J.A. Weber

Time of embryo transport through the mare oviduct.

The objectives of this study were 1) to determine the time of embryo transport through the mare oviduct, 2) to determine whether equine embryos increase in diameter prior to the time of oviductal transport, and 3) to assess the stage of equine embryonic development at the time of oviductal transport. The time of oviductal transport (interval from ovulation to uterine entry) was estimated by collecting embryos from the mare oviduct or uterus at 2-hour intervals from 120 to 168 h postovulation. The time of oviductal transport was 130 to 142 h, since 9 9 embryos were located in the oviduct from 120 to 128 h; 7 14 embryos were in the oviduct and 7 14 embryos were in the uterus from 130 to 142 h; and 13 14 embryos were in the uterus from 144 to 168 h postovulation. Embryos collected during the period of oviductal transport (130 h to 142 h) were not significantly larger (P>0.1) in diameter than embryos collected prior to the period of oviductal transport (162.5+/-3.7 vs 156.7+/-3.1 mum, respectively). During the period of oviductal transport, embryos collected from the uterus were not significantly larger (P>0.1) in diameter than embryos collected from the oviduct (160.7+/-3.2 vs 164.3+/-7.0 mum, respectively). During this same period 12 14 embryos were compact morulae, and 2 14 embryos were blastocysts.

Seminal collection, seminal characteristics and pattern of ejaculation in llamas

Semen was collected from 10/10 llamas during 26/30 (87%) collection attempts using an artificial vagina mounted inside a surrogate female. For the 26 semen collections, the duration of copulation (mount to dismount) with the artificial vagina was 31.7 +/- 12.0 min (mean +/- SD). Seminal pH was 8.1 +/- 1.1, and seminal volume per collection was 3.0 +/- 1.9 ml. Sperm concentration per collection was 1.0 +/- 0.8 x 10(6) sperm/ml, total number of spermatozoa was 2.9 +/- 3.1 x 10(6), total sperm motility was 23.7 +/- 20.0%, and the percentage of morphologically normal spermatozoa was 39.7 +/- 18.5%. Morphologically abnormal spermatozoa were categorized according to abnormal heads (20.1 +/- 19.9%), tail-less heads (8.7 +/- 8.9%), abnormal acrosomes (12.9 +/- 12.4%), abnormal midpieces (1.0 +/- 3.7%), cytoplasmic droplets (11.1 +/- 12.4%), and abnormal tails (6.6 +/- 12.0%). There were 0.3 +/- 0.3 million motile, morphologically normal spermatozoa per collection: less than 1000 during the first 5 min of copulation, 0.01 +/- 0.01 x 10(6) between 5 and 10 min of copulation, 0.04 +/- 0.08 x 10(6) between 10 and 15 min of copulation, 0.09 +/- 0.21 x 10(6) between 15 and 20 min of copulation, and 0.15 +/- 0.28 x 10(6) between 20 min and the end of copulation.

Corpus luteal function in nonpregnant mares following intrauterine administration of prostaglandin E2 or estradiol-17β

The objective of this study was to test the hypothesis that intrauterine administration of prostaglandin E(2) (PGE(2)) or estradiol-17beta (E-17beta) would prolong CL function in nonpregnant mares. Nonpregnant mares were continuously infused with 240 mug/d of PGE(2), 6 mug/d of E-17beta, or vehicle (sham-treated) on Days 10 to 16 post ovulation (ovulation = Day 0), using osmotic minipumps surgically placed into the uterine lumen on Day 10 (n = 11 per group). Nonpregnant and pregnant mares served as negative and positive controls, respectively (n = 11 per group). Mares were defined as having prolonged CL function if plasma progesterone remained > 2.5 ng/ml and if ovulation did not occur on Days 9 to 30. Corpus luteal function was prolonged until Day 30 in 1 11 nonpregnant mares, 4 11 sham-treated mares, 6 11 E-17beta-treated mares, 8 11 PGE(2)-treated mares, and 11 11 pregnant mares. The incidence of prolonged CL function was similar (P=0.16) in the sham-treated and nonpregnant mares. The hypothesis that PGE(2) would prolong CL function in nonpregnant mares was supported, since the incidence of prolonged CL function was higher (P=0.003) in PGE(2)-treated versus nonpregnant mares, tended to be higher (P=0.09) in PGE(2)-versus sham-treated mares, and was not lower (P=0.11) in PGE(2)-treated versus pregnant mares. The hypothesis that E-17beta would prolong CL function in nonpregnant mares was not supported, since the incidence of prolonged CL function was not higher (P=0.34) in E-17beta-versus sham-treated mares, and was lower (P=0.02) in E-17beta-treated versus pregnant mares. These results demonstrate that intrauterine administration of a pharmacologic dose of PGE(2) initiated prolonged CL function in nonpregnant mares. Further experiments are needed to confirm the role of conceptus secretion of PGE(2) in CL maintenance, and to determine the mechanism of action of PGE(2) within the equine reproductive tract.

EJACULATORY PATTERN OF LLAMAS DURING COPULATION

The objective of this study was to use transrectal digital palpation of urethral pulses to define the ejaculatory pattern of llamas during copulation. Five male llamas were palpated during 5 to 6 copulations each with receptive female llamas (n = 28 copulations). The time from first exposure of a male to a female until mounting was 0.7 +/- 1.1 min (mean +/- SD), time to the first intromission was 1.7 +/- 1.4 min, and time from initial mount to final dismount (copulation duration) was 21.7 +/- 7.8 min. A total of 121.9 +/- 61.0 urethral pulses per copulation (5.6 +/- 1.7 pulses/min) was palpated. During the first 3.9 +/- 3.7 min of copulation, urethral pulses (11.0 +/- 10.1 urethral pulses at 3.5 +/- 2.5 pulses/min) occurred randomly and were not associated with whole-body strains. After the first 4 min of copulation, urethral pulses occurred in a pattern of clusters of frequent urethral pulses associated with whole-body strains, alternating with intercluster intervals of infrequent urethral pulses without whole-body strains. Individual clusters were characterized by 4.3 +/- 2.7 urethral pulses at 16.7 +/- 4.5 pulses/min during strains, and intercluster intervals were characterized by 1.7 +/- 2.3 urethral pulses at 2.2 +/- 1.8 pulses/min. Each cluster of urethral pulses during a strain was preceded by 2.3 +/- 1.8 repositions of the males hindlegs and by 38.1 +/- 20.8 pelvic thrusts. There were 18.5 +/- 10.6 clusters of urethral pulses accompanied by strains per copulation at 0.9 +/- 0.3 clusters/min. The 18 to 19 clusters of urethral pulses appeared to be individual ejaculations. Therefore, we hypothesize that llamas ejaculated 18 to 19 times during their 22-min copulations.

Prostaglandin E2-specific binding to the equine oviduct

Prostaglandin E2 (PGE2) bound specifically (P less than 0.001) to ampullary and isthmic tissue on Day 2 and Day 5 after ovulation. No significant differences (P greater than 0.8) were detected between Day 2 and Day 5 in the specific binding of ampullary or isthmic tissue. Significantly more (P less than 0.05) PGE2 bound specifically to ampullary versus isthmic tissue on both days. Detection of PGE2-specific binding in the oviductal isthmus on Day 2 and Day 5 indicates that the oviduct is responsive to PGE2 when it is capable of transporting equine embryos.

Autotransfer of Day 4 embryos from oviduct to oviduct versus oviduct to uterus in the mare

Embryo autotransfer is defined as the collection of an embryo from and the transfer of this embryo into the same animal. The objectives of this study were to: 1) test the hypothesis that oviduct transport of the equine embryo from the oviduct into the uterus is not dependent on a unilateral embryo-corpus luteum interaction, 2) develop an embryo autotransfer technique for the mare and 3) compare the success rates of Day 4 embryos surgically autotransferred from the oviduct ipsilateral to ovulation to either the oviduct (n=10 mares) or the uterine horn (n=10 mares) contralateral to ovulation. Seventy percent (7 10 ) of the Day 4 embryos which were autotransferred to the oviduct contralateral to ovulation were transported through the oviduct and subsequently developed into embryonic vesicles detectable by ultrasonography between 10 and 21 days postovulation. This finding supported the hypothesis that oviductal embryo transport is not dependent upon the ipsilateral corpus luteum. Overall, sixty percent (12 20 ) of the autotransfers were successful. The success rate of uterine-transferred embryos was not significantly less (P>0.3) than that of oviductal-transferred embryos (5 10 vs 7 10 , respectively). Therefore, the Day 4 equine embryos were apparently mature enough to survive in the mares uterus.

Co-culture of day-5 to day-7 equine embryos in medium with oviductal tissue

Oviductal and uterine embryos were collected from mares at 5 to 7 days following ovulation 1) to evaluate the effects of oviductal tissue explants on in vitro growth and development of equine embryos and 2) to study the morphologic development of equine embryos in culture. Embryos were incubated for 5 days in a medium (control group) or in medium supplemented with oviductal tissue explants (co-culture group). Embryos were evaluated and the media changed daily. Following 5 days in culture, 10 10 (100%) control embryos and 27 29 (93%) co-cultured embryos had doubled in diameter. All embryos that were recovered as morulae developed to the blastocyst stage in culture. By 5 days in culture, 6 10 (60%) control embryos and 19 29 (66%) co-cultured embryos had reached the hatching blastocyst stage of development. By 3 days in culture, significantly more (P<0.05) control embryos versus co-cultured embryos had degenerated (4 10 vs 2 29 , respectively). By 5 days in culture, significantly more (P<0.01) control embryos versus co-cultured embryos had degenerated (6 10 vs. 3 29 , respectively). Embryos cultured with oviductal tissue were sustained longer than embryos cultured in medium alone. Hatching was characterized by the blastocyst squeezing through a small opening in the zona pellucida or by the zona pellucida thinning over approximately half of the blastocyst surface and subsequently disappearing entirely.

Prostaglandin E2 secretion by day-6 to day-9 equine embryos

Prostaglandin E2 (PGE2) secreted by Day-6, Day-7, Day-8 and Day-9 equine embryos (ovulation = Day 0) during in vitro incubation was measured by radioimmunoassay. Embryonic PGE2 secretion (ng/embryo/24 hr) was detectable on Day 6 (0.27 +/- 0.39), tended to increase (P less than 0.1) on Day 7 (0.57 +/- 0.88), and increased significantly (P less than 0.05) on Day 8 (2.23 +/- 0.86) and Day 9 (4.13 +/- 0.71). Embryo diameter at the start of the incubation period was linearly correlated (P less than 0.01) to embryonic PGE2 secretion.

Transrectal Ultrasonography for the Evaluation of Stallion Accessory Sex Glands

This article reviews the capabilities of transrectal ultrasonography for determining the distribution of fluid and tissue within stallion accessory sex glands. Emphasis is placed on describing the normal ultrasonographic appearance of the accessory sex glands, excurrent ducts, and pelvic urethra of stallions during rest, after teasing, and after ejaculation and using this information to detect glandular abnormalities.

Location of equine oviductal embryos on Day 5 post ovulation and oviductal transport time of Day 5 embryos autotransferred to the contralateral oviduct

Abstract The location of equine embryos and their rate of transport through the mares oviduct prior to uterine entry on Day 6 post ovulation are not well defined. We tested the hypothesis that equine embryos are located at the ampullary-isthmic junction until just prior to uterine entry by attempting to recover Day 5 equine embryos from 4 separately flushed oviductal segments (ampulla, ampullary-isthmic junction, proximal isthmus and distal isthmus) of 16 bred mares. At least 1 embryo was located in the oviductal segment that included the ampullary-isthmic junction in each of 12 mares, and 1 embryo was located in the uterus of each of the 4 remaining mares. The recovery of most Day 5 embryos near the ampullary-isthmic junction less than 24 h before the expected time of uterine entry supports the hypothesis that equine embryos are retained for most of the oviductal period near the ampullary-isthmic junction and suggests that embryo transport through the oviductal isthmus is rapid. We estimated the rate of embryo transport through the entire oviduct by transferring Day 5 embryos from the ipsilateral to the contralateral oviducts of 9 mares and subsequently attempting to recover the embryos from the uterus at 36, 48 or 72 h post autotransfer. Fewer (P