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http://dx.doi.org/10.5333/KGFS.2019.39.4.272

Effect of Barn or Grazing on Biochemical Indices in Prepartum, and Milk Composition in Postpartum of Dairy Cows  

Lim, Dong-Hyun (Dairy Science Division, National Institute of Animal Science, Rural Development Administration)
Ki, Kwang-Seok (Dairy Science Division, National Institute of Animal Science, Rural Development Administration)
Park, Seong-Min (Dairy Science Division, National Institute of Animal Science, Rural Development Administration)
Kim, Sang-Bum (Dairy Science Division, National Institute of Animal Science, Rural Development Administration)
Park, Ji-Hoo (Dairy Science Division, National Institute of Animal Science, Rural Development Administration)
Jung, Jeong Sung (Grassland and Forage Division, National Institute of Animal Science, Rural Development Administration)
Vijayakumar, Mayakrishnan (Dairy Science Division, National Institute of Animal Science, Rural Development Administration)
Kim, Dong-Hyeon (Dairy Science Division, National Institute of Animal Science, Rural Development Administration)
Lee, Hyun-Jeong (Dairy Science Division, National Institute of Animal Science, Rural Development Administration)
Choi, Hee-Chul (Dairy Science Division, National Institute of Animal Science, Rural Development Administration)
Kim, Tae-Il (Dairy Science Division, National Institute of Animal Science, Rural Development Administration)
Publication Information
Journal of The Korean Society of Grassland and Forage Science / v.39, no.4, 2019 , pp. 272-280 More about this Journal
Abstract
The present study was designed to determine the effect of barn or cycle of grazing on changes of biochemical metabolites in prepartum and changes of milk composition in postpartum of dairy cows. For this purpose, a total of sixteen 25 months old Holstein primiparous dairy cows were allocated in two groups (n=8) with an average body weight of 571.61 ± 35.30 kg (Barn) and 578.10 ± 39.20 kg (Grazing). The study was conducted from June 2018 to October 2018. Results revealed that barn raised dairy cows had a higher increase in their serum albumin and calcium level on day 14 prepartum. However, the level of palmitic acid, saturated fatty acid increased significantly, and the level of fat, oleic acid, γ-linoleic acid, arachidonic acid and unsaturated fatty acids decreased significantly in barn raised dairy cow's milk on day 14 postpartum. There were no significant differences observed with respect to all other biochemical metabolites, fatty acids and minerals between barn raised and cycle grazing dairy cows during prepartum and postpartum. Our study results could serve to a better understanding of barn raised cow with respect to changes of biochemical metabolites in prepartum and changes of milk composition, fatty acids and minerals content in grazing dairy cows in postpartum for estimating their physiological status.
Keywords
Blood; Concentrate; Feed efficiency; Health status; Prepartum; Postpartum;
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1 Morales-Almaraz, E., Soldado, A., Gonzalez, A., Martinez-Fernandez, A., Dominguez-Vara, I., de la Roza-Delgado, B. and Vicente, F. 2010. Improving the fatty acid profile of dairy cow milk by combining grazing with feeding of total mixed ration. Journal of Dairy Research. 77:225-230.   DOI
2 Nazifi, S., Saeb, M. and Ghavami, S.M. 2002. Serum lipid profile in Iranian fat-tailed sheep in late pregnancy, at parturition and during the post-parturition period. Journal of Veterinary Medicine A Physiology Pathology Clinical Medicine. 49:9-12.   DOI
3 Palmquist, D.L., Beaulieu, A.D. and Barbano, D.M. 1993. Feed and animal factors influencing milk fat composition. Journal of Dairy Science. 76:1753-1771.   DOI
4 Pechova, A., Illek, J. and Halouzka, R. 1997. Diagnosis and control of the development of hepatic lipidosis in dairy cows in the periparturient period. Acta Veterinaria Brno. 66:235-243.   DOI
5 Pelletier, G., Tremblay, A.V. and Helie, P. 1985. Facteurs influençant le profil metanologie des vaches laitičres. The Canadian Veterinary Journal. 26:306-311.
6 Peterson, R.G. and Waldern, D.E. 1981. Repeatabilities of serum constituents in Holstein-Friesians affected by feeding, age, lactation, and pregnancy. Journal of Dairy Science. 64:822-831.   DOI
7 Pirila, S., Taskinen, M. and Viljakainen, H. 2011. Infant milk feeding influences adult bone health: A prospective study from birth to 32 years. PLoS One. 6:e19068.   DOI
8 Roche, J.R., Friggens, N.C. and Kay, J.K. 2009. Invited review: Body condition score and its association with dairy cow productivity, health and welfare. Journal of Dairy Science. 92:5769-5801.   DOI
9 AbuGhazaleh, A.A., Felton, D.O. and Ibrahim, S.A. 2007. Milk conjugated linoleic acid response to fish oil and sunflower oil supplementation to dairy cows managed under two feeding systems. Journal of Dairy Science. 90:4763-4769.   DOI
10 Abdel-Raheem, S.M., Stur, S.I. and Iben, C. 2010. The use of blood profile, milk composition and body condition to evaluate the metabolic and nutritional status of Simmental dairy cows. Science Congress Faculty Veterinary Medicine Assiut Veterinary Medical Journal. 97:449-467.
11 Auldist, M.J., Marett, L.C., Greenwood, J.S., Hannah, M., Jacobs, J.L. and Wales, W.J. 2013. Effects of different strategies for feeding supplements on milk production responses in cows grazing a restricted pasture allowance. Journal of Dairy Science. 96:1218-1231.   DOI
12 Avondo, M., Bonanno, M., Pagano, R.I., Valenti, B., Di Grigoli, A., Alicata, M.L., Galofaro, V. and Pennisi, P. 2008. Milk quality as affected by grazing time of day in Mediterranean goats. Journal of Dairy Research. 75:48-54.   DOI
13 Bargo, F., Delahoy, J.E., Schroeder, G.F. and Muller, L.D. 2006. Milk fatty acid composition of dairy cows grazing at two pasture allowances and supplemented with different levels and sources of concentrate. Animal Feed Science and Technology. 125:17-31.   DOI
14 Seifi, H.A., Mohri, M. and Ehsani, A. 2005. Interpretation of bovine serum total calcium: effects of adjustment for albumin and total protein. Comparative Clinical Pathology. 14:155-159.   DOI
15 Rollin, E., Berghaus, R.D. and Rapnicki, P. 2010. The effect of injectable butaphosphan and cyanocobalamin on postpartum serum ${\beta}$-hydroxybutyrate, calcium and phosphorus concentrations in dairy cattle. Journal of Dairy Science. 93:978-987.   DOI
16 Roubies, N., Panouis, N. and Fytianou, A. 2006. Effects of age and reproductive stage on certain serum biochemical parameters of Chios sheep under greek rearing conditions. Journal of Veterinary Medicine A. Physiology Pathology Clinical Medicine. 53:277-281.   DOI
17 Sandra, S., Ho, M. and Alexander, M. 2012. Effect of soluble calcium on the renneting properties of casein micelles as measured by rheology and diffusing wave spectroscopy. Journal of Dairy Science. 95:75-82.   DOI
18 Scamell, J.M. 2006. Healthy land for healthy cattle. Cattle Practice. 14:143-152.
19 Schroeder, G.F., Delahoy, J.E. and Vidaurreta, I. 2003. Milk fatty acid composition of cows fed a total mixed ration or pasture plus concentrates replacing corn with fat. Journal of Dairy Science. 86:3237-3248.   DOI
20 Soriano, F.D., Polan, C.E. and Miller, C.N. 2001. Supplementing pasture to lactating holsteins fed a total mixed ration diet. Journal of Dairy Science. 84:2460-2468.   DOI
21 Sretenovic, L.J., Petrovic, M.P. and Aleksic, S. 2008. Influence of yeast, probiotics and enzymes in rations on dairy cows performances during transition. Biotechnology in Animal Husbandry. 24:33-43.   DOI
22 Stadnik, L., Duchacek, J. and Beran, J. 2015. Relationships between milk fatty acids composition in early lactation and subsequent reproductive performance in Czech Fleckvieh cows. Animal Reproduction Science. 155:75-79.   DOI
23 Cashman, K.D. 2011. Milk salts: macroelements, nutritional significance. In: Fuquay JW, Fox PF, McSweeney PLH, editors. Encyclopedia of dairy sciences. Vol. 3. London, UK: Academic Press. pp. 925-932.
24 Stockdale, C.R., Waler, G.P., Wales, W.J., Dalley, D.E., Birkett, A., Shen, Z. and Doyle, P.T. 2003. Influence of pasture and concentrates in the diet of grazing dairy cows on the fatty acid composition of milk. Journal of Dairy Research. 70:267-276.   DOI
25 Bargo, F., Muller, L.D., Delahoy, J.E. and Cassidy, T.W. 2002. Performance of high producing dairy cows with three different feeding systems combining pasture and total mixed rations. Journal of Dairy Science. 85:2948-2963.   DOI
26 Belury, M.A. 2002. Dietary conjugated linoleic acid in health: physiological effects and mechanisms of action. Annual Review of Nutrition. 22:505-531.   DOI
27 Bulent, E., Mustafa, K. and Ozgul, M.E. 2006. Evaluation of liver function tests in cows during periparturient period. Firat Universitesi Saglik Bilimleri Dergisi. 20:205-209.
28 Capper, J.L., Cady, R.A. and Bauman, D.E. 2009. The environmental impact of dairy production: 1944 compared with 2007. Journal of Animal Science. 87:160-2167.
29 Chilliard, Y., Ferlay, A. and Mansbridge, R. 2000. Ruminant milk fat plasticity: Nutritional control of saturated, polyunsaturated, trans and conjugated fatty acids. Ann De Zootechnie. 49:181-205.   DOI
30 Stojevic, Z., Piršljin, J. and Milinkovic-Tur, S. 2005. Activities of AST, ALT and GGT in clinically healthy dairy cows during lactation and in the dry period. Veterinarski Archives. 75:67-73.
31 Tsioulpas, A., Lewis, M.J. and Grandison, A.S. 2007. Effect of minerals on casein micelle stability of cows' milk. Journal of Dairy Research. 74:167-173.   DOI
32 Vasta, V., Pagano, R.I., Luciano, G., Scerra, M., Caparra, P., Foti, F., Cilione, C., Biondi, L., Priolo, A. and Avondo, M. 2012. Effect of morning vs. afternoon grazing on intramuscular fatty acid composition in lamb. Meat Science. 90:93-98.   DOI
33 Vibart, R.E., Fellner, V., Burns, J.C., Huntington, G.B. and Green, J.T. 2008. Performance of lactating dairy cows fed varying levels of total mixed ration and pasture. Journal of Dairy Research. 75:471-480.   DOI
34 Wheelock, J.B., Rhoads, R.P. and Vanbale, S. 2010. Effects of Heat stress on energetic metabolism in lactating Holstein cows. Journal of Dairy Science. 93:644-655.   DOI
35 Ferrell, C.L. 1991. Maternal and fetal influences on uterine and conceptus development in the cow: II. Blood Flow and nutrient flux. Journal of Animal Science. 69:1954-1965.   DOI
36 Cruywagen, C.W., Taylor, S. and Beya, M.M. 2015. The effect of buffering dairy cow diets with limestone, calcareous marine algae, or sodium bicarbonate on ruminal pH profiles, production responses, and rumen fermentation. Journal of Dairy Science. 98:5506-5514.   DOI
37 Cuadrado, F., Morales-Almaraz, E., de la Roza-Delgado, B., MartinezFernandez, A. and Vicente, F. 2011. Voluntary unifeed ration intake by grazing dairy cows according their physiologic state. In Proceedings of the 15th ESVCN Congress 153.
38 Dewhurst, R.J., Shingfield, K.J., Lee, M.R.F. and Scollan, N.D. 2006. Increasing the concentrations of beneficial polyunsaturated fatty acids in milk produced by dairy cows in high-forage systems. Animal Feed Science and Technology. 131:168-206.   DOI
39 Elgersma, A., Ellen, G., Bekker, P.R., van der Horst, H., Boer, H. and Tamminga, S. 2003. Effects of perennial ryegrass (Lolium perenne) cultivars with different linolenic acid contents on milk fatty acid composition. Aspects of Applied Biology. 70:107-114.
40 Ferlay, A., Martin, B., Pradel, P.H., Coulon, J.B. and Chilliard, Y. 2006. Influence of grass-based diets on milk fatty acid composition and milk lipolytic system in Tarentaise and Montbeliarde cow breeds. Journal of Dairy Science. 89:4026-4041.   DOI
41 Gaucheron, F. 2005. The minerals of milk. Reproduction Nutrition Development. 45:473-483.   DOI
42 Hernandez-Mendo, O., von Keyserlingk, M.A.G., Veira, D.M. and Weary, D.M. 2007. Effects of pasture on lameness in dairy cows. Journal of Dairy Science. 90:1209-1214.   DOI
43 Goff, J.P. 2000. Pathophysiology of calcium and phosphorus disorders. The Veterinary Clinics of North America. Food Animal Practice. 16:319-337.   DOI
44 Gregorini, P., Soder, K.J. and Sanderson, M.A. 2008. Case study: A snapshot in time of fatty acids composition of grass herbage as affected by time of day. The Professional Animal Scientist. 24:1-6.   DOI
45 Gregorini, P., Soder, K.J., Sanderson, M.A. and Ziegler, G.R. 2009. Toughness, particle size and chemical composition of meadow fescue (Festuca pratensis Hud.) herbage as affected by time of day. Animal Feed Science and Technology. 151:330-336.   DOI
46 Khanal, R.C., Dhiman, T.R. and Boman, R.L. 2008. Changes in fatty acid composition of milk from lactating dairy cows during transition to and from pasture. Livestock Science. 114:164-175.   DOI
47 Holt, C. and Jenness, R. 1984. Interrelationships of constituents and partition of salts in milk samples from eight species. Comparative Biochemistry and Physiology A: Physiology. 77:275-282.   DOI
48 Horne, D.S. 2016. Ethanol stability and milk composition. In: McSweeney PLH, O'Mahony JA, editors. Advanced dairy chemistry. Vol 1B: proteins: applied aspects. 4th Ed. New York, NY: Springer. pp. 225-246.
49 Huzzey, J.M., Veira, D.M., Weary, D.M. and von Keyserlingk, M.A.G. 2007. Prepartum behavior and dry matter intake identify dairy cows at risk for metritis. Journal of Dairy Science. 90:3220-3230.   DOI
50 Kennedy, E., Curran, J., Mayes, B., McEvoy, M., Murphy, J.P. and O'Donovan, M. 2011. Restricting dairy cow access time to pasture in early lactation: The effects on milk production, grazing behaviour and dry matter intake. Animal. 5:1805-1813.   DOI
51 Liesegang, A. 2008. Influence of anionic salts on bone metabolism in periparturient dairy goats and sheep. Journal of Dairy Science. 91:2449-2460.   DOI
52 Little, W. 1974. An effect of the stage of lactation on the concentration of albumin in the serum of dairy cows. Research in Veterinary Science. 17:193-199.   DOI
53 Morales-Almaraz, E., de la Roza-Delgado, B., Gonzalez, A., Soldado, A., Rodriguez, M.L., Pelaez, M. and Vicente, F. 2011. Effect of feeding system on unsaturated fatty acid level in milk of dairy cows. Renewable Agriculture and Food Systems. 26:224-229.   DOI