Effect of progesterone on some fertility performances in cattle (original) (raw)
Related papers
Theriogenology, 2005
The objectives of this study were to evaluate the effect using two doses of progesterone (P4) releasing devices in two different programs on reproductive performance of anestrous dairy cows. Cows (n = 1555) not detected in estrus by 10 d before the planned start of the seasonal breeding program and in which no CL was palpable were treated with an intravaginal P4-releasing device ('Single'; 1.56gofP4)oramodifieddevicewithtriplethenormalP4dose(′Triple′;1.56 g of P4) or a modified device with triple the normal P4 dose ('Triple'; 1.56gofP4)oramodifieddevicewithtriplethenormalP4dose(′Triple′;4.7 g of P4). The devices were in place for either 6 d ('Short') or 8 d ('Long'), with 1 mg estradiol benzoate (EB) given 24 h after device removal. The 'Long' program also included treatment with 2 mg EB at device insertion. The Long program resulted in a higher first service conception rate (RR = 1.18 (95% CI = 1.03-1.33); P = 0.02), but had no effect on the 28-d, 56-d or final pregnancy rate compared to the Short program. There were no effects of dose of P4 on any outcome. In conclusion, the Long compared to the Short program, but not the dose of P4, improved first service conception rates in anestrous cows. #
Journal of Dairy Science, 2009
The objectives were to evaluate the effect of supplemental progesterone during a timed artificial insemination (TAI) protocol on pregnancy per insemination and pregnancy loss. Lactating dairy cows from 2 dairy herds were presynchronized with 2 injections of PGF 2α 14 d apart, and cows observed in estrus following the second PGF 2α injection were inseminated (n = 1,301). Cows not inseminated by 11 d after the end of the presynchronization were submitted to the TAI protocol (d 0 GnRH, d 7 PGF 2α , d 8 estradiol cypionate, and d 10 TAI). On the day of the GnRH of the TAI protocol (study d 0), cows were assigned randomly to receive no exogenous progesterone (control = 432), one controlled internal drug-release (CIDR) insert (CIDR1 = 440), or 2 CIDR inserts (CIDR2 = 440) containing 1.38 g of progesterone each from study d 0 to 7. Blood was sampled on study d 0 before insertion of CIDR for determination of progesterone concentration in plasma, and cows with concentration <1.0 ng/mL were classified as low progesterone (LP) and those with concentration ≥1.0 ng/ mL were classified as high progesterone (HP). From a subgroup of 240 cows, blood was sampled on study d 3, 7, 17 and 24 and ovaries were examined by ultrasonography on study d 0 and 7. Pregnancy was diagnosed at 38 ± 3 and 66 ± 3 d after AI. Data were analyzed including only cows randomly assigned to treatments and excluding cows that were inseminated after the second PGF 2α injection. The proportion of cows classified as HP at the beginning of the TAI protocol was similar among treatments, but differed between herds. Concentrations of progesterone in plasma during the TAI protocol increased linearly with number of CIDR used, and the increment was 0.9 ng/mL per CIDR. The proportion of cows with plasma progesterone ≥1.0 ng/ mL on study d 17 was not affected by treatment, but a greater proportion of control than CIDR-treated cows had asynchronous estrous cycles following the TAI protocol. Treatment with CIDR inserts, however, did not affect pregnancy at 38 ± 3 and 66 ± 3 d after AI or pregnancy loss.
Animal reproduction science, 2008
A study on postpartum dairy cows was done to evaluate the effect of using progesterone intravaginal device (CIDR) to synchronize return to oestrus of previously timed inseminated (TAI) cows and to evaluate embryo survival and pregnancy rate in the return to oestrus cows. All cows were subjected to TAI program. On Day 14 after AI, cows were assigned randomly into two groups: treated group (CTAI; n=126) and control group (TAI; n=172). Every cow in the CTAI group received CIDR device for 7 days. Cows were observed for oestrus after CIDR removal in the first period (Days 21-28). Cows, which did not show oestrus, were retreated with CIDR on Day 28 for 7 days and they were observed for oestrus after CIDR removal in the second period (Days 35-42). Pregnancy was diagnosed on Days 28, 45 and 90 after AI. In the first period, more cows in the CTAI group showed oestrus within 2.4 days after CIDR removal compared to cows within 4 days in the control. In the second period, more cows in the CTAI ...
Brazilian Journal of Veterinary Research and Animal Science, 2018
The effect of injectable progesterone was evaluated along with estradiol benzoate (EB) on the fate of the dominant follicle (DF) present in the ovary at the beginning of low progesterone-based TAI protocol. All cattle were given 500 µg cloprostenol im (PGF; Schering-Plough Animal Health for Estrumate, Pointe-Claire, QC, Canada) twice, 11 d apart, and allocated into two groups: Estradiol group (E group, n = 11) and Estradiol-Progesterone group (EP group, n = 11). Ten days after the second PGF (Day 0), all cattle were given an intravaginal progesterone device with half progesterone concentration (Cue-Mate with a single pod containing 0.78 g progesterone). Concurrently, all cattle were given 1.5 mg im of estradiol benzoate in 3 mL of canola oil and PGF im on Day 0 of the protocol in a crossover design, in which each cow received both treatments. Cows in the EP group also received 100 mg im progesterone (Sigma) in 2 mL of canola oil. On Day 8, progesterone devices were removed and all c...
Journal of animal science, 2001
Four experiment stations (IL, KS, MN, and MO) conducted experiments to determine effects of introducing a CIDR (controlled internal device release) into an ovulation control program for postpartum suckled beef cows. Five hundred sixty cows were assigned randomly to two treatments: 1) 100 microg of GnRH (i.m.) followed in 7 d with 25 mg of PGF2alpha, followed in 48 h by a second injection of GnRH and one fixed-time insemination (Cosynch; n = 287) or 2) Cosynch plus one CIDR during the 7 d between the first injection of GnRH and PGF2alpha (Cosynch+P; n = 273). Cows at three stations were inseminated at the time of the second GnRH injection (n = 462), whereas 98 cows at the fourth station were inseminated 16 to 18 h after that injection. Blood samples were collected at d -17, -7, 0, and 2 relative to PGF2alpha to determine concentrations of progesterone. Ultrasonography was used to monitor follicle diameter on d 2 and to determine the presence of an embryo at 30 to 35 d after inseminat...
Influence of different doses of progesterone treatments on ovarian follicle status in beef cows
Animal Reproduction Science, 2006
To determine a dose of progesterone (P4) that allow ovarian follicular wave control, Aberdeen Angus cows were randomly assigned into four groups: T600 (n = 5), 600 mg of P4/day; T400 (n = 5), 400 mg of P4/day; T200 (n = 4), 200 mg of P4/day and Control (n = 4) (excipient only). Progesterone was injected from day 3 to 9 of estrous cycle. Ultrasonographies and blood sample collections were performed daily from day 2 to 10 and on day 15 of the estrous cycle. Additionally, an ultrasonographic study was conducted on day 13. Progesterone concentrations were different among all groups (P < 0.01). The diameter of the dominant follicle was greater for control than for T200, T400 and T600 groups (P < 0.01); there was no difference between T200 and T400 (P > 0.05), but they had a greater diameter follicle than the T600 group (P < 0.01). The growth rate of the dominant follicle between day 3 and 7 of estrous cycle was greater for control group (1.63 ± 0.3 mm day −1) than for T200 (0.56 ± 0.19 mm day −1 , P < 0.05), T400 (0.6 ± 0.23 mm day −1 , P < 0.05) and T600 (0.11 ± 0.13 mm day −1 , P < 0.01) groups. The mean number of class I follicles (3-4 mm) per day for the entire experimental period was less for the control group than for T200 (P < 0.05), T400 and T600 (P < 0.01) groups (3.7 ± 1.3; 5.3 ± 1.3; 6.6 ± 1.8 and 8.1 ± 1.9, respectively). The mean number for the T200 group was less than for T600 (P < 0.05) and similar for T400 and T600 groups (P > 0.05).
International Journal of Livestock Research, 2017
Progesterone (P 4) is a steroid hormone primarily secreted by the Corpus luteum (CL). Adequate circulating P 4 concentration is essential for establishment and maintenance of pregnancy. Exposure to insufficient circulating level of P 4 during the growth of the ovulatory follicle is one of the important factors that affect fertility in high producing animals. P 4 has a negative feedback effect on LH secretion and it is believed that sub-luteal phase plasma P 4 concentrations result in elevated LH pulse-frequency. There is a linear trend for the number of LH pulses to decrease concurrently with the increase in P 4 concentrations as the estrous cycle progresses. These changes in LH pulse frequency are supposed to be associated with alterations in the process of follicular maturation and subsequent embryo survival. Beneficial effects of increased progesterone level during growth of dominant follicle or following AI can be documented from the current literature. P 4 concentration during the development of dominant follicle (DF) influences the fertility since the DF of first and second wave use to grow under different P 4 environment. Further a slight increase in circulating level of progesterone near the time of artificial insemination (AI) is highly detrimental for fertility. So, a control of follicle and CL development through utilization of various hormonal regimens is routinely done now a days to further enhance the reproductive performance of dairy animals. Taking into account above all facts, the present review highlights the progesterone manipulation strategies to improve bovine fertility.
TURKISH JOURNAL OF VETERINARY AND ANIMAL SCIENCES, 2016
An experiment was conducted to investigate the effects of hormonal synchronization of ovulation on progesterone concentrations in milk and blood serum and on reproductive performance. Sixty Holstein-Friesian cows averaging 8000 L over 305 days of lactation were divided into 2 groups of 30 animals. One-factor ANOVA and a t-test of progesterone concentrations in venous serum and milk revealed that the lowest concentrations of progesterone in milk (Ovsynch 5.8 ± 1.0 ng/mL; control 4.5 ± 0.6 ng/mL) and blood serum (Ovsynch 1.3 ± 0.9 ng/mL; control 1.4 ± 0.5 ng/mL) in both groups were found on the day of estrus or artificial insemination (AI) (both P < 0.05). Increases in the concentrations of progesterone in milk (Ovsynch 17.6 ± 4.3 ng/mL; control 10.5 ± 1.9 ng/mL) and blood serum (Ovsynch 3.6 ± 1.1 ng/mL; control 4.0 ± 1.0 ng/mL) were observed on day 7 after AI (both P < 0.05). Concentrations of progesterone in milk and blood serum in nonpregnant cows were reduced on day 21 after AI. Assessment of reproductive performance revealed that the application of treatment shortened the duration of the service period (Ovsynch 76 days; control 83 days) and the calving interval (Ovsynch 376 days; control 382 days).
Physiological and practical effects of progesterone on reproduction in dairy cattle
Animal, 2014
The discovery of progesterone (P4) and elucidation of the mechanisms of P4 action have an important place in the history of endocrinology and reproduction. Circulating P4 concentration is determined by a balance between P4 production, primarily by the corpus luteum (CL), and P4 metabolism, primarily by the liver. The volume of luteal tissue and number and function of large luteal cells are primary factors determining P4 production. Rate of P4 metabolism is generally determined by liver blood flow and can be of critical importance in determining circulating P4 concentrations, particularly in dairy cattle. During timed artificial insemination (AI) protocols, elevations in P4 are achieved by increasing number of CL by creating accessory CL or by supplementation with exogenous P4. Dietary manipulations can also alter circulating P4, although practical methods to apply these techniques have not yet been reported. Elevating P4 before the timed AI generally decreases double ovulation and i...