Synchronization of ovulation and fixed-time artificial insemination in beef cattle

G. A. Bó; P. S. Baruselli

doi:10.1017/S1751731114000822

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Volume 8, Issue s1 (New Science ‐ New Practices International Cow Fertility Conference 18‐21 May 2014, Westport, Ireland)
May 2014 , pp. 144-150

Synchronization of ovulation and fixed-time artificial insemination in beef cattle

G. A. Bó ^(a1) ^(a2) and P. S. Baruselli ^(a3)

- https://doi.org/10.1017/S1751731114000822
- Published online: 09 April 2014

Abstract

The main objective of the implementation of artificial insemination (AI) in cattle is to produce a sustained genetic progress in the herd. Although AI is an old reproductive biotechnology, its widespread implementation is very recent and is mainly because of the use of protocols that allows AI without oestrus detection, commonly called fixed-time artificial insemination (FTAI). The development of FTAI protocols also allowed the application of AI in larger, extensively managed herds and especially in suckled cows instead of restricting the breeding programmes to the heifers. Fixed-time AI treatments are widely used in South America, with about 3 000 000 cows inseminated in the last season in Argentina and about 8 000 000 in Brazil. The objective of this review is to present and describe the various treatments available and some of the factors that may affect pregnancy rates in beef cattle.

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† E-mail: gabrielbo@iracbiogen.com.ar

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Barros, CM, Moreira, MBB, Figueiredo, RA, Teixeira, AB and Trinca, LA 2000. Synchronization of ovulation in beef cows (Bos indicus), using GnRH, PGF_2α and estradiol benzoate. Theriogenology 53, 1121–1134.

Bartolome, JA, Sheerin, P, Luznar, S, Melendez, P, Kelbert, D, Risco, CA, Thatcher, WW and Archbald, LF 2002. Conception rate in lactating dairy cows using Ovsynch after presynchronization with prostaglandin F2α (PGF2α) or gonadotropin releasing hormone (GnRH). The Bovine Practitioner 36, 35–38.

Baruselli, PS, Reis, EL, Marques, MO, Nasser, LF and Bó, GA 2004. The use of treatments to improve reproductive performance of anestrus beef cattle in tropical climates. Animal Reproduction Science 82–83, 479–486.

Baruselli, PS, Sá Filho, MF, Ferreira, RM, Sales, JNS, Gimenes, LU, Vieira, LM, Mendanha, MF and Bó, GA 2012. Manipulation of follicle development to ensure optimal oocyte quality and conception rates in cattle. Reproduction in Domestic Animals 47 (suppl. 4), 134–141.

Bello, NM, Steibel, JP and Pursley, JR 2006. Optimizing ovulation to first GnRH improved outcomes to each hormonal injection of Ovsynch in lactating dairy cows. Journal of Dairy Science 89, 3413–3424.

Bó, GA, Cutaia, L and Tribulo, R 2002a. Hormonal treatments for fixed-time artificial insemination: some experiments performed in Argentina. Second part (in Spanish). Taurus 15, 17–32.

Bó, GA, Baruselli, PS, Moreno, D, Cutaia, L, Caccia, M, Tríbulo, R, Tríbulo, H and Mapletoft, RJ 2002b. The control of follicular wave development for self-appointed embryo transfer programs in cattle. Theriogenology 57, 53–72.

Bó, GA, Baruselli, PS and Mapletoft, RJ 2013. Synchronization techniques to increase the utilization of artificial insemination in beef and dairy cattle. Animal Reproduction 10, 137–142.

Bó, GA, Cutaia, L, Peres, LC, Pincinato, D, Maraña, D and Baruselli, PS 2007. Technologies for fixed-time artificial insemination and their influence on reproductive performance of Bos indicus cattle. In Reproduction in Domestic Ruminants VI (ed. JL Juengel, JF Murray and MF Smith), pp. 223–236. Nottingham University Press, Nottingham, UK.

Bridges, GA, Mussard, ML, Hesler, LA and Day, ML 2014. Comparison of follicular dynamics and hormone concentrations between the 7-day and 5-day CO-Synch+CIDR program in primiparous beef cows. Theriogenology 81, 632–638.

Bridges, GA, Helser, LA, Grum, DE, Mussard, ML, Gasser, CL and Day, ML 2008. Decreasing the interval between GnRH and PGF2α from 7 to 5 days and lengthening proestrus increases timed-AI pregnancy rates in beef cows. Theriogenology 69, 843–851.

Bridges, GA, Ahola, JK, Brauner, C, Cruppe, LH, Currin, JC, Day, ML, Gunn, PJ, Jaeger, JR, Lake, SL, Lamb, GC, Marquezini, GHL, Peel, RK, Radunz, AE, Stevenson, JS and Whittier, WD 2012. Determination of the appropriate delivery of prostaglandin F2α in the five-day CO-Synch+controlled intravaginal drug release protocol in suckled beef cows. Journal of Animal Science 90, 4814–4822.

Brusveen, DJ, Cunha, AP, Silva, CD, Cunha, PM, Sterry, RA, Silva, EPB, Guenther, JN and Wiltbank, MC 2008. Altering the time of the second gonadotropin-releasing hormone injection and artificial insemination (AI) during Ovsynch affects pregnancies per AI in lactating dairy cows. Journal of Dairy Science 91, 1044–1052.

Busch, DC, Schafer, DJ, Wilson, DJ, Mallory, DA, Leitman, NR, Haden, JK, Ellersieck, MR, Smith, MF and Patterson, DJ 2008. Timing of artificial insemination in postpartum beef cows following administration of the Co-Synch+controlled internal drug-release protocol. Journal of Animal Science 86, 1519–1525.

Butler, SAA, Atkinson, PC, Boe-Hansen, GB, Burns, BM, Dawson, K, Bo, GA and McGowan, MR 2011. Pregnancy rates after fixed-time artificial insemination of Brahman heifers treated to synchronize ovulation with low-dose intravaginal progesterone releasing devices, with or without eCG. Theriogenology 76, 1416–1423.

Castro Duarte, GH and Osorno Chica, RC 2010. Effect of calf removal on pregnancy rates in commercial Brahman suckled cows treated with progestin, estradiol and eCG and fixed-time AI. Final Thesis. Specialization in Bovine Reproduction, Institute of Animal Reproduction Cordoba (IRAC) and National University of Cordoba, Cordoba, Argentina. Retrieved 15 October 2013, from http://www.iracbiogen.com.ar

Colazo, MG and Ambrose, DJ 2011. Neither duration of progesterone insert nor initial GnRH treatment affected pregnancy per timed-insemination in dairy heifers subjected to a Co-Synch protocol. Theriogenology 76, 578–588.

Colazo, MG, Kastelic, JP and Mapletoft, RJ 2003. Estradiol cypionate (ECP) on ovarian follicular dynamics, synchrony of ovulation, and fertility in CIDR-B-based, fixed-time AI programs in beef heifers. Theriogenology 60, 855–865.

Colazo, MG, Gordon, MB, Rajamahendran, R, Mapletoft, RJ and Ambrose, DJ 2009. Pregnancy rates to timed artificial insemination in dairy cows treated with gonadotropin-releasing hormone or porcine luteinizing hormone. Theriogenology 72, 262–270.

Colazo, MG, Small, JA, Ward, DR, Erickson, NE, Kastelic, JP and Mapletoft, RJ 2004. The effect of presynchronization on pregnancy rate to fixed-time AI in beef heifers subjected to a CO-Synch protocol. Reproduction Fertility and Development 16, 128.

de la Mata, JJ and Bó, GA 2012. Estrus synchronization and ovulation using protocols with estradiol benzoate and GnRH and reduced periods of insertion of a progesterone releasing device in beef heifers. Taurus 55, 17–23.

Diskin, MG, Austin, EJ and Roche, JF 2002. Exogenous hormonal manipulation of ovarian activity in cattle. Domestic Animal Endocrinology 23, 211–228.

Fernandes, P, Teixeria, AB, Crocci, AJ and Barros, CM 2001. Timed artificial insemination in beef cattle using GnRH agonist, PGF2a and estradiol benzoate (EB). Theriogenology 55, 1521–1532.

Galvão, KN, Sá Filho, MF and Santos, JEP 2007. Reducing the interval from presynchronization to initiation of timed artificial insemination improves fertility in dairy cows. Journal of Dairy Science 90, 4212–4218.

Geary, TW, Whittier, JC, Hallford, DM and MacNeil, MD 2001. Calf removal improves conception rates to the Ovsynch and Co-Synch protocols. Journal of Animal Science 79, 1–4.

Gumen, AJ, Guenther, M and Wiltbank, MC 2003. Follicular size and response to Ovsynch versus detection of estrus in anovular and ovular lactating dairy cows. Journal of Dairy Science 86, 3184–3194.

Huguenine, E, Peracchia, S, Benitez, R, Martini, H, Cledou, G, Bó, GA and Callejas, S 2013. Effect of the utilization of 5-day CO-Synch protocols combined or not with eCG in suckled cows in postpartum anoestrus. In Proceedings X Symposium on Animal Reproduction (ed. GA Bó and M Caccia), 313pp. Institute of Animal Reproduction Cordoba (IRAC), Córdoba, Argentina.

Kasimanickam, R, Day, ML, Rudolph, JS, Hall, JB and Whitier, WD 2009. Two doses of prostaglandin improve pregnancy rates to timed-AI in a 5-day progesterone based synchronization protocol in beef cows. Theriogenology 71, 762–767.

Kasimanickam, R, Asay, M, Firth, P, Whittier, WD and Hall, JB 2012. Artificial insemination at 56 h after intravaginal progesterone device removal improved AI pregnancy rate in beef heifers synchronized with five-day Co-Synch controlled internal drug release (CIDR) protocol. Theriogenology 77, 1624–1631.

Kasimanickam, R, Firth, P, Schuenemann, GM, Whitlock, BK, Gay, JM, Moore, DA, Hall, JB and Whittier, WD 2014. Effect of the first GnRH and two doses of PGF2a in a 5-day progesterone-based CO-Synch protocol on heifer pregnancy. Theriogenology 81, 797–804.

Lamb, GC, Stevenson, JS, Kesler, DJ, Garverick, HA, Brown, DR and Salfen, BE 2001. Inclusion of an intravaginal progesterone insert plus GnRH and prostaglandin F2α for ovulation control in postpartum suckled beef cows. Journal of Animal Science 79, 2253–2259.

Lima, FS, Ribeiro, ES, Bisinotto, RS, Greco, LF, Martinez, N, Amstalden, M, Thatcher, WW and Santos, JEP 2013. Hormonal manipulations in the 5-day timed artificial insemination protocol to optimize estrous cycle synchrony and fertility in dairy heifers. Journal of Dairy Science 96, 1–12.

Lima, FS, Ayres, H, Favoreto, MG, Bisinotto, RS, Greco, LF, Ribeiro, ES, Baruselli, PS, Risco, CA, Thatcher, WW and Santos, JEP 2011. Effects of gonadotropin releasing hormone at initiation of the 5-d timed artificial insemination (AI) program and timing of induction of ovulation relative to AI on ovarian dynamics and fertility of dairy heifers. Journal of Dairy Science 94, 4997–5004.

Marquezini, GHL, Mercadante, VRG, Olson, KC, Jaeger, JR, Perry, GA, Stevenson, JS and Lamb, GC 2013. Effects of equine chorionic gonadotropin on follicle development and pregnancy rates in suckled beef cows with or without calf removal. Journal of Animal Science 91, 1216–1224.

Martinez, MF, Adams, GP, Bergfelt, D, Kastelic, JP and Mapletoft, RJ 1999. Effect of LH or GnRH on the dominant follicle of the first follicular wave in heifers. Animal Reproduction Science 57, 23–33.

Martinez, MF, Kastelic, JP, Adams, GP, Cook, RB, Olson, WO and Mapletoft, RJ 2002a. The use of progestins in regimens for fixed-time artificial insemination in beef cattle. Theriogenology 57, 1049–1059.

Martinez, MF, Kastelic, JP, Adams, GP and Mapletoft, RJ 2002b. The use of a progesterone-releasing device (CIDR) or melengestrol acetate with GnRH, LH or estradiol benzoate for fixed-time AI in beef heifers. Journal of Animal Science 80, 1746–1751.

McDougall, S 2010. Effects of treatment of anestrous dairy cows with gonadotropin-releasing hormone, prostaglandin and progesterone. Journal of Dairy Science 93, 1944–1959.

Menchaca, A, Núñez, R, Wijma, R, García Pintos, C, Fabini, F and de Castro, T 2013. How fertility can be improved in fixed-time AI programs in beef cattle. In Proceedings X Symposium on Animal Reproduction (ed. GA Bó and M Caccia), pp. 103–134. Institute of Animal Reproduction Cordoba (IRAC), Córdoba, Argentina.

Moreira, F, Orlandi, C, Risco, CA, Schouten, MJ, Lopes, F and Thatcher, WW 2001. Effects of presynchronization and bovine somatotropin on pregnancy rates to a timed artificial insemination protocol in lactating dairy cows. Journal of Dairy Science 84, 1646–1659.

Penteado, L, Ayres, H, Madureira, EH and Baruselli, PS 2004. Effect of temporary weaning on pregnancy rates in lactating Nelore cows inseminated at a fixed-time. Acta Scientiae Veterinariae 32 (suppl.), 223.

Perry, GA, Smith, MF, Roberts, AJ, Macneil, MD and Geary, TW 2007. Relationship between size of the ovulatory follicle and pregnancy success in beef heifers. Journal of Animal Science 85, 684–689.

Peterson, C, Alkar, A, Smith, S, Kerr, S, Hall, JB, Moore, D and Kasimanickam, R 2011. Effects of one versus two doses of prostaglandin F2alpha on AI pregnancy rates in a 5-day progesterone-based, CO-Synch protocol in crossbred beef heifers. Theriogenology 75, 1536–1542.

Pincinato, D 2012. Follicular dynamics and fertility in beef suckled cows synchronized with progesterone releasing devices and GnRH. Master of Science Thesis, Faculty of Agriculture Sciences, National University of Cordoba, Cordoba, Argentina.

Pursley, JR, Mee, MO and Wiltbank, MC 1995. Synchronization of ovulation in dairy cows using PGF2α and GnRH. Theriogenology 44, 915–923.

Rabaglino, MB, Risco, C, Thatcher, MJ, Kim, IH, Santos, JE and Thatcher, WW 2010. Application of one injection of prostaglandin F2alpha in the five-day Co-Synch+CIDR protocol for estrous synchronization and resynchronization of dairy heifers. Journal of Dairy Science 93, 1050–1058.

Ré, M, de la Mata, JJ and Bó, GA 2014. Synchronization of ovulation in dairy heifers using a shortened estradiol-based protocol that provides for a lengthened proestrus. Reproduction Fertility and Development 26, 118.

Sá Filho, OG, Meneghetti, M, Peres, RFG, Lamb, GC and Vasconcelos, JLM 2009. Fixed-time artificial insemination with estradiol and progesterone for Bos indicus cows II: strategies and factors affecting fertility. Theriogenology 72, 210–218.

Sá Filho, MF, Ayres, H, Ferreira, RM, Marques, MO, Reis, EL, Silva, RC, Rodrigues, CA, Madureira, EH, Bó, GA and Baruselli, PS 2010a. Equine chorionic gonadotropin and gonadotropin-releasing hormone enhance fertility in a norgestomet-based, timed artificial insemination protocol in suckled Nelore (Bos indicus) cows. Theriogenology 73, 651–658.

Sá Filho, MF, Torres-Junior, JRS, Penteado, L, Gimenes, LU, Ferreira, RM, Ayres, H, Castro e Paula, LA, Sales, JNS and Baruselli, PS 2010b. Equine chorionic gonadotropin improves the efficacy of a progestin based fixed-time artificial insemination protocol in Nelore (Bos indicus) heifers. Animal Reproduction Science 118, 182–187.

Sá Filho, MF, Crespilho, AM, Santos, JE, Perry, GA and Baruselli, PS 2010c. Ovarian follicle diameter at timed insemination and estrous response influence likelihood of ovulation and pregnancy after estrous synchronization with progesterone or progestin-based protocols in suckled Bos indicus cows. Animal Reproduction Science 120, 23–30.

Sales, JNS, Crepaldi, GA, Girotto, RW, Souza, AH and Baruselli, PS 2011. Fixed-time AI protocols replacing eCG with a single dose of FSH were less effective in stimulating follicular growth, ovulation and fertility in suckled-anestrus Nelore beef cows. Animal Reproduction Science 124, 12–18.

Small, JA, Colazo, MG, Kastelic, JP and Mapletoft, RJ 2009. Effects of progesterone pre-synchronization and eCG on pregnancy rates to GnRH-based, timed-AI in beef cattle. Theriogenology 71, 698–706.

Souza, AH, Ayres, H, Ferreira, RM and Wiltbank, MC 2008. A new presynchronization system (Double-Ovsynch) increases fertility at first postpartum timed AI in lactating dairy cows. Theriogenology 70, 208–215.

Twagiramungu, H, Guilbault, LA and Dufour, JJ 1995. Synchronization of ovarian follicular waves with a gonadotropin-releasing hormone agonist to increase the precision of estrus in cattle: A review. Journal of Animal Science 73, 3141–3151.

Whittier, WD, Currin, JF, Schramm, H, Holland, S and Kasimanickam, RK 2013. Fertility in Angus cross beef cows following 5-day CO-Synch+CIDR or 7-day CO-Synch+CIDR estrus synchronization and timed artificial insemination. Theriogenology 80, 963–969.

Williams, SW, Stanko, RL, Amstalden, M and Williams, GL 2002. Comparison of three approaches for synchronization of ovulation for timed artificial insemination in Bos indicus-influenced cattle managed on the Texas gulf coast. Journal of Animal Science 80, 1173–1178.

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