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Chelating forms of microelements in poultry nutrition

Published online by Cambridge University Press:  27 February 2014

V.S. STANAĆEV
Affiliation:
Dept. of Animal Science, University of Novi Sad, Faculty of Agriculture, Trg Dositeja Obradovića 8, 21000 Novi Sad, Serbia
N. MILOŠEVIĆ
Affiliation:
Dept. of Animal Science, University of Novi Sad, Faculty of Agriculture, Trg Dositeja Obradovića 8, 21000 Novi Sad, Serbia
V.Ž. STANAĆEV
Affiliation:
Perutnina Ptuj-Topiko ad., Petefi brigade 2, 24300 Bačka Topola, Serbia
N. PUVAČA*
Affiliation:
Dept. of Animal Science, University of Novi Sad, Faculty of Agriculture, Trg Dositeja Obradovića 8, 21000 Novi Sad, Serbia
D. MILIĆ
Affiliation:
Perutnina Ptuj-Topiko ad., Petefi brigade 2, 24300 Bačka Topola, Serbia
Z. PAVLOVSKI
Affiliation:
Institute for Animal Husbandry, Auto put 16, 11080 Zemun, Serbia
*
Corresponding author: [email protected] or [email protected]
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Abstract

The aim of this review was to analyse the available literature on the effects of the use of microelements and their chelated forms on performance parameters of poultry as well as the cholesterol content in the tissues of broiler chickens. Published research has indicated that the significantly lower levels of organic minerals had a positive influence on the production performance of meat poultry and improved the production performance of laying hens and their heavy line hybrid parents. This has major impacts not only in terms of more efficient utilisation of chelated minerals in poultry diets, but also for less excretion of unused inorganic minerals into the environment, which is a major problem in many countries.

Type
Review Article
Copyright
Copyright © World's Poultry Science Association 2014 

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References

ADAMOVIĆ, M., JOVANOVIĆ, R., STOIČEVIĆ, LJ., RADOVANOVIĆ, M., SRETENOVIĆ, LJ., PAVLIĆEVIĆ, A. and VUKIĆ-VRANJEŠ, M. (1997) Rezultati korišćenja organski vezanih mikroelemenata u ishranigoveda. VII Simpozijum Tehnologija Stočne Hrane, Tara, pp. 49-66.Google Scholar
AO, T. and PIERCE, J. (2013) The replacement of inorganic mineral salts with mineral proteinates in poultry diets. World's Poultry Science Journal 69: 5-16.Google Scholar
BROWN, F. and ZERINGUE, K. (1994) Laboratory evaluations of solubility and structural integrity of complexed and chelated trace mineral supplements. Journal of Dairy Science 77: 181-189.Google Scholar
CHERNAVINA, A. (1970) Fiziologiya i Biokhimiya Mikroelementov. Moscow, Vysshayashkola.Google Scholar
DIBNER, J. (2005) Early nutrition of zinc and copper in chicks and poults: impact on growth and immune function. Proceedings of the 3rd Mid-Atlantic Nutrition Conference, Timonium, pp. 213-218.Google Scholar
DIBNER, J., RICHARDS, D., KITCHELL, L. and QUIROZ, A. (2007) Metabolic challenges and early bone development. Journal of Applied Poultry Research 16: 126-137.CrossRefGoogle Scholar
DONOGHUE, D., BROPY, P.O., RATH, M. and BOLAND, M.P. (1995) The effect of proteinated minerals added to the diet on performance of post-partum dairy cows, Biotechnology in the Feed Industry. Proceedings of Alltech XI Annual Symposium, Kentucky, pp. 121-129.Google Scholar
DU, Z., HEMKEN, W. and HARMON, J. (1996) Copper metabolism of Holstein and Jersey cattle fed high dietary sulphate on proteinate. Journal of Dairy Science 79: 1873-1879.Google Scholar
EL-SAMEE, L., EL-WARDANY, I., ALI, N. and ABO-EL-AZAB, O. (2012) Egg quality, fertility and hatchability of laying quails fed diets supplemented with organic zinc, chromium yeast or mannan oligosaccharides. International Journal of Poultry Science 11: 221-224.Google Scholar
FERKET, R., OVIEDO-RONDON, O., MENTE, L., BOHORQUEZ, V., SANTOS, A., GRIMES, L., RICHARDS, D., DIBNER, J. and FELTS, V. (2009) Organic trace minerals and 25-hydroxycholecalciferol affect performance characteristics, leg abnormalities and biomechanical properties of leg bones of turkeys. Poultry Science 88: 118-131.Google Scholar
GEORGIEVSKI, I., ANNENKOV, N. and SAMOKHIN, I. (1982) Mineral nutrition of animals. (Eds) (Butterworths, Academic Press).Google Scholar
GUO, R., HENRY, R., HOLWERDA, A., CAO, J., LITTELL, C., MILES, D. and AMMERMAN, B. (2001) Chemical characteristics and relative bioavailability of supplemental organic copper sources for poultry. Journal of Animal Science 79: 1132-1141.Google Scholar
HUANG, L., LU, L., LI, F., LUO, G. and LIU, B. (2009) Relative bio availabilities of organic zinc source with different chelation strengths for broilers fed a conventional corn-soybean meal diet. Journal of Animal Science 87: 2038-2046.Google Scholar
INVERNIZZI, G., AGAZZI, A., FERRONI, M., REBUCCI, R., FANELLI, A. and BALDI, A. (2013) Effects of inclusion of selenium-enriched yeast in the diet of laying hens on performance, eggshell quality, and selenium tissue deposition. Italian Journal of Animal Science 12: 1-8.Google Scholar
JOKIĆ, Ž., KOVČIN, S. and JOKSIMOVIĆ-TODOROVIĆ, M. (2004) Ishranaživine. Poljoprivrednifakultet, Beograd (University Press).Google Scholar
KESSLER, J., MOREL, I., DUFEY, P. and STERN, A. (2001) Organic zink-verbindungen in der munimast. AgrarForschung 8: 376-381.Google Scholar
KRATZER, H., ALLRED, B., DAVIS, N., MARSHALL, J. and VOHRA, P. (1959) The effects of autoclaving soybean protein and addition of ethylenediaminetetetra acetic acid on biological availability of dietary zinc for turkey poults. Journal of Nutrition 68: 313-319.Google Scholar
MANANGI, K., HAMPTON, T., FISHER, P., RICHARDS, D., VAZQUEZ-ANON, M. and CHRISTENSEN, D. (2010) Impact of feeding lower levels of chelated minerals vs. Industry levels of inorganic trace minerals on broiler performance, yield, foot pad health, and litter mineral concentration. Proceedings of International Poultry Scientific Forum, Atlanta, pp. 122-127.Google Scholar
PETROVIČ, V., NOLLET, L. and KOVAČ, G. (2010) Effect of dietary supplementation of trace elements on the growth performance and their distribution in the breast and thigh muscles depending on the age of broiler chickens. Acta Veterinaria Brno 79: 203-209.Google Scholar
PUPAVAC, S., SINOVEC, Z. and JERKOVIĆ, B. (1999) Uticaj korišćenja organski vezanih mikroelemenata na proizvodne rezultate krmaca. Zbornik naučnih radova, Institut PKB Agroekonomik 5: 483-488.Google Scholar
RAO, S., PRAKASH, B., KUMARI, K., RAJU, M. and PANDA, A. (2013) Effect of supplementing different concentrations of organic trace minerals on performance, antioxidant activity, and bone mineralisation in Vanaraja chickens developed for free range farming. Tropical Animal Health and Production 45: 1-5.Google Scholar
REDDY, A., DWIVEDI, J. and DE WAYNE ASHMED, H. (1992) Mineral chelation generates profit. Misset World Poultry 8: 13-15.Google Scholar
SOLOMON, S. and BAIN, M. (2012) Structural and physical changes in the hen's eggshell in response to the inclusion of dietary organic minerals. British Poultry Science 53: 343-350.Google Scholar
STANAĆEV, V., KOVČIN, S. and PERIĆ, L. (2004) Effect of chelates in nutrition of domestic animals. Book of abstracts of International Conference on Sustainable Agriculture and European Integration Processes, Novi Sad, pp. 119-120.Google Scholar
STANAĆEV, V., KOVČIN, S. and SAVIĆ, S. (1999) Helati u ishranisvinja. Savremenapoljoprivreda 48: 289-293.Google Scholar
WALDROUP, P., FRITTS, C. and YAN, F. (2003) Utilisation of Bio-Mosmannan oligosaccharide and Bioplex copper in broilers diets. International Journal of Poultry Science 2: 44-52.Google Scholar
YILDIZ, A., CUFADAR, Y. and OLGUN, O. (2011) Effects of dietary organic and inorganic manganese supplementation on performance, egg quality and bone mineralisation in laying hens. Review of Medicinal and Veterinary 162: 482-488.Google Scholar