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Arsanilic acid, sodium salicylate and bromide salts as potential growth stimulants for pigs receiving diets with and without copper sulphate

Published online by Cambridge University Press:  06 August 2007

R. S Barber ,
R Braude  and
K. G Mitchell
R. S Barber
Affiliation:
National Institute for Research in Dairying, Shinfield, Reading RG2 9AT
R Braude
Affiliation:
National Institute for Research in Dairying, Shinfield, Reading RG2 9AT
K. G Mitchell
Affiliation:
National Institute for Research in Dairying, Shinfield, Reading RG2 9AT
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Abstract

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1. Results are presented of three experiments involving 112 individually fed pigs, covering the growing period between 20 and 90 kg live weight, in which the potential performance-stimulating properties of three different compounds were studied in relation to those of a dietary supplement of 250 mg Cu/kg diet.

2. The three compounds studied and the levels of supplementation used (mg/kg diet) were: Expt I arsanilic acid (100), Expt 2 sodium salicylate (200), Expt 3 a mixture of bromide salts (200); each was added to the diets either alone or with 250mg Cu/kg diet given as CuSO4, 5H2O.

3. The diets were given wet, ‘to appetite’ twice daily up to a daily maximum of 3 kg feed/pig. Measurements of length and of back-fat thickness at a number of points were made on all carcasses at slaughter.

4. Arsanilic acid and sodium salicylate alone gave growth responses similar to those obtained with Cu alone, whereas the bromide salt had no effect on performance. None of the three compounds when added to diets in conjunction with 250mg Cu/kg diet gave results superior to those obtained with the Cu supplement alone.

5. When added to the diets alone, none of the three compounds tested nor Cu had any marked effect on any of the carcass measurements.

6. Arsanilic acid reduced total liver weight and markedly reduced the large increase in total liver Cu stores that resulted from supplementation of the diets with 250 mg Cu/kg diet.

Type
Research Article
Information
British Journal of Nutrition , Volume 25 , Issue 3 , May 1971 , pp. 381 - 389
Copyright
Copyright © The Nutrition Society 1971

References

Allen, M. M., Barber, R. S., Braude, R. & Mitchell, K. G. (1958). Proc. Nutr. Soc. 17, xii.Google Scholar
Andrus, S. (1955). Analyst, Lond. 80, 514.CrossRefGoogle Scholar
Anonymous (1956). Nutr. Rev. 14, 206.Google Scholar
Barber, R. S., Braude, R., Chamberlain, A. G. & Mitchell, K. G. (1961). Int. Congr. Anim. Prod. viii. hamburg 3, 86.Google Scholar
Barber, R. S., Braude, R. & Mitchell, K. G. (1965). Br. J. Nutr. 19, 575.CrossRefGoogle Scholar
Braude, R. (1965). Transactions of a symposium on cuprum pro vita, vienna, p. 55. Also published in Wld Rev. Anim. Prod. (1967) 3, 69.Google Scholar
Carpenter, L. E. (1951). Archs Biochem. Biophys. 32, 181.CrossRefGoogle Scholar
Eidrigevich, E. V., Osipov, K. V., Zaplatnikov, A. K., Bazarnyi, V. M., D'yakova, A. A. & Rumyantsev, B. N. (1967). Vest. sel'-khoz. Nauki, Mosk. 12, no. 1, p.82.Google Scholar
Foster, J. R., Speer, V. C., Hays, V. W. & Catron, D. V. (1958). J. Anim. Sci. 17, 1177.Google Scholar
Frost, D. V. (1963). Western feed and seed. 04.Google Scholar
Frost, D. V. (1967). Fedn Proc. Fedn Am. Socs exp. Biol. 26, 194.Google Scholar
Gitter, M. & Lewis, G. (1969). Vet. Rec. 85, 389.CrossRefGoogle Scholar
Hanrahan, T. J. & O&grady, J. F. (1968). Anim. Prod. 10, 423.Google Scholar
Hanson, L. E., Carpenter, L. E., Aunan, W. J. & Ferrin, E. F. (1955).J. Anim. Sci. 14, 513.CrossRefGoogle Scholar
Hawbaker, J. A., Speer, V. C., Hays, V. W. & Catron, D. V. (1961).J. Anim. Sci. 20, 163.CrossRefGoogle Scholar
Herzig, I. & Najman, L. (1966). Biol. Chem. výž. zvíř. 2, 483.Google Scholar
Lennig chemicals Ltd (1970). Whitmoyer Tech. Bull. no. 11.Google Scholar
Mills, C. F. (1968). Feed Forum 3, 21.Google Scholar
Morehouse, N. F. (1949). Poult. Sci. 28, 375.CrossRefGoogle Scholar
Müller, Z. & čulik, J. (1965). Biol. Chem. výž. zvíř. 1, 101.Google Scholar
Müller, Z., šatava, M., Vrchota, V. & štmnc, M. (1967). Sb. vys. Šk. zeměd. provoz. ekon. Fak., Ceské Buděovich 5, 51.Google Scholar
Rechka, J. & Kalous, J. (1964). Sb. vys. Šk. zeměd. Praze p. 429.Google Scholar
Ritchie, H. D., Luecke, R. W., Baltzer, B. V., Miller, E. R., Ullrey, D. E. & Hoefer, J. A. (1963). J. Nutr. 79, 117.CrossRefGoogle Scholar
Rozman, J. (1968 a). Biol. Chem. výž. zvíř. 4, 67.Google Scholar
Rozman, J. (1968 b).Biol. Chem. výž. zvíř. 4, 339.Google Scholar
Rozman, J. & Hejzlar, Z. (1970). Biol. Chem. výž. zvíř. 6, 179.Google Scholar
Ruszczyc, Z. & Glapś, J. (1960). Roczn. Nauk. roln. 75–B–4, 541.Google Scholar
Ruszczyc, Z. & Glapś, J. (1963). Jb. Arbeitsgemeinsch. Fütterungsberat. 4, 193.Google Scholar
šatava, M., štrunc, M., Rozman, J.,čulik, J. & Müller, Z. (1966).Sb. vys. Šk. zeměd. provoz. ekon. Fak., Ceské Budějovich 4, 55.Google Scholar
Wallace, H. D. (1967). High Level Copper in Swine Feeding— a review of research in the U.S. New york and london: International copper research association, Inc.Google Scholar