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Levels of copper and zinc in diets for growing and finishing pigs can be reduced without detrimental effects on production and mineral status*

Published online by Cambridge University Press:  01 December 2008

A. Hernández*
Affiliation:
School of Veterinary and Biomedical Sciences, Murdoch University, Murdoch 6150, Western Australia, Australia
J. R. Pluske
Affiliation:
School of Veterinary and Biomedical Sciences, Murdoch University, Murdoch 6150, Western Australia, Australia
D. N. D’Souza
Affiliation:
Alltech Biotechnology P/L, 64-70 Nissan Drive, Dandenong South, 3175, Victoria, Australia
B. P. Mullan
Affiliation:
Department of Agriculture and Food of Western Australia, Locked Bag No. 4, Bentley Delivery Centre, Western Australia 6983, Australia
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Abstract

One hundred and sixty pigs were used to evaluate dietary copper (Cu) and zinc (Zn) supplementation on performance, fecal mineral levels, body mineral status and carcass and meat quality. Diets differed in mineral form (MF) (Cu and Zn in the form of proteinate amino acid chelate (organic) or sulfate (inorganic)) and inclusion level (IL) (27 mg/kg of total Cu and 65 mg/kg of total Zn (‘low’) or 156 mg/kg of total Cu and 170 mg/kg of total Zn (‘high’)) according to a 2 × 2 factorial arrangement of treatments. Pigs were used from 25 to 107 kg body weight (BW) and fed their respective diets ad libitum. Blood and fecal samples were collected on days 14 and 77 of the experiment. Blood was analyzed for concentration of Cu and Zn, hemoglobin (Hb), Cu content of red blood cells (RBC Cu) and alkaline phosphatase (ALP) and feces for Cu and Zn concentration. Hot carcass weight (HCW) and backfat depth were measured at slaughter and indices of meat quality were assessed on a section of longissimus thoracis. Liver, kidney and bone samples were collected immediately after slaughter and liver and kidney were tested for Cu and Zn content, while bone was only tested for Zn. Over the entire experimental period (25 to 107 kg BW) no significant treatment differences in average daily gain (ADG) or average daily feed intake (ADFI) occurred; however, feed conversion ratio (FCR) was improved by the inclusion of proteinate amino acid chelate (P = 0.012). Copper and Zn concentrations in feces were in direct proportion to the IL in the diet. Blood mineral levels were within normal physiological ranges in all treatments and tissue Cu and Zn concentrations increased with dietary IL (P < 0.05). Results indicate that Cu and Zn fecal concentrations were reduced by approximately 6-fold for Cu and by 2.5-fold for Zn by feeding 27 mg/kg Cu and 65 mg/kg Zn, in either the proteinate amino acid chelate or the sulfate form, compared with a diet containing 156 mg/kg Cu and 170 mg/kg Zn. This decrease in total dietary Cu and Zn did not reduce performance or mineral status of pigs.

Type
Full Paper
Copyright
Copyright © The Animal Consortium 2008

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Footnotes

*

This project was funded in part by Alltech Biotechnology P/L. Dandenong South 3175, Australia.

References

Apgar, GA, Kornegay, ET 1996. Mineral balance of finishing pigs fed copper sulfate or a copper-lysine complex at growth-stimulating levels. Journal of Animal Science 74, 15941600.CrossRefGoogle ScholarPubMed
Apgar, GA, Kornegay, ET, Lindemann, MD, Notter, DR 1995. Evaluation of copper sulfate and a copper lysine complex as growth promoters for weanling swine. Journal of Animal Science 73, 26402646.CrossRefGoogle Scholar
Bosi, P, Cacciavillani, JA, Casini, L, Lo Fiego, DP, Marchetti, M, Mattuzzi, S 2000. Effects of dietary high-oleic acid sunflower oil, copper and vitamin E levels on the fatty acid composition and the quality of dry cured Parma ham. Meat Science 54, 119126.CrossRefGoogle ScholarPubMed
Byrne, D 2003. Commission Regulation (EC) No. 1334/2003 of July 2003 amending the conditions for authorization of a number of additives in feedingstuffs belonging to the group of trace elements. Official Journal of the European Union L 187, 1115.Google Scholar
Cao, J, Henry, PR, Davis, SR, Cousins, RJ, Miles, RD, Littell, RC, Ammerman, CB 2002. Relative bioavailability of organic zinc sources based on tissue zinc and metallothionein in chicks fed conventional dietary zinc concentrations. Animal Feed Science and Technology 101, 161170.CrossRefGoogle Scholar
Carlson, MS, Hoover, SL, Hill, GM, Link, GE, Ward, TL 1997. The impact of organic and inorganic sources of zinc supplementation on intestinal metallothionein concentration in the nursery pig. Journal of Animal Science 75, 188.Google Scholar
Carlson, MS, Boren, CA, Wu, C, Huntington, CE, Bollinger, DW, Veum, TL 2004. Evaluation of various inclusion rates of organic zinc either as polysaccharide or proteinate complex on the growth performance, plasma, and excretion of nursery pigs. Journal of Animal Science 82, 13591366.CrossRefGoogle ScholarPubMed
Case, CL, Carlson, MS 2002. Effect of feeding organic and inorganic sources of additional zinc on growth performance and zinc balance in nursery pigs. Journal of Animal Science 80, 19171924.CrossRefGoogle ScholarPubMed
Cheng, J, Kornegay, ET, Schell, T 1998. Influence of dietary lysine on the utilization of zinc from zinc sulfate and a zinc-lysine complex by young pigs. Journal of Animal Science 76, 10641074.CrossRefGoogle Scholar
Close, WH 2002. Trace mineral nutrition in pigs: working within the new recommendations. In Proceedings of the Alltech’s 18th Annual Symposium (ed. TP Lyons and KA Jacques), pp. 401406. Nottingham University Press, Nottingham, United Kingdom.Google Scholar
Creech, BL, Spears, JW, Flowers, WL, Hill, GM, Lloyd, KE, Armstrong, TA, Engle, TE 2004. Effect of dietary trace mineral concentration and source (inorganic vs. chelated) on performance, mineral status, and fecal mineral excretion in pigs from weaning through finishing. Journal of Animal Science 82, 21402147.CrossRefGoogle ScholarPubMed
Davis, ME, Maxwell, CV, Brown, DC, de Rodas, BZ, Johnson, ZB, Kegley, EB, Hellwig, DH, Dvorak, RA 2002. Effect of dietary mannan oligosaccharides and (or) pharmacological additions of copper sulfate on growth performance and immunocompetence of weanling and growing-finishing pigs. Journal of Animal Science 80, 28872894.CrossRefGoogle ScholarPubMed
Fremaut, D 2003. Trace mineral proteinates in modern pig production: reducing mineral excretion without sacrificing performance. In Proceedings of Alltech’s 19th Annual Symposium (ed. TP Lyons and KA Jacques), pp. 171178. Nottingham University Press, Nottingham, United Kingdom.Google Scholar
Henman, D 2001. Organic mineral supplements in pig nutrition: performance and meat quality, reproduction and environmental responses. In Proceedings of Alltech’s 17th Annual Symposium (ed. TP Lyons and KA Jacques), pp. 297304. Nottingham University Press, Nottingham, United Kingdom.Google Scholar
Jensen, C, Flensted-Jensen, M, Skibsted, LH, Bertelsen, G 1998. Effects of Dietary Rape Seed Oil, Copper(II) Sulphate and Vitamin E on Drip Loss, Colour and Lipid Oxidation of Chilled Pork Chops Packed in Atmospheric Air or in a High Oxygen Atmosphere. Meat Science 50, 211221.CrossRefGoogle ScholarPubMed
Jondreville C and Revy PS 2003. An update on use of organic minerals in swine nutrition. In Proceedings of the Eastern Nutrition Conference, pp. 1–16. Quebec, Canada.Google Scholar
Kauffman, RG, Eikelenboom, G, van der Wal, PG, Merkus, G, Zaar, M 1986. The use of filter paper to estimate drip loss of porcine musculature. Meat Science 18, 191200.CrossRefGoogle ScholarPubMed
Kawas, JR, Moreno, JM, Sepulveda, JI, Alejo, TE, Garza, JF 1996. Dietary effects of fat and/or copper sulphate on performance of finishing pigs. Journal of Animal Science 74, 183.Google Scholar
Klasing, KC 2001. Protecting animal health and well-being: nutrition and immune function. Scientific advances in animal nutrition: promise for the New Century. NRC. National Academy Press, Washington, DC.Google Scholar
McGrath, SP, Chaudri, AM, Giller, KE 1995. Long-term effect of metals in sewage sludge on soils microorganisms and plants. Journal of Industrial Microbiology 14, 94104.CrossRefGoogle ScholarPubMed
Mullan, BP, Wilson, RH, Harris, D, Allen, JA, Naylor, A 2002. Supplementation of weaner pig diets with zinc oxide or Bioplex zinc. In Proceedings of Alltech’s 18th Annual Symposium (ed. TP Lyons and KA Jacques), pp. 419424. Nottingham University Press, Nottingham, United Kingdom.Google Scholar
NRC 1998. Nutrient requirements of swine, 9th revised edition. Natl. Acad. Press, Washington, DC.Google Scholar
Puls, R 1994. Mineral levels in animal health – diagnostic data, 2nd edition. Sherpa International, Clearbrook, DC, Canada.Google Scholar
Reeves, PG 1995. Adaptation responses in rats to long-term feeding of high-zinc diets: emphasis on intestinal metallothionein. The Journal of Nutritional Biochemistry 6, 4854.CrossRefGoogle Scholar
Scheuhammer, AM, Cherian, MG 1991. Quantification of metallothionein by silver saturation. Methods of enzymology 205, 7883.CrossRefGoogle ScholarPubMed
Schiavon, S, Bailoni, L, Ramanzin, M, Vincenzi, R, Simonetto, A, Bittante, G 2000. Effect of proteinate or sulphate mineral sources on trace elements in blood and liver of piglets. Animal Science 71, 131139.CrossRefGoogle Scholar
Smits, RJ, Henman, DJ 2000. Practical experiences with Bioplexes in intensive pig production. In Proceedings of the Alltech’s 16th Annual Symposium (ed. TP Lyons and KA Jacques), pp. 293300. Nottingham University Press, Nottingham, United Kingdom.Google Scholar
Stansbury, WF, Tribble, LF, Orr, DE 1990. Effect of chelated copper sources on performance of nursery and growing pigs. Journal of Animal Science 68, 13181322.CrossRefGoogle ScholarPubMed
Underwood, EJ, Suttle, NF 1999. The mineral nutrition of livestock, 3rd edition. CABI Publishing, United Kingdom.CrossRefGoogle Scholar
van Heugten, E, Spears, J, Kegley, E, Ward, J, Qureshi, M 2003. Effects of organic forms of zinc on growth performance, tissue zinc distribution and immune response of weanling pigs. Journal of Animal Science 81, 20632071.CrossRefGoogle ScholarPubMed
Veum, TL, Bollinger, DW, Ellersiek, M 1995. Proteinated trace minerals and condensed fish protein digest in weanling pig diets. Journal of Animal Science 73, 187.Google Scholar
Wedekind, KJ, Lewis, AJ, Giesemann, MA, Miller, PS 1994. Bioavailability of zinc from inorganic and organic sources for pigs fed corn-soybean meal diets. Journal of Animal Science 72, 26812689.CrossRefGoogle ScholarPubMed
Zhou, W, Kornegay, ET, van Laar, H, Swinkels, JGM, Wong, EA, Lindemann, MD 1994. The role of feed consumption and feed efficiency in copper-stimulated growth. Journal of Animal Science 72, 23852394.CrossRefGoogle ScholarPubMed