Jeffrey S. Stevenson

Effect of stage of the estrous cycle on interval to estrus after PGF2α in beef cattle

Abstract Effect of stage of the estrous cycle at the time of prostaglandin F 2α (PGF 2α ) (b) injection on subsequent reproductive events in beef females was studied in four trials involving 194 animals. Cycling animals were given two injections of 25 mg PGF 2α 11 days apart or, in some cases, the interval was altered to allow the second injection to fall on a specific day of the cycle. Day of estrous cycle at time of the second injection was determined by estrous detection. Interval from the second PGF 2α injection to the onset of estrus (interval to estrus) was shorter (P 2α injection on either day 7 or day 14 declined linearly (P 2α injection had no effect on rate of progesterone decline, even though heifers injected on day 7 had a shorter (P 2α injection were treated on days 5 through 8 of the cycle, indicating that PGF 2α was less effective in regressing the corpus luteum between days 4 and 9 of the cycle than later in the cycle.

Detection of anovulation by heatmount detectors and transrectal ultrasonography before treatment with progesterone in a timed insemination protocol

Our objective was to determine the accuracy of identifying noncycling lactating dairy cows before the application of a timed artificial insemination (AI) protocol [with or without progesterone supplementation via a controlled internal drug-release (CIDR) insert and 2 different timings of AI] by using heatmount detectors and a single ovarian ultrasound examination. At 6 locations in the Midwest, 1,072 cows were enrolled in a Presynch protocol (2 injections of PGF(2alpha) 14 d apart), with the second injection administered 14 d before initiating the Ovsynch protocol (injection of GnRH 7 d before and 48 h after PGF(2alpha) injection, with timed AI at 0 or 24 h after the second GnRH injection). Heatmount detectors were applied to cows just before the first Presynch injection, assessed 14 d later at the second Presynch injection (replaced when activated or missing), and reassessed at initiation of the Ovsynch protocol. Ovaries were examined for the presence of a corpus luteum (CL) by ultrasound before the initiation of treatment. Treatments were assigned to cows based on the presence or absence of a CL detected by ultrasound: 1) no CL + no CIDR; 2) no CL + CIDR insert for 7 d; and 3) CL present. Further, alternate cows within the 3 treatments were assigned to be inseminated concurrent with the second GnRH injection of Ovsynch (0 h) or 24 h later. Pregnancy was diagnosed at 33 and 61 d after the second GnRH injection. By using low (<1 ng/mL) concentrations of progesterone in serum as the standard for noncycling status, heatmount detectors were activated on a large percentage of noncycling cows (>60%), whereas the single ultrasound examination incorrectly classified noncycling cows only 21% of the time. Conversely, cycling cows (progesterone > or =1 ng/mL) were correctly identified 70 to 78% of the time by heatmount detectors, but 85 to 92% were correctly identified by ultrasound. Overall accuracy of heatmount detectors and ultrasound was 71 and 84%, respectively. Application of progesterone to cows without a CL at the time of the first injection of GnRH reduced the incidence of ovulation but increased the proportions of pregnancies per AI at d 33 or 61 compared with nontreated cows without a CL at the onset of the Ovsynch protocol. Percentages of cows pregnant and pregnancy survival did not differ for cows having a CL before treatment compared with those not having a CL and treated with progesterone. Compared with no response, when a follicle ovulated in response to the first GnRH injection, percentage of cows becoming pregnant after the timed AI increased from 33.3 to 41.6%. Timing of AI at 0 or 24 h after the second GnRH injection did not alter pregnancies per AI, but cows having luteal activity before treatment had improved pregnancies per AI compared with noncycling cows. We conclude that identifying noncycling cows by ultrasound was more accurate than by heatmount detectors. Subsequent progesterone treatment of previously cycling cows not having a CL at the onset of Ovsynch increased the proportion of pregnant cows, equal to that of cows having a CL but not treated with progesterone.

Influence of early estrus, ovulation, and insemination on fertility in postpartum Holstein cows☆☆☆

Abstract Our objective was to determine the effects of early estrus and ovulation on subsequent reproductive performance in Holstein cows (n=80) first inseminated after 40 days postpartum. Blood for radioimmunoassayable progesterone was collected twice weekly between calving and day 85 postpartum to determine ovulation frequency. Changes in serum progesterone concentration and visual observation of estrus were used to estimate first and subsequent ovulations and duration of estrous cycles before first service. Reproductive performance was measured by first-service conception rates, days open, and total services per conception. Interval to first ovulation was 19±1 days (X±SE), whereas interval to first detected estrus averaged 45±3 days. Cows had 3±0.1 and 1.6±0.1 estrous cycles that were ovulatory, and 1.5±0.1 and 1.3±0.1 estrous cycles that were ovulatory and involved detected heats through first service and by 40 days postpartum, respectively. Intervals to first service were prolonged when: 1) first ovulations were delayed beyond 4 wk; 2) when first expressed heats were delayed beyond 60 days postpartum; and 3) when first estrous cycles were longer than 24 days. Intervals from calving to conception were extended when cows failed to show estrus before day 60 postpartum and when interval to first service was prolonged. Postpartum fertility was improved (higher frist-service conception rates) when cows had one or two heats by day 40 and when first inseminated before day 60 postpartum. Failure to express estrus was associated with uterine infection, persistent luteal function, and(or) prolonged anovulation. Estrus by day 40 postpartum appeared to be a good indicator of the reproductive status of the dairy herd because fertility and overall reproductive performance was improved by early reestablishment of ovarian cycles and estrous expression.

Control of the estrous cycle to improve fertility for fixed-time artificial insemination in beef cattle: a review.

Early estrus-synchronization protocols focused on regressing the corpus luteum (CL) with an injection of PGF(2alpha) followed by detection of estrus or involved the use of exogenous progestins that prevent estrus from occurring. Later, protocols combining the use of PGF(2alpha) and exogenous progestins were developed. Gonadotropin-releasing hormone was utilized to control follicular waves, synchronize ovulation, or to luteinize large dominant follicles. Our research aimed to develop reliable protocols that 1) relied solely on fixed-timed AI (TAI); 2) required a maximum of 3 animal handlings, and 3) were successful in estrous-cycling and noncycling females. In cows, insertion of an intravaginal progesterone insert during the 7-d interval between the initial GnRH and PGF(2alpha) injections enhanced pregnancy rates by 9 to 10%. In a multi-location study, a TAI protocol yielded pregnancy rates similar to a protocol involving detection of estrus plus a fixed-time clean-up AI for females not detected in estrus (54 vs. 58%, respectively, for cows and 53 vs. 57%, respectively, for heifers). Initiation of estrous cycles in noncycling cows is likely the primary manner in which beef producers may improve fertility in response to estrus synchronization and TAI protocols. Treatment of noncycling females with progesterone and GnRH increases the percentage of cycling females and improves fertility to a TAI, but inducing cyclicity with hCG failed to enhance fertility in TAI protocols. Supplementing progesterone after TAI failed to increase pregnancy rates in beef cattle. In contrast, administration of hCG 7 d after TAI induced an accessory CL, increased progesterone, and tended to enhance pregnancy rates. Development of TAI protocols that reduce the hassle factors associated with ovulation synchronization and AI provide cattle producers efficient and effective tools for capturing selective genetic traits of economic consequences. Location variables, however, which may include differences in pasture and diet, breed composition, body condition, postpartum interval, climate, and geographic location, affect the success of TAI protocols.

Supplementation of progesterone via controlled internal drug release inserts during ovulation synchronization protocols in lactating dairy cows

Our objective was to determine the effect of exogenous progesterone (P4) during a timed artificial insemination (TAI) protocol on pregnancies per AI (P/AI) in dairy cows not previously detected in estrus. Lactating cows (n=3,248) from 7 commercial dairy herds were submitted to a presynchronization protocol (2 injections of PGF(2alpha) 14 d apart; Presynch), and cows in estrus after the second PGF(2alpha) received AI (EDAI; n=1,583). Cows not inseminated by 12 to 14 d after the second PGF(2alpha) injection were submitted to a TAI protocol (GnRH on d 0, PGF(2alpha) on d 7, and GnRH+TAI 72h after PGF(2alpha)). At onset of the TAI protocol, cows were balanced by parity and days in milk and assigned randomly to receive no exogenous P4 (control, n=803) or a controlled internal drug release (CIDR) insert containing 1.38g of P4 from d 0 to 7 (CIDR, n=862). Blood samples were collected at the second PGF(2alpha) injection of the Presynch and on the day of the first GnRH injection of the TAI protocol for P4 determination. When P4 in both samples was <1 ng/mL, cows were classified as anovular, whereas cows having at least 1 sample >or=1 ng/mL were classified as cyclic. Concentration of P4 at 11 to 14 d after AI was determined in a subgroup of cows (n=453) from 2 herds. Pregnancy was diagnosed at 40+/-5 and 65+/-5 d after AI. Proportion of cows inseminated on estrus after the second PGF(2alpha) injection of the Presynch protocol differed among herds (range=26.7 to 59.8%). Overall P/AI for EDAI cows at 40+/-5 and 65+/-5 d were 36.2 and 33.7%, respectively, and pregnancy loss was 8.8%. Proportion of cyclic cows at the onset of the TAI protocol differed among herds (range from 66.5 to 86.3%), but did not differ between treatments (control=72.4%, CIDR=74.1%). Treatment affected P/AI at 40+/-5 (control=33.3%, CIDR=38.1%) and 65+/-5 (control=30.0%, CIDR=35.1%) d after AI but did not affect pregnancy loss (8.6%). Cyclic cows had greater P/AI at 40+/-5 (38.2 vs. 29.3%) and 65+/-5 d (35.1 vs. 26.1%) after AI, but cyclic status had no effect on pregnancy loss. Treatment affected P4 concentration after AI, with more CIDR cows having P4 >or=1 ng/mL (94.4 vs. 86.9%) and P4 >or=3.2 ng/mL (81.8 vs. 68.0%) at 11 to 14 d after AI compared with control cows. Treatment of cows not previously detected in estrus with a CIDR insert during a TAI protocol increased proportion of cows with functional CL after AI and P/AI.

Failure of timed inseminations and associated luteal function in dairy cattle after two injections of prostaglandin F2-alpha

Abstract Lactating Holstein cows (n = 235) were used to study changes in luteal function after two injections of prostaglandin F 2 -alpha (PGF 2 -alpha) were administered to induce estrus for timing the first postpartum inseminations. Cows were assigned randomly at parturition to two experimental groups and one control group. Control cows (n = 59) were inseminated at a spontaneous estrus beginning 40 d postpartum. The remaining cows were given two injections of PGF 2 -alpha 11 d apart, beginning 40 to 46 d postpartum. After the second injection (0 h), cows were 1) inseminated once at 80 h (n = 119) or 2) inseminated twice at 72 and 96 h (n = 57). Progesterone was measured in blood serum collected from all cows at 0 and 48 h after each injection of PGF 2 -alpha and from 48 cows throughout the anticipated luteal phase following the second injection. Conception rates of cows inseminated at 80 h (23%) and at 72 and 96 h (30%) after PGF 2 -alpha were lower (P 2 -alpha cows were detected in estrus, conception rate of twice-inseminated cows (55%) was similar to that of controls, whereas the rate of once-inseminated cows (38%) tended to be lower (P = 0.09). Lower conception rates after timed inseminations resulted from failure of PGF 2 -alpha to induce luteolysis (13% of cows) and the presence of low ( 2 -alpha. These results suggest that timed inseminations lowered conception rates after PGF 2 -alpha because of poor timing of insemination relative to estrual events, less than expected induced luteolysis, and to lack of anticipated luteal function at the time of the second injection of PGF 2 -alpha. The latter appeared to be the result of both prolonged postpartum anestrus and ovulatory failure following a previous injection of PGF 2 -alpha.

Prolonging the MGA-prostaglandin F2α interval from 17 to 19 days in an estrus synchronization system for heifers.

Our objective was to determine whether extending the interval from 17 to 19 d between removal of melengestrol acetate (MGA) feed and administration of PGF2 alpha would alter conception rates, pregnancy rates and the degree of synchrony in replacement beef heifers. A commercial heifer operation in north-central Kansas purchased 591 Angus x Hereford heifers from 12 sources. Prior to the spring breeding season, 14% of the heifers were culled. The remaining heifers were assigned randomly to 2 MGA-PGF2 alpha synchronization systems. All heifers were fed MGA (0.5 mg/head/d) for 14 d, and PGF2 alpha was administered either 17 or 19 d after the completion of MGA feeding. Heifers were inseminated artificially for 30 d followed by 30 d of natural mating. Based on each source, first-service conception rates ranged from 66 to 90%, whereas overall pregnancy rates ranged from 91 to 100%. Heifers given PGF2 alpha on Day 17 after MGA had first-service conception rates of 75.9% compared with 81.4% for heifers receiving PGF2 alpha on Day 19. In response to the PGF2 alpha injection, 99% of the Day 19 heifers that were detected in estrus were inseminated artificially by 72 h after the PGF2 alpha injection, whereas 74% of the heifers in the Day 17 treatment were inseminated by that time. Average interval to artificial insemination (AI) after PGF2 alpha was greater (P < 0.01) for the Day 17 heifers (73.1 +/- 1.1 h) than for the Day 19 heifers (56.2 +/- 1.1 h). No differences in conception rates or overall pregnancy rates occurred; however, heifers receiving PGF2 alpha on Day 19 after MGA had shorter intervals to estrus, and a greater proportion was inseminated within 72 h after PGF2 alpha, thus possibly facilitating successful timed insemination of the remaining heifers not yet inseminated by that time.

Interrelationships of lactation and postpartum anovulation in suckled and milked cows

Abstract Reproduction is a major factor limiting efficiency of beef and dairy cattle production. Onset of lactation and reestablishment of postpartum estrous cycles are energy-competing processes, with lactation having a greater priority for dietary nutrients and body reserves through homeorhetic controls. Prolonged postpartum anestrus or anovulation limits reproductive efficiency by delaying or preventing conception. Suckling or milking frequency (> 4 × daily) delays first ovulation longer than 2 × milking. However, mere presence of a calf (own or foster) to which the cow (udder-intact or mastectomized) is bonded delays onset of postpartum ovulation. Furthermore, anovulation was prolonged when cows maintained a bond with their own calves while their milk is harvested by an unrelated suckling calf, but not when removed by 2 × milking. Although continuous presence of a nonsuckling calf prolongs anovulation only slightly, yield and composition of milk for cows milked 2 × daily are greater due to increased synthesis or ejection of milk associated with calf presence. When lactation is interrupted 13 to 18 days after calving and normal suckling, cows ovulated during the next 4 weeks while neither milked nor suckled. When these cows were reunited with their calves after 4 weeks to provide ad libitum suckling, milk secretion was reinitiated successfully. Suckling plus milking increases milk yield beyond milking alone at similar harvest frequencies. Greater milk yield in milked cows, associated with increased energy deficits and increased milking frequency, inhibits estrual expression to a greater extent than the onset of postpartum ovulation. Energy balance is the key to the timing of first postpartum ovulation in milked cows. Acute, dynamic changes in energy balance during early lactation or at weaning, rather than absolute magnitude of energy balance, provide the cow information about its metabolic status. Cows respond to positive changes in energy balance by resuming ovarian cycles during energy deficiency. Ovarian follicular development and resumption of follicular waves in suckled and milked cows do not limit early ovulation but rather the failure of dominant follicles to ovulate in the face of inadequate LH pulse frequency. Further work is needed to elucidate which metabolic signals serve as effectors of increased pulsatile LH secretion and their pivotal role in reinitiating first postpartum follicular maturation and ovulation in cattle.

Prostaglandin F2α and gonadotropin-releasing hormone administration improve progesterone status, luteal number, and proportion of ovular and anovular dairy cows with corpora lutea before a timed artificial insemination program1

The objective of this research was to increase the proportion of cows with at least 1 functional corpus luteum (CL) and elevated progesterone at the onset of the timed artificial insemination (TAI) protocol. Postpartum Holstein cows in one herd were stratified by lactation number at calving (September 2009 through August 2010) and assigned randomly to 2 treatments: 1) Presynch-10 (n=105): two 25-mg injections of PGF(2α) (PG) 14 d apart (Presynch); and 2) PG-3-G (n=105): one 25-mg injection of PG 3 d before 100-μg GnRH (Pre-GnRH) injection, with the PG injection administered at the same time as the second PG injection in the Presynch-10 treatment. Cows were enrolled in a TAI protocol [Ovsynch; injection of GnRH 7 d before (GnRH-1) and 56 h after (GnRH-2) PG injection with AI 16 to 18 h after GnRH-2] 10 d after the second or only PG injection. Blood samples for progesterone or estradiol analyses were collected on median days in milk (DIM): 36, 39, 50, 53 (Pre-GnRH), 60 (GnRH-1), 67 (PG), 69 (GnRH-2), and 70 (TAI). Ovarian structures were measured by ultrasonography on median DIM 53, 60, 67, 69, and 6 d post-TAI to determine follicle diameters, ovulation response to GnRH, or both. Although progesterone concentration did not differ between treatments before Pre-GnRH injection, the proportion of cows with at least 1 CL tended to be greater for PG-3-G than Presynch-10 cows, and more PG-3-G cows ovulated after Pre-GnRH injection than ovulated spontaneously in Presynch-10. Further, the diameter of follicles that ovulated tended to be smaller in PG-3-G than in Presynch-10 cows after Pre-GnRH injection. At GnRH-1, the proportion of cows with progesterone ≥1 ng/mL, the number of CL per cow, and the proportion of cows with at least 1 CL were greater for PG-3-G than Presynch-10. Neither follicle diameter nor percentage of cows ovulating after GnRH-1 differed between treatments. At PG injection during the week of TAI, progesterone concentration and the proportion of cows with progesterone ≥1 ng/mL tended to be greater for PG-3-G than Presynch-10, and PG-3-G had more CL per cow than Presynch-10. No ovarian characteristics differed between treatments after GnRH-2, including progesterone concentration, number of CL per cow, and total luteal volume 7 d after GnRH-2. Many of the previous ovarian traits were improved in both ovular and anovular cows after PG-3-G compared with Presynch-10. Pregnancies per AI at d 32 and 60 were only numerically greater for PG-3-G than for Presynch-10 cows, largely because of differences detected during months without heat stress. We concluded that the PG-3-G treatment increased ovulation rate and luteal function 7 d before the onset of Ovsynch, resulting in improved follicular synchrony and predisposing potentially greater pregnancies per AI in lactating dairy cows.

Conception rates of dairy cows following early not-pregnant diagnosis by ultrasonography and subsequent treatments with shortened Ovsynch protocol

Our objective was to determine the feasibility of prompt reinsemination of dairy cows when diagnosed not pregnant 27-29 days after first-service timed AI (TAI). We assumed that a first-wave dominant follicle was present at that time that would ovulate in response to GnRH once precocious luteal regression was induced after administration of PGF(2alpha). Cows that had not been detected in estrus and reinseminated by Days 27-29 after a first-service TAI were diagnosed not pregnant by ultrasonography. Nonpregnant cows from three herds were assigned randomly to receive either no further treatment until reinsemination (controls; n=189); 25mg i.m. of PGF(2alpha) and then reinsemination according to detected estrus (81 of 108) or at 72-80h after PGF(2alpha) treatment (PGF) in the absence of estrus (27 of 108); or 25mg i.m. of PGF(2alpha) followed by 100 microg i.m. of GnRH 48h later (PGF+GnRH) and then reinsemination after detection of estrus (9 of 160) or at 16-20h after GnRH (151 of 160). Blood samples were collected at the time of the not-pregnant diagnosis and again 48h later. Concentrations of progesterone before treatment with PGF(2alpha) were elevated (<1ng/ml) in 61% of the cows when PGF(2alpha) was administered and 81% of the cows given PGF(2alpha) had low (<1ng/ml) concentrations of progesterone 48h after PGF(2alpha). Treated cows were re-inseminated earlier (P<0.01; 31+/-1days) after first-service TAI than controls (55+/-1days). Conception rates after treatment were not different among treatments: PGF (22%), PGF+GnRH (23%), and control (23%). Average intervals from calving to conception were 22-23 days less (P<0.001) in treated cows than in controls. We concluded that treating nonpregnant cows with PGF(2alpha) on Days 27-29 after insemination produced acceptable conception rates when inseminations were made after detected estrus or when TAI was used after GnRH treatment. Further, both treatments reduced days between first-service TAI and second inseminations, and days from calving to conception.