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Estimation of Zn requirement in wheat-soy diet through growth performance responses in broiler chickens

Document Type : Research Paper

Authors

1 Department of animal Science, Faculty of Agriculture, Ferdowsi University of Mashhad, Mashhad, Iran

2 Department of Animal Science, Faculty of Agriculture, Ferdowsi University of Mashhad, Mashhad, Iran

Abstract

The present study was conducted to determine the zinc (Zn) requirement in broiler chickens fed wheat-soy based diet. Two hundred fifty day-old broiler chicks (Ross 308), were randomly assigned to a completely randomised design (CRD) experiment with 5 treatments, and 5 replicates of 10b each. The experimental treatments included five dietary Zn levels (30, 70, 110, 150, and 190 mg/kg) provided by the addition of reagent grade “ZnSO4.7H2O”. The experiment lasted from 1-42d of age. Increasing dietary Zn level to 70mg/kg significantly increased 10, 24 and 42d live body weight (LBW), feed intake (FI) and weight gain (WG) during 1-10, 25-42 and 1-42d of age and feed efficiency (FE) during 1-10d of age. The linear broken-line (LBL), quadratic-broken line (QBL) and the quadratic polynomial (QP) regression models were used to estimate the Zn requirement. The Zn requirement for optimal final LBW and FI, WG, and FE during 1-42d of ages by LBL model were 68.77, 83.12, 66.99 and 62.75 mg/kg of diet, and by QBL model 70.00, 79.93, 69.63 and 58.01 mg/kg of diet, respectively. In conclusion, Zn requirement varied between 58-83 mg/kg, which is higher than NRC and is lower than strain recommendation in the broiler chickens fed wheat-based diet.

Keywords

References
1.      Ao T, Pierce JL, Pescatore AJ, Cantor AH, Dawson KA, Ford MJ and Shafer BL (2007) Effects of organic zinc and phytase supplementation in a maize-soybean meal diet on the performance and tissue zinc content of broiler chicks. British Poultry Science. 48: 690-695.
2.      Ao T, Pierce JL, Power R, Dawson KA, Pescatore AJ, Cantor AH and Ford MJ (2006) Evaluation of Bioplex Zn® as an organic zinc source for chicks. International Journal of Poultry Science. 5: 808-811.
3.      Ao T, Pierce JL, Power R, Pescatore AJ, Cantor AH, Dawson KA and Ford MJ (2009) Effects of feeding different forms of zinc and copper on the performance and tissue mineral content of chicks. Poultry Science. 88: 2171-2175.
4.        Aviagen (2014) Ross 308: broiler nutrition specification, In: Aviagen Inc., H., AL (ed.), USA.
5.      Bao YM, Choct M, Iji PA and Bruerton K (2007) Effect of organically complexed copper, iron, manganese, and zinc on broiler performance, mineral excretion, and accumulation in tissues. Journal of Applied Poultry Research. 16: 448-755.
6.      Bartlett JR and Smith MO (2003) Effects of different levels of zinc on the performance and immunocompetence of broilers under heat stress. Poultry Science. 82: 1580-1588.
7.      Batal AB, Parr TM, and Baker DH (2001) Zinc bioavailability in tetrabasic zinc chloride and dietary zinc requirement of young chicks fed a soy concentrate diet. Poultry Science 80: 87-90.
8.      Bedford M and Partrige G (2010) Enzymes in farm animal nutrition. 2nd edn. CAB International Publisher.
9.      Brandeo-Neto J, Stefan V, Mendonca B, Bloise W and Castro A (1995) The essential role of zinc in growth. Nutrition Research. 15(3): 335-358.
10.   Burrell AL, Dozier WA, Davis AJ, Compton MM, Freeman ME, Vendrell PF and Ward TL (2004) Responses of broilers to dietary zinc concentrations and sources in relation to environmental implications. British Poultry Science 45: 225-263.
11.   Cao J, Henry PR, Guo R, Holwerda RA, Toth JP, Littrell RC, Miles RD and Ammerman CB (2000) Chemical characteristics and relative bioavailability of supplemental organic zinc sources for poultry and ruminants. Journal of Animal Science. 78: 2039-2054.
12.   Cobb-Vantress (2014) Cobb 500 broiler performance and nutrition supplement, In: Aviagen Inc., H., AL, (ed.), USA.
13.   Collins NE and Moran ET (1999) Influence of supplemental manganese and zinc on live performance and carcass quality of diverse broilers strains. Journal of Applied Poultry Research. 8: 228-235.
14.   Dozier WA, Davis AJ, Freeman ME and Ward TL (2003) Early growth and environmental implications of dietary zinc and copper concentrations and sources of broiler chicks. British Poultry Science. 44(5): 726-731.
15.   Ebrahimi E, Sobhani RS and Zarghi H (2017) Effect of triticale level and exogenous enzyme in the grower diet on performance, gastrointestinal tract relative weight, jejunal morphology and blood lipids of Japanese quail (Coturnix coturnix Japonica). Journal of Agricultural Science and Technology. 19: 569-580.
16.   Hegazy SM and Adachi Y (2000) Comparison of the effects of dietary Selenium, zinc and selenium and zinc supplementation on growth and immune response between chick groups that were inoculated with salmonella and aflatoxin or salmonella. Poultry Science. 79: 331-335.
 
17.   Hess JB, Bilgili SF, Parson AM and Downs KM (2001) Influence of complexed zinc products on live performance and carcass grade of broilers. Journal of Appllied Animal Research. 19: 49-60.
18.   Huang YL, Lu L, Luo XG and Liu B (2007) An optimal dietary zinc level of broiler chicks fed a corn-soybean meal diet. Poultry Science. 86: 2582-2589.
19.   Hudson BP, Dozier WA, Fairchild BD, Wilson JL, Sander JE and Ward TL (2004) Live performance and immune responses of straight-run broilers: influences of zinc source in broiler breeder hen and progeny diets and ambient temperature during the broiler production period. Journal of Appllied Poultry Research. 13: 291-301.
20.   Jahanian R and Rasouli E (2015) Effects of dietary substitution of zinc-methionine for inorganic zinc sources on growth performance, tissue zinc accumulation and some blood parameters in broiler chicks. Journal of Animal Physiology and Animal Nutrition. 99(1):50-58.
21.   Kaps M and Lamberson WR (2004) Biostatistics for Animal Science. CABI Pub.
22.   Kennedy KJ, Rains TM and Shay NF (1998) Zinc deficiency changes preferred macronutrient intake in subpopulations of Sprague-Dewley out bred rats and reduces hepatic pyruvate kinase gene expression. Journal of Nutrition. 128 (1): 43-49.
23.   Kidd M, Anthony N, Newberry L and Lee S (1993) Effect of supplemental zinc in either a corn–soybean or a milo and corn–soybean meal diet on the performance of young broiler breeders and their progeny. Poultry Science 72: 1492-1499.
24.   Kidd MT, Ferket PR and Quresh MA (1996) Zinc metabolism with special reference to its role in immunity. World’s Poult Science Journal. 52: 309-323.
25.   Kim WK and Patterson PH (2004) Effects of dietary zinc supplementation on broiler performance and nitrogen loss from manure. Poultry Science. 83: 34-38.
26.   Lesson S and Summers JD (2005) Commercial poultry nutrition. Nottingham University Press, Manor Farm, Church Lane, Thrumpton, Nottingham, NG11 0AX, England.
27.   McDonald RS (2005) The role of zinc in growth and cell proliferation. Journal of Nutrition. 130: 1500S-1508S.
28.   National Research Council (1994) Nutrient requirements of poultry. 9 edn. National Academy Press, Washington, DC.
29.   Pimental JL, Cook ME and Greger JL (1991) Immune response of chicks fed various levels of zinc. Journal of Poultry Science. 70: 947-954.
30.   Robbins KR, Saxton AM and Southern LL (2006) Estimation of nutrient requirements using broken-line regression analysis. Journal of  Animal Science. 84: Suppl: E155-165.
31.   Rossi P, Rutz F, Anciuti MA, Rech JL and Zauk NHF (2007) Influence of graded levels of organic zinc on growth performance and carcass traits of broilers. Journal  of Appllied  Poultry Research. 16: 219-225.
32.   Salim HM, Cheorun J and Lee BD (2008) Zinc in broiler feeding and nutrition. Avian Biology Research. 1(1): 5-18.
33.   Sandoval M, Henry PR, Littell RC, Miles RD, Butcher GD and Ammerman CB (1999) Effect of dietary zinc source and method of oral administration on performance and tissue trace mineral concentration of broiler chicks. Journal of animal Science. 77: 1788-1799.
34.   Sandoval M, Henry PR, Luo XG, Littell RC, Miles RD and Ammerman CB (1998) Performance and tissue zinc and metallothionine accumulation in chicks fed a high dietary level of zinc. Poultry Science. 77: 1354-1363.
35.   SAS (2003) User's guide: Statistics. S.A.S Institute Cary, NC.
36.   Sunder GS, Panda AK, Gopinath NCS, Rama Rao SV, Raju MVLN, Reddy MR and Kumar CV (2008) Effects of higher levels of zinc supplementation on performance, mineral availability and immune competence in broiler chickens. Journal of Appled Poultry Research. 17: 79-86.
37.   Swinkels JW, Kornegay ET and Verstegen MW (1994) Biology of zinc and biological value of dietary organic zinc complexes and chelates. Nutrition Research Reviews. 7: 129-149.
38.   Tabatabaei YF, Golian A, Zarghi H and Varidi M (2017) Effect of wheat-soy diet nutrient density and guanidine acetic acid supplementation on performance and energy metabolism in broiler chickens. Italian Journal of Animal Science. 16: 593-600.
39.   Wang X, Fosmire GJ, Gay CV and Leach RM (2002) Short-term zinc deficiency inhibits chondrocyte proliferation and induces cell apoptosis in the epiphyseal growth plate of young chickens. Journal of Nutrition. 132: 665-673.
40.   Wedekind KJ, Hortin AE and Baker DH (1992) Methodology for assessing zinc bioavailability: Efficacy estimates for zincmethionine, zinc sulfate, and zinc oxide. Journal of Animal Science. 70: 178-187.
41.   Zarghi H (2018) Application of xylanas and β-glucanase to improve nutrient utilization in poultry fed cereal base diets: Used of enzymes in poultry diet. Insights in Enzyme Research. 2(1):11-17.
 
 
Animal Production
Volume 20, Issue 4
February 2019
Pages 577-587
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