Factors Associated with Negative Energy Balance and Its Effect on Behavior and Production Performance of Dairy Cows: A Review
محورهای موضوعی : CamelA.K. Singh 1 , C. Bhakat 2 , D.K. Mandal 3 , A. Mandal 4 , A. Chatterjee 5 , M.K. Ghosh 6 , T.K. Dutta 7 , M. Karunakaran 8
1 - Department of Livestock Production Management, ICAR-National Dairy Research Institute, Karnal, India
2 - Department of Livestock Production Management, ICAR-National Dairy Research Institute, Eastern Regional Station, Kalyani, India
3 - Department of Livestock Production Management, ICAR-National Dairy Research Institute, Eastern Regional Station, Kalyani, India
4 - Department of Animal Genetics and Breeding, ICAR-National Dairy Research Institute, Eastern Regional Station, Kalyani, India
5 - Department of Animal Nutrition, ICAR-National Dairy Research Institute, Eastern Regional Station, India
6 - Department of Animal Nutrition, ICAR-National Dairy Research Institute, Eastern Regional Station, India
7 - Department of Animal Nutrition, ICAR-National Dairy Research Institute, Eastern Regional Station, India
8 - Department of Animal Reproduction, ICAR-National Dairy Research Institute, Eastern Regional Station, India
کلید واژه: behavior, dairy cows, negative energy balance, production performance,
چکیده مقاله :
Optimum nutritional condition of dairy cows during the different stages of production is highly recommended. Production of high quality milk is the primary goal of every herdsman. However, improper nutrition of dairy cows leads to different unwanted ailments and disease losses. This becomes a burden for dairy owners. Most commonly, dairy cow undergoes negative energy balance (NEBL) condition due to improper dry matter intake (DMI). DMI in proper amount provides good nutrition for the dairy animals. There is a common trend of depressed DMI during the transition and the initial lactation period of high-producing animals. Following which elevated levels of non-esterified fatty acids (NEFA), beta-hydroxybutyrate (BHBA), blood urea nitrogen (BUN), undesired body condition stages, lowered production performances, poor milk quality, and inferior udder health status of dairy cows are observed. Both over-conditioned and under-conditioned bodies of the dairy animal are more at risk of NEBL thereby posing a negative impact on behavioral and production performance. This review is framed to discuss the effect of negative energy balance on the behavior and production performance of dairy cows.
Aggarwal A. and Singh M. (2008). Changes in skin and rectal temperature in lactating buffaloes provided with showers and wallowing during hot-dry season. Trop. Anim. Health Prod. 40, 223-228.
Aggarwal A. and Upadhyay R. (2013). Heat Stress and Animal Productivity. Springer, New York, USA.
Alamouti A.A., Alikhani G.R., Ghorbani A.T. and Bagheri M. (2014). Response of early-lactation Holstein cows to partial replacement of neutral detergent soluble fibre for starch in diets varying in forage particle size. Livest. Sci. 160, 60-68.
Alhussien M.N. and Dang A.K. (2018). Milk somatic cells, factors influencing their release, future prospects and practical utility in dairy animals: An overview. Vet. World. 11, 562-577.
Azizi O., Kaufmann O. and Hasselmann L. (2009). Relationship between feeding behavior and feed intake of dairy cows depending on their parity and milk yield. Livest. Sci. 122, 156-161.
Bachman K.C. and Schairer M.L. (2003). Invited review: Bovine studies on optimal lengths of dry periods. J. Dairy Sci. 86, 3027-3037.
Batavani R.A., Asri S. and Naebzadeh H. (2007). The effect of Subclinical mastitis on milk composition in dairy cows. Iranian J. Vet. Res. 8(3), 205-211.
Beauchemin K.A. and Yang W.Z. (2005). Effects of physically effective fiber on intake, chewing activity, and ruminal acidosis for dairy cows fed diets based on corn silage. J. Dairy Sci. 88, 2117-2129.
Beever D.E. (2006). The impact of controlled nutrition during the dry period on dairy cow health, fertility and performance. Anim. Reprod. Sci. 96, 212-226.
Berry D.P., Macdonald K.A., Stafford K., Matthews L. and Roche J.R. (2007). Associations between body condition score, body weight and somatic cell count and clinical mastitis in seasonally calving dairy cattle. J. Dairy Sci. 90, 637-648.
Bhakat C., Chatterjee A., Mandal D.K., Karunakaran M., Mandal A., Garai S. and Dutta T.K. (2017a). Milking management practices and IMI in Jersey crossbred cows in changing scenario. Indian J. Anim. Sci. 87(4), 95-100.
Bhakat C., Chatterjee A., Mandal A., Mandal D.K., Karunakaran M. and Dutta T.K. (2017b). Effect of cleanliness and hygiene on occurrence of mastitis in crossbred cows in WB. Life Sci. Int. Res. J. 4(1), 10-14.
Bharti P., Bhakat C., Ghosh M.K., Dutta T.K. and Das R. (2015). Relationship among intramammary infection and raw milk parameters in Jersey crossbred cows under hot-humid climate. J. Anim. Res. 5(2), 317-320.
Boas D.F.V., Filho A.E.V., Pereira M.A., Junior L.C.R. and Faro L.E. (2017). Association between electrical conductivity and milk production traits in dairy Gyr cows. J. Appl. Anim. Res. 45, 227-233.
Börner S., Derno M., Hacke S., Kautzsch U., Schäff C., Thanthan S., Kuwayama H., Hammon H.M., Röntgen M., Weikard R., Kühn C., Tuchscherer A. and Kuhla B. (2013). Plasma ghrelin is positively associated with body fat, liver fat and milk fat content but not with feed intake of dairy cows after parturition. J. Endocrinol. 216(2), 217-229.
Bouraoui R., Lahmar M., Majdoub A., Djemali M. and Belyea R. (2002). The relationship of temperature-humidity index with milk production of dairy cows in a Mediterranean climate. Anim. Res. 51(6), 479-491.
Busato A., Faissler D., Kupfer U. and Blum J.W. (2002). Body condition scores in dairy cows: Associations with metabolic and endocrine changes in healthy dairy cows. J. Vet. Med. A. 49(9), 455-460.
Butler W.R. (2009). Energy balance relationships with follicular development, ovulation and fertility in postpartum dairy cows. Livest. Prod. Sci. 83, 211-218.
Buttchereit N., Stamer E., Junge W. and Thaller G. (2010). Evaluation of five lactation curve models fitted for fat-protein ratio of milk and daily energy balance. J. Dairy Sci. 93, 1702-1712.
Buttchereit N., Stamer E., Junge W. and Thaller G. (2011). Short communication: Genetic relationships among daily energy balance, feed intake, body condition score, and fat to protein ratio of milk in dairy cows. J. Dairy Sci. 94, 1586-1591.
Caja G., Castro-Costa A. and Knight C.H. (2016). Engineering to support wellbeing of dairy animals. J. Dairy Res. 83, 136-147.
Capper J.L., Cady R.A. and Bauman D.E. (2009). The environmental impact of dairy production: 1944 compared with 2007. J. Anim. Sci. 87, 2160-2167.
Cavestany D., Blanch J.E., Kulcsar M., Uriarte G., Chilibroste P., Meikle A., Febel H., Ferraris A. and Krall E. (2005). Studies of the transition cow under a pasture-based milk production system: metabolic profiles. J. Vet. Med. A. 52, 1-7.
Chapinal N., Carson M., Duffield T.F., Capel M., Godden S., Overton M., Santos J.E. and LeBlanc S.J. (2011). The association of serum metabolites with clinical disease during the transition period. J. Dairy Sci. 94(10), 4897-4903.
Chapinal N., Carson M.E., LeBlanc S.J., Leslie K.E., Godden S., Capel M., Santos J.E., Overton M.W. and Duffield T.F. (2012). The association of serum metabolites in the transition period with milk production and early-lactation reproductive performance. J. Dairy Sci. 95(3), 1301-1309.
Chien E.K., Hara M., Rouard M., Yano H., Philippe M., Polonsky K.S. andBell G.I. (1997). Increase in serum leptin and uterine leptin receptormessengerRNAlevels during pregnancy in rats. Biochem. Biophys. Res. Commun. 2237, 476-480.
Chilibroste P., Soca P., Mattiauda D.A., Bentancur O. and Robinson P.H. (2007). Short term fasting as a tool to design effective grazing strategies for lactating dairy cattle: a review. Australian J. Agric. Res. 47, 1075-1084.
Chilibrostea P., Mattiaudaa D.A., Bentancurb O., Socaa P. andMeiklec A. (2012). Effect of herbage allowance on grazing behavior and productive performance of early lactation primiparous Holstein cows. Anim. Feed Sci. Technol. 173, 201- 209.
Contreras G., Thelen K., Schmidt S.E., Strieder-Barboza C., Preseault C.L., Raphael W., Kiupel M., Caron J. and Lock A.L. (2016). Adipose tissue remodeling in late-lactation dairy cows during feed-restriction-induced negative energy balance. J. Dairy Sci. 99(12), 10009-10021.
Dann H.M., Morin D.E., Bollero G.A., Murphy M.R. and Drackley J.K. (2005). Prepartum intake, postpartum induction of ketosis, and periparturient disorders affect the metabolic status of dairy cows. J. Dairy Sci. 88(9), 3249-3264.
Das R., Sailo L., Verma N., Bharti P., Saikia J., Imtiwati I. and Kumar R. (2016). Impact of heat stress on health and performance of dairy animals: A review. Vet. World. 9(3), 260-268.
Denton D.A., McKinley M.J., Farrell M. and Egan G.F. (2009). The role of primordial emotions in the evolutionary origin of consciousness. Conscious. Cogn. 18, 500-514.
DeVries T.J., Dohme F. and Beauchemin K.A. (2008). Repeated ruminal acidosis challenges in lactating dairy cows at high and low risk for developing acidosis: Feed sorting. J. Dairy Sci. 91, 3958-3967.
DeVries T.J., Holtshausen L., Oba M. and Beauchemin K.A. (2011). Effect of parity and stage of lactation on feed sorting behavior of lactating dairy cows. J. Dairy Sci. 94, 4039-4045.
DeVriese C. and Delporte C. (2008). Ghrelin: A new peptide regulating growth hormone release and food intake. Int. J. Biochem. Cell. Biol. 40, 1420-1424.
Drackley J.K. and Cardoso F.C. (2014). Prepartum and postpartum nutritional management to optimize fertility in high-yielding dairy cows in confined TMR systems. Animal. 8(1), 5-14.
Drackley J.K., Dann H.M., Douglas G.N., Guretzky N.A.J., Litherland N.B., Underwood J.P. and Loor J.J. (2005). Physiological and pathological adaptations in dairy cows that may increase suseptibility to periparturient diseases and disorders. Italian J. Anim. Sci. 4(4), 323-344.
Esposito G., Raffrenato E., Lukamba S.D., Adnane M., Irons P.C., Cormican P., Tasara T. and Chapwanya A. (2020). Characterization of metabolic and inflammatory profiles of transition dairy cows fed an energy-restricted diet. J. Anim. Sci. 98(1), 1-15.
Fenwick M.A., Llewellyn S., Fitzpatrick R., Kenny D.A., Murphy J.J., Patton J. and Wathes D.C. (2008). Negative energy balance in dairy cows is associated with specific changes in IGF-binding protein expression in the oviduct. Reproduction. 135(1), 63-75.
Fish J.A. and DeVries T.J. (2012). Short communication: Varying dietary dry matter concentration through water addition: Effect on nutrient intake and sorting of dairy cows in late lactation. J. Dairy Sci. 95, 850-855.
Garcia A.M.B., Cardoso F.C., Diego X.T. and Gonzalez F.H.D. (2011). Metabolic evaluation of dairy cows submitted to three different strategies to decrease the effects of negative energy balance in early postpartum. Pesq. Vet. Bras. 31(1), 11-17.
Gencoglu H., Shaver R.D., Steinberg W., Ensink J., Ferraretto L.F., Bertics S.J., Lopes J.C. and Akins M.S. (2010). Effect of feedinga reduced-starch diet with or without amylase addition on lactation performance in dairy cows. J. Dairy Sci. 93, 723-732.
Gilmore H.S., Young F.J., Patterson D.C., Wylie A.R.G., Law R.A., Kilpatrick D.J., Elliott C.T. and Mayne C.S. (2011). An evaluation of the effect of altering nutrition and nutritional strategies in early lactation on reproductive performance and estrous behavior of high-yielding Holstein-Friesian dairy cows. J. Dairy Sci. 94, 3510-3526.
Grant R.J. and Ferraretto L.F. (2018). Silage review: Silage feeding management: Silage characteristics and dairy cow feeding behavior. J. Dairy Sci. 101, 4111-4121.
Green T.C. and Mellor D.J. (2011). Extending ideas about animal welfare assessment to include ‘quality of life’ and related concepts. New Zealand Vet. J. 59, 263-271.
Gumen A., Keskin A., Yilmazbas-Mecitoglu G., Karakaya E. and Wiltbank M.C. (2011). Dry period management and optimization of post-partum reproductive management in dairy cattle. Reprod. Domest. Anim. 46(3), 11-17.
Habegger K.M., Heppner K.M., Geary N., Bartness T.J., DiMarchi R. and Tschöp M.H. (2010). The metabolic actions of glucagon revisited. Nat. Rev. Endocrinol. 6(12), 689-697.
Hamzaoui S., Salama A.A.K., Caja G., Albanell E., Flores C. and Such X. (2012). Milk production losses in early lactating dairy goats under heat stress. J. Dairy Sci. 95(2), 672-673.
Heuer C., Van Straalen W.M., Schukken Y.H., Dirkzwager A. and Noordhuizen T.M. (2001). Prediction of energy balance in high yielding dairy cows with test-day information. J. Dairy Sci. 84(2), 471-481.
Hooda O.K. and Singh S. (2010). Effect of thermal stress on feed intake, plasma enzymes and blood bio-chemicals in buffalo heifers. Indian J. Anim. Nutr. 27(2), 122-127.
Hosseini A., Tariq M.R., Trindade da Rosa F., Kesser J., Iqbal Z., Mora O., Sauerwein H., Drackley J.K., Trevisi E. and Loor J.J. (2015). Insulin sensitivity in adipose and skeletal muscle tissue of dairy cows in response to dietary energy level and 2,4-thiazolidinedione (TZD). PLoS One. 10(11), e0142633.
ICAR-DARE-Annual-Report. (2013). Accessed at https://icar.org.in/files/reports/icar-dare-annual-reports/2013-14/climate-change-AR-2013-14.pdf.
Ingvartsen K.L. and Andersen J.B. (2000). Integration of metabolism and intake regulation: A review focusing on periparturient animals. J. Dairy Sci. 83(7), 1573-1597.
IPCC (Inter Governmental Panel on Climate Change). (2007). Climate Change: Synthesis Report. Available at: https://archive.ipcc.ch/.
Itle A.J., Huzzey J.M., Weary D.M. and von Keyserlingk M.A.G. (2015). Clinical ketosis and standing behavior in transition cows. J. Dairy Sci. 98, 128-134.
Janovick N., Boisclair Y. and Drackley J.K. (2011). Prepartum dietary energy intake affects metabolism and health during the periparturient period in primiparous and multiparous Holstein cows. J. Dairy Sci. 94(3), 1385-1400.
Jensen M.B. (2012). Behaviour around the time of calving in dairycows. Appl. Anim. Behav. Sci. 139, 195-202.
Jiang F.G., Lin X.Y., Yan Z.G., Hu Z.Y., Liu G.M., Sun Y.D., Liu X.W. and Wang Z.H. (2017). Effect of dietary roughage level on chewing activity, ruminal pH, and saliva secretion in lactating Holstein cows. J. Dairy Sci. 100, 2660-2671.
Jiang F.G., Lin X.Y., Yan Z.G., Hu Z.Y., Wang Y. and Wang Z.H. (2018). Effect of forage source and particle size on feed sorting, milk production and nutrient digestibility in lactating dairy cows. J. Anim. Physiol. Anim. Nutr. 102, 1472-1481.
Kansal G., Yadav D.K., Singh A.K. and Rajput M.S. (2020). Advances in the management of bovine mastitis. Int. J. Adv. Agric. Sci. Technol. 7(2), 10-22.
Kaufman E.I., LeBlanc S.J., McBride B.W., Duffield T.F. and DeVries T.J. (2016). Short communication: Association of lying behavior and subclinical ketosis in transition dairy cows. J. Dairy Sci. 99, 1-8.
Kawai M., Yamaguchi M., Murakami T., Shima K., Murata Y. and Kishi K. (1997). The placenta is not the main source of leptin production in pregnant rats: gestational profile of leptin in plasma and adipose tissues. Biochem. Biophys. Res. Commun. 240, 798-802.
Kawashima C., Munakata M., Shimizu T., Miyamoto A., Kida K. and Matsui M. (2016). Relationship between the degree of insulin resistance during late gestation and postpartum performance in dairy cows and factors that affect growth and metabolic status of their calves. J. Vet. Med. Sci. 78(5), 739-745.
Kim I.H. and Suh G.H. (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, 1445-1456.
Knegsel A.T., Van den Brand H., Dijkstra J., van Straalen W.M., Heetkamp M.J., Tamminga S. and Kemp B. (2007). Dietary energy source in dairy cows in early lactation: energy partitioning and milk composition. J. Dairy Sci. 90(3), 1467-1476.
Kumari T., Bhakat C. and Singh A.K. (2020). Adoption of management practices by the farmers to control sub clinical mastitis in dairy animals. J. Entomol. Zool. Stud. 8(2), 924-927.
Kumari T., Bhakat C., Singh A.K., Sahu J., Mandal D.K. and Choudhary R.K. (2019). Low cost management practices to detect and control sub-clinical mastitis in dairy cattle. Int. J. Curr. Microbiol. Appl. Sci. 8(5), 1958-1964.
Lacetera N., Bernabucci U., Ronchi B. and Nardone A. (1996). Body condition score, metabolic status and milk production of early lactation dairy cows exposed to warm environment. Rivista Agric. Subtrop. Trop. 90(1), 43-55.
Lake S.L., Scholljegerdes E.J., Hallford D.M., Moss G.E., Rule D.C. and Hess B.W. (2006). Effects of body condition score at parturition and postpartum supplemental fat on metabolite and hormone concentrations of beef cows and their suckling calves. J. Anim. Sci. 84(4), 1038-1047.
LeBlanc S.J., Leslie K.E. and Duffield T.F. (2005). Metabolic predicators of displaced abomasum in dairy cattle. J. Dairy Sci. 88, 159-170.
Lecorps B., Ludwig B.R., von Keyserlingk M.A.G. and Weary D.M. (2019). Pain-Induced Pessimism and Anhedonia: Evidence from a novel probability-based judgment bias test. Front. Behav. 13, 54-63.
Li L., Cao Y., Xie Z. and Zhang Y. (2017). A high-concentrate diet induced milk fat decline via glucagon-mediated activation of AMP-activated protein kinase in dairy cows. Sci. Rep. 7, 44217-44229.
Linzell J.L. and Peaker M. (1971). Mechanism of milk secretion. Physiol. Rev. 51(3), 564-597.
Maffei M., Fei H., Lee G.H., Dani C., Leroy P., Zhang Y., Proenca R., Negrel R., Ailhaud G. and Friedman J.M. (1995). Increased expression in adipocytes of ob RNA in mice lesions of the hypothalamus and with mutations at the db locus. Proc. Natl. Acad. Sci. 92, 6957-6960.
Malek dos Reis C.B., Barreiro J.R., Moreno J.F., Porcinato M.A. and Santos M.V. (2011). Evaluation of somatic cell count thresholds to detect subclinical mastitis in Gyr cows. J. Dairy Sci. 94, 4406-4412.
Maltz E., Barbosa L.F., Bueno P., Scagion L., Kaniyamattam K., Greco L.F., De Vries A. and Santos J.E.P. (2013). Effect of feeding according to energy balance on performance, nutrient excretion, and feeding behavior of early lactation dairy cows. J. Dairy Sci. 96, 5249-5266.
Mann S., Yepes F.A., Overton T.R., Wakshlag J.J., Lock A.L., Ryan C.M. and Nydam D.V. (2015). Dry period plane of energy: Effects on feed intake, energy balance, milk production, and composition in transition dairy cows. J. Dairy Sci. 98(5), 3366-3382.
McArt J.A.A., Nydam D.V. and Oetzel G.R. (2013). Dry period and parturient predictors of early lactation hyperketonemia in dairy cattle. J. Dairy Sci. 96(1), 198-209.
McCann J.P., Bergman E.N. and Beermann D.H. (1992). Dynamic and static phases of severe dietary obesity in sheep: food intakes, endocrinology and carcass and organ chemical composition. J. Nutr. 122, 496-505.
Meeran K., O’Shea D., Edwards C.M., Turton M.D., Heath M.M., Gunn I., Abusnana S., Rossi M., Small C.J., Goldstone A.P., Taylor G.M., Sunter D., Steere J., Choi S.J., Ghatei M.A. and Bloom S.R. (1999). Repeated intracerebroventricular administration of glucagon-like peptide-1-(7-36) amide or exendin-(9-39) alters body weight in the rat. Endocrinology. 140, 244-250.
Mellor D.J. (2012). Animal emotions, behaviour and the promotion of positive welfare states. New Zealand Vet. J. 60, 1-8.
Miller-Cushon E.K. and DeVries T.J. (2017). Associations between feed push-up frequency, feeding and lying behavior and milk yield composition of dairy cows. J. Dairy Sci. 100, 2213–2218.
Mohammed M.A.B., Al-Shami S.A. and Al-Eknah M.M. (2015). Body condition scores at calving and their association with dairy cow performance and health in semiarid environment under two cooling systems. Italian J. Anim. Sci. 14(1), 77-85.
Moore S.M. and DeVries T.J. (2020). Effect of diet-induced negative energy balance on the feeding behavior of dairy cows. J. Dairy Sci. 103(8), 7288-7301.
Novak J., Stojanovski K., Melotti L., Reichlin T., Palme R. and Würbel H. (2016). Effects of stereotypic behaviour and chronic mild stress on judgement bias in laboratory mice. Appl. Anim. Behav. Sci. 174, 162-172.
Nowroozi-Asl A., Aarabi N. and Rowshan-Ghasrodashti A. (2016). Ghrelin and its correlation with leptin, energy related metabolites and thyroidal hormones in dairy cows in transitional period. Polish J. Vet. Sci. 19(1), 197-204.
NRC. (2007). Nutrient Requirements of Small Ruminants, Sheep, Goats, Cervids, and New World Camelids. National Academy Press, Washington, D.C., USA.
Ospina P.A., Nydam D.V., Stokol T. and Overton T.R. (2010). Associations of elevated nonesterified fatty acids and β-hydroxybutyrate concentrations with early lactation reproductive performance and milk production in transition dairy cattle in the northeastern United States. J. Dairy Sci. 93(4), 1596-1603.
Overton T.R. and Waldron M.R. (2004). Nutritional management of transition dairy cows: Strategies to optimize metabolic health. J. Dairy Sci. 87, 105-119.
Paul A., Bhakat C., Mandal D.K., Mandal A., Mohammad A., Chatterjee A. and Rai S. (2018). Influence of udder hygiene management on milk characteristics in Jersey cross-bred cows at lower Gangetic region. Int. J. Curr. Microbiol. Appl. Sci. 7(8), 1264-1272.
Pezeshki A., Mehrzad J., Ghorbani G.R., Rahmani H.R., Collier R.J. and Burvenich C. (2007). Effects of short dry periods on performance and metabolic status in holstein dairy cows. J. Dairy Sci. 90(12), 5531-5541.
Quiroz-Rocha G.F., LeBlanc S., Duffield T., Wood D., Leslie K.E. and Jacobs R.M. (2009). Evaluation of prepartum serum cholesterol and fatty acids concentrations as predictors of postpartum retention of the placenta in dairy cows. J. Am. Vet. Med. Assoc. 234, 790-793.
Reis M.M., Cooke R.F., Ranches J. and Vasconcelos J.L.M. (2012). Effects of calcium salts of polyunsaturated fatty acids on productive and reproductive parameters of lactating Holstein cows. J. Dairy Sci. 95(12), 7039-7050.
Reist M., Erdin D., von Euw D., Tschuemperlin K., Leuenberger H., Chilliard Y., Hammon H.M., Morel C., Philipona C., Zbinden Y., Kuenzi N. and Blum J.W. (2002). Estimation of energy balance at the individual and herd level using blood and milk traits in high-yielding dairy cows. J. Dairy Sci. 85(12), 3314-3327.
Rhoads R.P., Baumgard L.H., Suagee J.K. and Sanders S.R. (2013). Nutritional interventions to alleviate the negative consequences of heat stress. Adv. Nutr. 4(3), 267-276.
Riedy C.A., Chavez M. and Woods S.C. (1995). Central insulin enhances sensitivity to cholecystokinin. Physiol. Behav. 58, 755-760.
Rizvi S.J., Pizzagalli D.A., Sproule B.A. and Kennedy S.H. (2016). Assessing anhedonia in depression: potentials and pitfalls. Neurosci. Biobehav. Rev. 65, 21-35.
Roche J.R. (2007). Milk production responses to pre- and post-calving dry matter intake in grazing dairy cows. Livest. Sci. 110, 12-24.
Roche J.R., Heiser A., Mitchell M.D., Crookenden M.A., Walker C.G., Kay J.K. and Meier S. (2016). Strategies to gain body condition score in pasture-based dairy cows during late lactation and the far-off non-lactating period and their interaction with close-up dry matter intake. J. Dairy Sci. 100(3), 1720-1738.
Roche J.R., Macdonald K.A., Schütz K.E., Matthews L.R., Verkerk G.A., Meier S. and Webster J.R. (2013). Calving body condition score affects indicators of health in grazing dairy cows. J. Dairy Sci. 96(9), 5811-5825.
Ryan G., Murphy J., Crosse S. and Rath M. (2003). The effect of precalving diet on post-calving cow performance. Livest. Prod. Sci. 79(1), 61-71.
Sahu D., Mandal D.K., Dar A.H., Podder M. and Gupta A. (2019). Modification in housing system affects the behavior and welfare of dairy Jersey crossbred cows in different seasons. Biol. Rhythm Res. 52(9), 1303-1312.
Seifi H.A., Gorji-Dooz M., Mohri M., Dalir-Naghadeh B. and Farzaneh N. (2007). Variations of energy-related biochemical metabolites during transition period in dairy cows. Comp. Clin. Pathol. 16, 253-258.
Senturk S., Cihan H., Kasap S., Mecitoglu Z. and Temizel M. (2015). Effects on negative energy balance of tannin in dairy cattle. Uludağ Üniv. Vet. Fak. Derg. 34, 1-7.
Sepúlveda-Varas P., Weary D.M., Noro M. and von Keyserlingk M.A.G. (2015). Transition diseases in grazing dairy cows are related to serum cholesterol and other analytes. PLoS One. 10, e0122317.
Silanikove N. and Koluman N.D. (2015). Impact of climate change on the dairy industry in temperate zones: Predications on the overall negative impact and on the positive role of dairy goats in adaptation to earth warming. Small Rumin. Res. 123, 27-34.
Singh A.K. (2019). Influence of alteration of management practice on performances of dairy cows at lower Gangetic region. MS Thesis. National Dairy Research Institute, Karnal, India.
Singh A.K. and Kumari T. (2019). Assesment of energy reserves in dairy animals through body condition scoring. Indian Dairyman. 10(5), 74-79.
Singh A.K., Bhakat C., Yadav D.K., Kumari T., Mandal D.K., Rajput M.S. and Bhatt N. (2020a). Effect of pre and postpartum Alphatocopherol supplementation on body measurements and its relationship with body condition, milk yield, and udder health of Jersey crossbred cows at tropical lower Gangetic region. J. Entomol. Zool. Stud. 8(1), 1499-1502.
Singh A.K., Bhakat C., Mandal D.K., Mandal A., Rai S., Chatterjee A. and Ghosh M.K. (2020b). Effect of reducing energy intake during dry period on milk production, udder health and body condition score of Jersey crossbred cows at tropical lower Gangetic region. Trop. Anim. Health Prod. 52, 1759-1767.
Singh A.K., Yadav D.K., Bhatt N., Sriranga K.R. and Roy S. (2020c). Housing management for dairy animals under Indian tropical type of climatic conditions-a review. Vet. Res. Int. 8(2), 94-99.
Singh A.K., Bhakat C., Yadav D.K., Kansal G. and Rajput M.S. (2020d). Importance of measuring water intake in dairy animals:a review. Int. J. Adv. Agric. Sci. Technol. 7(2), 23-30.
Singh A.K., Kumari T., Rajput M.S., Baishya A., Bhatt N. and Roy S. (2020e). Review on effect of bedding material on production, reproduction and health of dairy animals. Int. J. Livest. Res. 10, 11-20.
Singh A.K., Bhakat C., Kumari T., Mandal D.K., Chatterjee A. and Dutta T.K. (2020f). Influence of alteration of dry period feeding management on body weight and body measurements of Jersey crossbred cows at lower Gangetic region. J. Anim. Res. 10(1), 137-141.
Singh A.K., Bhakat C., Mohhamad A., Chatterjee A., Karunakaran M. and Ghosh M.K. (2020g). Economic analysis of pre and postpartum alphatocopherol supplementation for milk performance and dry matter ıntake of dairy cows in tropical region. Int. J. Livest. Res. 10(10), 137-143.
Singh A.K., Bhakat C., Mandal D.K. and Chatterjee A. (2020h). Effect of pre and postpartum alpha-tocopherol supplementation on body condition and some udder health parameters of Jersey crossbred cows at tropical lower Gangetic region. J. Anim. Res. 10(5), 697-703.
Singh A.K., Bhakat C., Chatterjee A. and Karunakaran M. (2020i). Influence of alteration in far-off period feeding management on water intake, water and dry matter efficiency, relative immunoglobulin level in dairy cows at tropical climate. J. Anim. Res. 10(5), 741-749.
Singh A.K. (2021). Advancements in management practices from far-off dry period to initial lactation period for improved production, reproduction, and health performances in dairy animals: A review. Int. J. Livest. Res. 11(3), 25-41.
Singh R., Randhawa S.N.S. and Randhawa C.S. (2015). Body condition score and its correlation with ultrasonographic back fat thickness in transition crossbred cows. Vet. World. 8(3), 290-294.
Smith G.L., Friggens N.C., Ashworth C.J. and Chagunda M.G.G. (2017). Association between body energy content in the dry period and post-calving production disease status in dairy cattle. Animal. 11(9), 1590-1598.
Soita H.W., Christensen D.A. and McKinnon J.J. (2000). Influence of particle size on the effectiveness of the fiber in barley silage. J. Dairy Sci. 83, 2295-2300.
Spiers D.E., Spain J.N., Sampson J.D. and Rhoads R.P. (2004). Use of physiological parameters to predict milk yield and feed intake in heat-stressed dairy cows. J. Therm. Biol. 29, 759-764.
Steensels M., Bahr C., Berckmans D., Halachmi I., Antler A. and Maltz E. (2012). Lying patterns of high producing healthy dairy cows after calving in commercial herds as affected by age, environmental conditions and production. Appl. Anim. Behav. Sci. 136(2), 88-95.
Stengel A. and Taché Y. (2013). Activation of somatostatin2 receptors in the brain and the periphery inducesoppo- site changes in circulating ghrelin levels: Functional implications. Front. Endocrinol. 3, 178-187.
Upadhyay R.C., Ashutosh A. and Singh S.V. (2009). Impact of climate change on reproductive functions of cattle and buffalo. Pp. 107-110 in Global Climate Change and Indian Agriculture. ICAR, New Delhi.
Van Hoeij R.J., Kok A., Bruckmaier R.M., Haskell M.J., Kemp B. and van Knegsel A.T.M. (2018). Relationship between metabolic status and behavior in dairy cows in week 4 of lactation. Animal. 13(3), 1-9.
Von Keyserlingk M.A.G. and Weary D.M. (2010). Feeding behaviour of dairy cattle: Measures and applications. Canadian J. Anim. Sci. 90, 303-309.
Wankhade P.R., Manimaran A., Kumaresan A., Jeyakumar S., Ramesha K.P., Sejian V., Rajendran D. and Varghese M.R. (2017). Metabolic and immunological changes in transition dairy cows: A review. Vet. World. 10(11), 1367-1377.
Weary D.M., Droege P. and Braithwaite V.A. (2017). Behavioral evidence of felt emotions: approaches, inferences, and refinements. Adv. Stud. Behav. 49, 27-48.
Xu W., Vervoort J., Saccenti E., van Hoeij R., Kemp B. and van Knegsel A. (2018). Milk metabolomics data reveal the energy balance of individual dairy cows in early lactation. Sci. Rep. 8(1), 15828-15836.
Yalcin I., Barthas F. and Barrot M. (2014). Emotional consequences of neuropathic pain: Insight from preclinical studies. Neurosci. Biobehav. Rev. 47, 154-164.
Yamada T., Kawakami S. and Nakanishi N. (2003). The relationship between plasma leptin concentrations and distribution of body fat in crossbred steers. Anim. Sci. J. 74, 95-100.
Yang W.Z. and Beauchemin K.A. (2006). Effects of physically effective fiber on chewing activity and ruminal pH of dairy cows fed diets based on barley silage. J. Dairy Sci. 89, 217-228.
