young embryo.

Automated electronic systems for the detection of oestrus and timing of AI in cattle

For the majority of dairy herds where artificial insemination (AI) is practiced, the limiting factor toward obtaining efficient reproductive performance is the failure to detect oestrus in a timely and accurate manner. Periodic visual observation has been the dominant method used to identify cows in oestrus. New approaches are being developed to provide automated systems of detection of oestrus using electronic technology. The goal of an oestrus detection program should be to identify oestrus positively and accurately in all cycling animals and consequently to identify animals not cycling. The ultimate goal should be to predict the time of ovulation, thus allowing for insemination that will maximize the opportunity for conception. Unfortunately, most studies designed to evaluate the optimal time of AI generally contained two technical deficiencies: inadequate numbers of cows for valid statistical comparisons and inaccurate knowledge of the onset of oestrus because of low frequency of visual observations and/or efficiency of methods used for the detection of oestrus. Studies using pedometry and a pressure sensing radiotelemetric system will be reviewed as each have independently obtained an optimal time of AI of 5 to 17 h after either the increase in locomotive activity or following the first standing event associated with the onset of oestrus.

Selected times of insemination with microencapsulated bovine spermatozoa affect pregnancy rates of synchronized heifers

This experiment was designed to test whether spermatozoa encapsulated in an alginate poly-L-lysine matrix had an extended fertile life in vivo after insemination. Estrus was synchronized in 417 primiparous Friesian and Jersey heifers with a system based on a CIDR-B intravaginal device before the heifers were inseminated either during proestrus (24 h after device removal) or at estrus (48 h after device removal). Pregnancy rates to first inseminations did not differ between the 24 and 48 h inseminations (61 vs 60.6%) with liquid semen diluted in Caprogen (control) but differed with encapsulated semen (45.1 vs 68.6%). The difference in pregnancy rates between the 2 types of semen was more pronounced (P < 0.08) in the animals that were visually detected in estrus. The mean survival time of spermatozoa in the female reproductive tract following insemination at the 24-h insemination time was estimated to be 50 +/- 7.5 h. The increased pregnancy rate with insemination of encapsulated spermatozoa at 48 h could have been due to this process predisposing spermatozoa to capacitate soon after insemination.

The educational implications of reproductive problems identified during investigations at Michigan dairy farms

This study constitutes the review of 44 dairy herd investigations that were initiated because of complaints relating to decreased reproductive efficiency. Each investigation was conducted at the request of the veterinary practitioner who provided the routine reproductive examinations and consultations at the farm. Thus the types of problems identified were those not resolved by routine veterinary care and management practices. A total of 4.5, 27.3 and 31.8% of the farms, respectively, failed to keep reproductive records, failed to maintain accurate records on events such as breeding dates, or failed to evaluate available summary reports with the local veterinary practitioner. Of the 44 farms, 50.0, 38.6, 54.5 and 11.4%, respectively, reported problems related to estrus detection rate, number of days to first service (for reasons other than estrus detection), conception rate and early embryonic death. Within each of these reproductive parameters specific problems were defined and discussed. Reproductive inefficiency was found to be most commonly associated with ineffective estrus detection and decreased conception rate. Most importantly, farm managers and employees frequently misunderstood the relationship between the accuracy of estrus detection and the conception rate (61.4% of the farms). We therefore identified factors which have an impact on dairy herd reproductive efficiency to suggest topics for training programs for producers and practicing veterinarians as well as for elective courses for veterinary students in the area of theriogenology.