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Prepartum and postpartum nutritional management to optimize fertility in high-yielding dairy cows in confined TMR systems

Published online by Cambridge University Press:  09 April 2014

J. K. Drackley  and
F. C. Cardoso
J. K. Drackley*
Affiliation:
Department of Animal Sciences, University of Illinois, 1207 West Gregory Drive, Urbana, Illinois, USA
F. C. Cardoso
Affiliation:
Department of Animal Sciences, University of Illinois, 1207 West Gregory Drive, Urbana, Illinois, USA
*
E-mail: drackley@illinois.edu
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Abstract

The 6 to 8-week period centered on parturition, known as the transition or periparturient period, is critical to welfare and profitability of individual cows. Fertility of high-producing cows is compromised by difficult transitions. Deficiencies in either nutritional or non-nutritional management increase risk for periparturient metabolic disorders and infectious diseases, which decrease subsequent fertility. A primary factor impeding fertility is the extent of negative energy balance (NEB) early postpartum, which may inhibit timing of first ovulation, return to cyclicity, and oocyte quality. In particular, pronounced NEB during the first 10 days to 2 weeks (the time of greatest occurrence of health problems) is critical for later reproductive efficiency. Avoiding over-conditioning and preventing cows from over-consuming energy relative to their requirements in late gestation result in higher dry matter intake (DMI) and less NEB after calving. A pooled statistical analysis of previous studies in our group showed that days to pregnancy are decreased (by 10 days) by controlling energy intake to near requirements of cows before calving compared with allowing cows to over-consume energy. To control energy intake, total mixed rations (TMR) must be well balanced for metabolizable protein, minerals and vitamins yet limit total DM consumed, and cows must uniformly consume the TMR without sorting. Dietary management to maintain blood calcium and rumen health around and after calving also are important. Opportunities may exist to further improve energy status in fresh cows. Recent research to manipulate the glucogenic to lipogenic balance and the essential fatty acid content of tissues are intriguing. High-producing cows that adapt successfully to lactation can have high reproductive efficiency, and nutritional management of the transition period both pre- and post-calving must facilitate that adaptation.

Keywords

transition periodreproductionnutritionmetabolic disorders
Type
Full Paper
Information
animal , Volume 8 , Supplement s1: New Science ‐ New Practices International Cow Fertility Conference 18‐21 May 2014, Westport, Ireland , May 2014 , pp. 5 - 14
Copyright
© The Animal Consortium 2014 

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References

Allen, MS, Bradford, BJ and Oba, M 2009. Board invited review: the hepatic oxidation theory of the control of feed intake and its application to ruminants. Journal of Animal Science 87, 33173334.CrossRefGoogle ScholarPubMed
Ametaj, BN, Bradford, BJ, Bobe, GB, Nafikov, RA, Lu, Y, Young, JW and Beitz, DC 2005. Strong relationships between mediators of the acute phase response and fatty liver in dairy cows. Canadian Journal of Animal Science 85, 165175.CrossRefGoogle Scholar
Bach, A, Valls, N, Solans, A and Torrent, T 2008. Association between nondietary factors and dairy herd performance. Journal of Dairy Science 91, 32593267.Google Scholar
Beever, DE 2006. The impact of controlled nutrition during the dry period on dairy cow health, fertility and performance. Animal Reproduction Science 96, 212226.CrossRefGoogle ScholarPubMed
Bell, AW, Burhans, WS and Overton, TR 2000. Protein nutrition in late pregnancy, maternal protein reserves and lactation performance in dairy cows. Proceedings of the Nutrition Society 59, 119136.CrossRefGoogle ScholarPubMed
Bello, NM, Stevenson, JS and Tempelman, RJ 2012. Invited review: milk production and reproductive performance: Modern interdisciplinary insights into an enduring axiom. Journal of Dairy Science 95, 54615475.CrossRefGoogle ScholarPubMed
Bertoni, G, Trevisi, E, Han, X and Bionaz, M 2008. Effects of inflammatory conditions on liver activity in puerperium period and consequences for performance in dairy cows. Journal of Dairy Science 91, 33003310.Google Scholar
Bossaert, P, Leroy, JL, De Vliegher, S and Opsomer, G 2008. Interrelations between glucose-induced insulin response, metabolic indicators, and time of first ovulation in high-yielding dairy cows. Journal of Dairy Science 91, 33633371.Google Scholar
Butler, WR 2003. Energy balance relationships with follicular development, ovulation and fertility in postpartum dairy cows. Livestock Production Science 83, 211218.CrossRefGoogle Scholar
Cardoso, FC, LeBlanc, SJ, Murphy, MR and Drackley, JK 2013. Prepartum nutritional strategy affects reproductive performance in dairy cows. Journal of Dairy Science 96, 58595871.Google Scholar
Chapinal, N, Leblanc, SJ, Carson, ME, Leslie, KE, Godden, S, Capel, M, Santos, JE, Overton, MW and Duffield, TF 2012. Herd-level associations of serum metabolites in the transition period with disease, milk production, and early lactation reproductive performance. Journal of Dairy Science 95, 56765682.Google Scholar
Contreras, GA and Sordillo, LM 2011. Lipid mobilization and inflammatory responses during the transition period of dairy cows. Comparative Immunology, Microbiology and Infectious Diseases 34, 281289.CrossRefGoogle ScholarPubMed
Dann, HM and Nelson, BH 2011. Early lactation diets for dairy cattle – focus on starch. In Proceedings of the 2011 Cornell Nutrition Conference for Feed Manufacturers, Syracuse, NY, USA.Google Scholar
Dann, HM, Morin, DE, Murphy, MR, Bollero, GA and Drackley, JK 2005. Prepartum intake, postpartum induction of ketosis, and periparturient disorders affect the metabolic status of dairy cows. Journal of Dairy Science 88, 32493264.Google Scholar
Dann, HM, Litherland, NB, Underwood, JP, Bionaz, M, D’Angelo, A, McFadden, JW and Drackley, JK 2006. Diets during far-off and close-up dry periods affect periparturient metabolism and lactation in multiparous cows. Journal of Dairy Science 89, 35633577.CrossRefGoogle ScholarPubMed
DeGaris, PJ, Lean, IJ, Rabiee, AR and Heur, C 2010. Effects of increasing days of exposure to prepartum transition diets on reproduction and health in dairy cows. Australian Veterinary Journal 88, 8492.Google Scholar
Diskin, MG and Morris, DG 2008. Embryonic and early foetal losses in cattle and other ruminants. Reproduction in Domestic Animals 43 (suppl. 2), 260267.Google Scholar
Douglas, GN, Overton, TR, Bateman, HG, Dann, HM and Drackley, JK 2006. Prepartal plane of nutrition, regardless of dietary energy source, affects periparturient metabolism and dry matter intake in Holstein cows. Journal of Dairy Science 89, 21412157.CrossRefGoogle ScholarPubMed
Drackley, JK and Dann, HM 2008. A scientific approach to feeding dry cows. In Recent advances in animal nutrition – 2007 (ed. PC Garnsworthy and J Wiseman), pp. 4374. Nottingham University Press, Nottingham, UK.Google Scholar
Drackley, JK, Overton, TR and Douglas, GN 2001. Adaptations of glucose and long-chain fatty acid metabolism in liver of dairy cows during the periparturient period. Journal of Dairy Science 84 (E. suppl.), E100E112.Google Scholar
Drackley, JK, Wallace, RL, Graugnard, D, Vasquez, J, Richards, BF and Loor, JJ 2014. Visceral adipose tissue mass in non-lactating dairy cows fed diets differing in energy density. Journal of Dairy Science 97 (in press).Google Scholar
Drackley, JK, Dann, HM, Douglas, GN, Janovick Guretzky, NA, Litherland, NB, Underwood, JP and Loor, JJ 2005. Physiological and pathological adaptations in dairy cows that may increase susceptibility to periparturient diseases and disorders. Italian Journal of Animal Science 4, 323344.Google Scholar
Dyck, BL, Colaz, MG, Ambrose, DJ, Dyck, MK and Doepel, L 2011. Starch source and content in postpartum dairy cow diets: effects on plasma metabolites and reproductive processes. Journal of Dairy Science 94, 46364646.Google Scholar
Emmanuel, DG, Dunn, SM and Ametaj, BN 2008. Feeding high proportions of barley grain stimulates an inflammatory response in dairy cows. Journal of Dairy Science 91, 606614.Google Scholar
Emmanuel, DG, Madsen, KL, Churchill, TA, Dunn, SM and Ametaj, BN 2007. Acidosis and lipopolysaccharide from Escherichia coli B:055 cause hyperpermeability of rumen and colon tissues. Journal of Dairy Science 90, 55525557.CrossRefGoogle Scholar
Friggens, NC 2003. Body lipid reserves and reproductive cycle: towards a better understanding. Livestock Production Science 83, 219236.Google Scholar
Friggens, NC, Andersen, JB, Larsen, T, Aaes, O and Dewhurst, RJ 2004. Priming the dairy cow for lactation: a review of dry cow feeding strategies. Animal Research 53, 453473.CrossRefGoogle Scholar
Galvão, KN, Flaminio, MJBF, Brittin, SB, Sper, R, Fraga, M, Caixeta, L, Ricci, A, Guard, CL, Butler, WR and Gilbert, RO 2010a. Association between uterine disease and indicators of neutrophil and systemic energy status in lactating Holstein cows. Journal of Dairy Science 93, 29262937.Google Scholar
Galvão, KN, Frajblat, M, Butler, WR, Brittin, SB, Guard, CL and Gilbert, RO 2010b. Effect of early postpartum ovulation on fertility in dairy cows. Reproduction in Domestic Animals 45, e207e211.Google Scholar
Garnsworthy, PC 2007. Body condition score in dairy cows: targets for production and fertility. In Recent advances in animal nutrition – 2006 (ed. PC Garnsworthy and J Wiseman), pp. 6186. Nottingham University Press, Nottingham, UK.Google Scholar
Garnsworthy, PC, Sinclair, KD and Webb, R 2008. Integration of physiological mechanisms that influence fertility in dairy cows. Animal 2, 11441152.CrossRefGoogle ScholarPubMed
Garnsworthy, PC, Fouladi-Nashta, AA, Mann, GE, Sinclair, KD and Webb, R 2009. Effect of dietary-induced changes in plasma insulin concentrations during the early post partum period on pregnancy rate in dairy cows. Reproduction 137, 759768.CrossRefGoogle ScholarPubMed
Garverick, HA, Harris, MN, Vogel-Bluel, R, Sampson, JD, Bader, J, Lamberson, WR, Spain, JN, Lucy, MC and Youngquist, RS 2013. Concentrations of nonesterified fatty acids and glucose in blood of periparturient dairy cows are indicative of pregnancy success at first insemination. Journal of Dairy Science 96, 181188.Google Scholar
Gilmore, HS, Young, FJ, Patterson, DC, Wylie, ARG, Law, RA, Kilpatrick, DJ, Elliott, CT and Mayne, CS 2011. An evaluation of altering nutrition and nutritional strategies in early lactation on reproductive performance and estrous behavior of high-yielding Holstein-Friesian dairy cows. Journal of Dairy Science 94, 35103526.Google Scholar
Goldhawk, C, Chapinal, N, Veira, DM, Weary, DM and von Keyserlingk, MA 2009. Prepartum feeding behavior is an early indicator of subclinical ketosis. Journal of Dairy Science 92, 49714977.Google Scholar
Graugnard, DE, Moyes, KM, Trevisi, E, Khan, MJ, Keisler, D, Drackley, JK, Bertoni, G and Loor, JJ 2013. Liver lipid content and inflammometabolic indices in peripartal dairy cows are altered in response to prepartal energy intake and postpartal intramammary inflammatory challenge. Journal of Dairy Science 96, 918935.Google Scholar
Graugnard, DE, Bionaz, M, Trevisi, E, Moyes, KM, Salak-Johnson, JL, Wallace, RL, Drackley, JK, Bertoni, G and Loor, JJ 2012. Blood immunometabolic indices and polymorphonuclear leukocyte function in peripartum dairy cows are altered by level of dietary energy prepartum. Journal of Dairy Science 95, 17491758.Google Scholar
Grum, DE, Drackley, JK, Younker, RS, LaCount, DW and Veenhuizen, JJ 1996. Nutrition during the dry period and hepatic lipid metabolism of periparturient dairy cows. Journal of Dairy Science 79, 18501864.CrossRefGoogle ScholarPubMed
Grummer, RR, Mashek, DG and Hayirli, A 2004. Dry matter intake and energy balance in the transition period. Veterinary Clinics North America Food Animal Practice 20, 447470.Google Scholar
Hammon, DS, Evjen, IM, Dhiman, TR, Goff, JP and Walters, JL 2006. Neutrophil function and energy status in Holstein cows with uterine health disorders. Veterinary Immunology and Immunopathology 113, 2129.CrossRefGoogle ScholarPubMed
Holcomb, CS, Van Horn, HH, Head, HH, Hall, MB and Wilcox, CJ 2001. Effects of prepartum dry matter intake and forage percentage on postpartum performance of lactating dairy cows. Journal of Dairy Science 84, 20512058.Google Scholar
Holtenius, K, Agenäs, S, Delavaud, C and Chilliard, Y 2003. Effects of feeding intensity during the dry period. 2. Metabolic and hormonal responses. Journal of Dairy Science 86, 883891.Google Scholar
Horst, RL, Goff, JP, Reinhardt, TA and Buxton, DR 1997. Strategies for preventing milk fever in dairy cattle. Journal of Dairy Science 80, 12691280.CrossRefGoogle ScholarPubMed
Houdijk, JGH, Jessop, NS and Kyriazakis, I 2001. Nutrient partitioning between reproductive and immune functions in animals. Proceedings of the Nutrition Society 60, 515525.Google Scholar
Huzzey, JM, Veira, DM, Weary, DM and von Keyserlingk, MA 2007. Prepartum behavior and dry matter intake identify dairy cows at risk for metritis. Journal of Dairy Science 90, 32203233.CrossRefGoogle ScholarPubMed
Ingvartsen, KL 2006. Feeding- and management-related diseases in the transition cow. Physiological adaptations around calving and strategies to reduce feeding-related diseases. Animal Feed Science and Technology 126, 175213.Google Scholar
Ingvartsen, KL and Moyes, K 2013. Nutrition, immune function and health of dairy cattle. Animal 7 (suppl. 1), 112122.CrossRefGoogle ScholarPubMed
Ingvartsen, KL, Dewhurst, RJ and Friggens, NC 2003. On the relationship between lactational performance and health: is it yield or metabolic imbalance that cause production diseases in dairy cattle? A position paper. Livestock Production Science 83, 277308.CrossRefGoogle Scholar
Janovick, NA and Drackley, JK 2010. Prepartum dietary management of energy intake affects postpartum intake and lactation performance by primiparous and multiparous Holstein cows. Journal of Dairy Science 93, 30863102.Google Scholar
Janovick, NA, Boisclair, YR and Drackley, JK 2011. Prepartum dietary energy intake affects metabolism and health during the periparturient period in primiparous and multiparous Holstein cows. Journal of Dairy Science 94, 13851400.Google Scholar
Ji, P, Osorio, JS, Drackley, JK and Loor, JJ 2012. Overfeeding a moderate energy diet prepartum does not impair bovine subcutaneous adipose tissue insulin transduction and induces marked changes in peripartal gene network expression. Journal of Dairy Science 95, 43334351.Google Scholar
Jorritsma, R, Wensing, T, Kruip, TA, Vos, PL and Noordhuizen, JP 2003. Metabolic changes in early lactation and impaired reproductive performance in dairy cows. Veterinary Research 34, 1126.Google Scholar
Kim, IH and Suh, GH 2003. Effect of the amount of body condition loss from the dry to near calving periods on the subsequent body condition change, occurrence of postpartum diseases, metabolic parameters and reproductive performance in Holstein dairy cows. Theriogenology 60, 14451456.Google Scholar
Kimura, K, Reinhardt, TA and Goff, JP 2006. Parturition and hypocalcemia blunts calcium signals in immune cells of dairy cattle. Journal of Dairy Science 89, 25882595.CrossRefGoogle ScholarPubMed
Kimura, K, Goff, JP, Kehrli, ME Jr and Reinhardt, TA 2002. Decreased neutrophil function as a cause of retained placenta in dairy cattle. Journal of Dairy Science 85, 544550.Google Scholar
Kunz, PL, Blum, JW, Hart, IC, Bickel, J and Landis, J 1985. Effects of different energy intakes before and after calving on food intake, performance and blood hormones and metabolites in dairy cows. Animal Production 40, 219231.Google Scholar
Lean, IJ, Van Saun, R and Degaris, PJ 2013a. Energy and protein nutrition management of transition dairy cows. Veterinary Clinics North America Food Animal Practice 29, 337366.CrossRefGoogle ScholarPubMed
Lean, IJ, Van Saun, R and Degaris, PJ 2013b. Mineral and antioxidant management of transition dairy cows. Veterinary Clinics North America Food Animal Practice 29, 367386.Google Scholar
LeBlanc, S 2010. Assessing the association of the level of milk production with reproductive performance in dairy cattle. Journal of Reproduction and Development 56 (suppl.), S1S7.Google Scholar
Lemley, CO, Butler, ST, Butler, WR and Wilson, ME 2008. Short communication: insulin alters hepatic progesterone catabolic enzymes cytochrome P450 2C and 3A in dairy cows. Journal of Dairy Science 91, 641645.CrossRefGoogle ScholarPubMed
Leroy, JL, Vanholder, T, Opsomer, G, Van Soom, A and de Kruif, A 2006. The in vitro development of bovince oocytes after maturation in glucose and β-hydroxybutyrate concentrations associated with negative energy balance. Reproduction in Domestic Animals 41, 119123.CrossRefGoogle ScholarPubMed
Leroy, JL, Vanholder, T, Delanghe, JR, Opsomer, G, Van Soom, A, Bols, PE, Dewulf, J and de Kruif, A 2004. Metabolic changes in follicular fluid of the dominant follicle in high-yielding dairy cows early post partum. Theriogenology 62, 11311143.CrossRefGoogle ScholarPubMed
Loor, JJ 2010. Genomics of metabolic adaptations in the peripartal cow. Animal 4, 11101139.Google Scholar
Loor, JJ, Everts, RE, Bionaz, M, Dann, HM, Morin, DE, Oliveira, R, Rodriguez-Zas, SL, Drackley, JK and Lewin, HA 2007. Nutrition-induced ketosis alters metabolic and signaling gene networks in liver of periparturient dairy cows. Physiological Genomics 32, 105116.CrossRefGoogle ScholarPubMed
Loor, JJ, Dann, HM, Janovick Guretzky, NA, Everts, RE, Oliveira, R, Green, CA, Litherland, NB, Rodriguez-Zas, SL, Lewin, HA and Drackley, JK 2006. Plane of nutrition prepartum alters hepatic gene expression and function in dairy cows as assessed by longitudinal transcript and metabolic profiling. Physiological Genomics 27, 2941.Google Scholar
Lucy, MC 2000. Regulation of ovarian follicular growth by somatotropin and insulin-like growth factors in cattle. Journal of Dairy Science 83, 16351647.CrossRefGoogle ScholarPubMed
McArt, JA, Nydam, DV and Oetzel, GR 2012. Epidemiology of subclinical ketosis in early lactation dairy cattle. Journal of Dairy Science 95, 50565066.Google Scholar
Moyes, KM, Drackley, JK, Salak-Johnson, JL, Morin, DE, Hope, JC and Loor, JJ 2009. Dietary-induced negative energy balance has minimal effects on innate immunity during a Streptococcus uberis mastitis challenge in dairy cows during midlactation. Journal of Dairy Science 92, 43014316.CrossRefGoogle ScholarPubMed
Mulligan, FJ and Doherty, ML 2008. Production diseases of the transition cow. Veterinary Journal 176, 39.Google Scholar
Mulligan, FJ, O’Grady, L, Rice, DA and Doherty, ML 2006. A herd health approach to dairy cow nutrition and production diseases of the transition cow. Animal Reproduction Science 96, 331353.Google Scholar
Ospina, PA, Nydam, DV, Stokol, T and Overton, TR 2010. Association between the proportion of sampled transition cows with increased nonesterified fatty acids and β-hydroxybutyrate and disease incidence, pregnancy rate, and milk production at the herd level. Journal of Dairy Science 93, 35953601.Google Scholar
Pearce, SC, Mani, V, Weber, TE, Rhoads, RP, Patience, JE, Baumgard, LH and Gabler, NK 2013. Heat stress and reduced plane of nutrition decreases intestinal integrity and function in pigs Journal of Animal Science 91, 51835193.Google Scholar
Pushpakumara, PG, Gardner, NH, Reynolds, CK, Beever, DE and Wathes, DC 2003. Relationships between transition period diet, metabolic parameters and fertility in lactating dairy cows. Theriogenology 60, 11651185.Google Scholar
Reinhardt, TA, Lippolis, JD, McCluskey, BJ, Goff, JP and Horst, RL 2011. Prevalence of subclinical hypocalcemia in dairy herds. Veterinary Journal 188, 122124.Google Scholar
Reist, M, Erdin, DK, von Euw, D, Tschümperlin, KM, Leuenberger, H, Hammon, HM, Morel, C, Philipona, C, Zbinden, Y, Künzi, N and Blum, JW 2003. Postpartum reproductive function: association with energy, metabolic and endocrine status in high yielding dairy cows. Theriogenology 59, 17071723.CrossRefGoogle ScholarPubMed
Reynolds, CK, Aikman, PC, Lupoli, B, Humphries, DJ and Beever, DE 2003. Splanchnic metabolism of dairy cows during the transition from late gestation through early lactation. Journal of Dairy Science 86, 12011217.Google Scholar
Roche, JR, Bell, AW, Overton, TR and Loor, JJ 2013. Nutritional management of the transition cow in the 21st century – a paradigm shift in thinking. Animal Production Science 53, 10001023.Google Scholar
Rukkwamsuk, T, Wensing, T and Geelen, MJ 1998. Effect of overfeeding during the dry period on regulation of adipose tissue metabolism in dairy cows during the periparturient period. Journal of Dairy Science 81, 29042911.Google Scholar
Rukkwamsuk, T, Wensing, T and Kruip, TA 1999. Relationship between triacylglycerol concentration in the liver and first ovulation in postpartum dairy cows. Theriogenology 51, 11331142.CrossRefGoogle ScholarPubMed
Sangsritavong, S, Combs, DK, Sartori, R, Armentano, LE and Wiltbank, MC 2002. High feed intake increases liver blood flow and metabolism of progesterone and estradiol-17beta in dairy cattle. Journal of Dairy Science 85, 28312842.Google Scholar
Santos, JE, Rutigliano, HM and Sa Filho, MF 2009. Risk factors for resumption of postpartum estrous cycles and embryonic survival in lactating dairy cows. Animal Reproduction Science 110, 207221.Google Scholar
Schoenberg, KM and Overton, TR 2011. Effects of plane of nutrition and 2,4-thiazolidinedione on insulin responses and adipose tissue gene expression in dairy cattle during late gestation. Journal of Dairy Science 94, 60216035.Google Scholar
Silva-del-Rio, N, Fricke, PM and Grummer, RR 2010. Effects of twin pregnancy and dry period strategy on milk production, energy balance, and metabolic profile in dairy cows. Journal of Animal Science 88, 10481060.Google Scholar
Silvestre, FT, Carvalho, TS, Francisco, N, Santos, JE, Staples, CR, Jenkins, TC and Thatcher, WW 2011. Effects of differential supplementation of fatty acids during the peripartum and breeding periods of Holstein cows: I. Uterine and metabolic responses, reproduction, and lactation. Journal of Dairy Science 94, 189204.Google Scholar
Sutter, F and Beever, DE 2000. Energy and nitrogen metabolism in Holstein-Friesen cows during early lactation. Animal Science 70, 503514.Google Scholar
Tharwat, M, Takamizawa, A, Hosaka, YZ, Endoh, D and Oikawa, S 2012. Hepatocyte apoptosis in dairy cattle during the transition period. Canadian Journal of Veterinary Research 76, 241247.Google Scholar
Thatcher, W, Santos, JE and Staples, CR 2011. Dietary manipulations to improve embryonic survival in cattle. Theriogenology 76, 16191631.Google Scholar
Van der Drift, SG, Houweling, M, Schonewille, JT, Tielens, AG and Jorritsma, R 2012. Protein and fat mobilization and associations with serum β-hydroxybutyrate concentrations in dairy cows. Journal of Dairy Science 95, 49114920.Google Scholar
Vickers, LA, Weary, DM, Veira, DM and von Keyserlingk, MA 2013. Feeding a higher forage diet prepartum decreases incidences of subclinical ketosis in transition dairy cows. Journal of Animal Science 91, 886894.Google Scholar
Walsh, RB, Walton, JS, Kelton, DF, LeBlanc, SJ, Leslie, KE and Duffield, TF 2007. The effect of subclinical ketosis in early lactation on reproductive performance of postpartum dairy cows. Journal of Dairy Science 90, 27882796.Google Scholar
Whitaker, DA, Smith, EJ, da Rosa, GO and Kelly, JM 1993. Some effects of nutrition and management on the fertility of dairy cattle. Veterinary Record 133, 6164.Google Scholar
Winkleman, LA, Elsasser, TH and Reynolds, CK 2008. Limit-feeding a high-energy diet to meet energy requirements in the dry period alters plasma metabolite concentrations but does not affect intake or milk production in early lactation. Journal of Dairy Science 91, 10671079.Google Scholar
Zebeli, Q and Metzler-Zebeli, BU 2012. Interplay between rumen digestive disorders and diet-induced inflammation. Research in Veterinary Science 93, 10991108.Google Scholar
Zebeli, Q, Sivaraman, S, Dunn, SM and Ametaj, BN 2011. Intermittent parenteral administration of endotoxin triggers metabolic and immunological alterations typically associated with displaced abomasum and retained placenta in periparturient dairy cows. Journal of Dairy Science 94, 49684983.Google Scholar
Zurek, E, Foxcroft, GR and Kennelly, JJ 1995. Metabolic status and interval to first ovulation in postpartum dairy cows. Journal of Dairy Science 78, 19091920.Google Scholar