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Phosphorus studies in pigs

1. Available phosphorus requirements of grower/finisher pigs

Published online by Cambridge University Press:  09 March 2007

P. P. Ketaren
Affiliation:
NSW Agriculture, Wollongbar Agricultural Institute, Wollongbar, NSW 2477, Australia
E. S. Batterham
Affiliation:
NSW Agriculture, Wollongbar Agricultural Institute, Wollongbar, NSW 2477, Australia
E. White
Affiliation:
NSW Agriculture, Wollongbar Agricultural Institute, Wollongbar, NSW 2477, Australia
D. J. Farrell
Affiliation:
Department of Biochemistry, Microbiology and Nutrition, University of New England, Armidale, NSW 2351, Australia
B. K. Milthorpe
Affiliation:
Centre for Biomedical Engineering, University of New South Wales, Sydney, NSW 2033, Australia
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Abstract

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Two experiments were conducted to determine the available P requirements of grower and grower/finisher pigs and to define the conditions for conducting a growth assay for P availability. In the first experiment, diets with four levels of calculated available P (1–4 g/kg) and four Ca: available P ratios (1·7–2·9) were used to determine the available P requirements of grower pigs. The diets were formulated by substituting the required amounts of limestone and sodium tripolyphosphate for sugar in a soya-bean meal and sugar-based diet. In addition to measuring growth responses, a range of bones were examined to determine the most suitable criteria for assessing the response to available P. There was a small quadratic response of feed intake and growth rate of the pigs to level of available P, with maximum responses occurring to approximately 3 g available P/kg (P < 0·05). There were linear depressing effects of increasing Ca:available P ratios on carcass gain and feed conversion ratio (P < 0·01) but most of these effects occurred when the ratio exceeded 2·5:1. All bone variables examined increased linearly (P < 0·05) or curvilinearly (P < 0·01) with increasing available P concentration. In general, these variables were not affected by the Ca: available P ratio. The results of the growth responses and bone development indicate that the grower pig requires approximately 3 g available P/kg. However, for availability assays, where linearity of response is needed, the dietary concentration of available P should be a maximum of approximately 2 g/kg. In the second experiment four levels of calculated available P (1–4 g/kg) with a Ca: available P ratio of 2·5:1 were used to determine the available P requirements of grower/finisher pigs from 20 to 90 kg live weight. At 50 kg live weight the dietary available P concentration for half the pigs fed at 2, 3 and 4 g available P/kg was reduced to 1, 2 and 3 g/kg respectively. The pigs were fed ad lib. and growth performance, bone characteristics, P retention and ash concentration in the empty body were taken as response criteria to assess P adequacy. Among the variables tested, the ash concentration in the radius/ulna bone and P and ash concentrations in the empty body appeared to be more responsive than other variables to the changes in dietary P levels. Based on these variables, the P requirements for growth and bone development of growing pigs from 20 to 50 kg live weight was 3 g/kg and reduced to 2 g/kg for finisher pigs from 50 to 90 kg live weight.

Type
Phosphorus Availability in Pigs
Copyright
Copyright © The Nutrition Society 1993

References

REFERENCES

Agricultural Research Council (1981). The Nutrient Requirements of Pigs. Slough: Commonwealth Agricultural Bureaux.Google Scholar
Crenshaw, T. D., Peo, E. R. Jr, Lewis, A. J. & Moser, B. D. (1981 a). Bone strength as a trait for assessing mineralization in swine: a critical review of techniques involved. Journal of Animal Science 53, 827835.CrossRefGoogle Scholar
Crenshaw, T. D., Peo, E. R. Jr, Lewis, A. J., Moser, B. D. & Olson, D. (1981 b). Influence of age, sex and calcium and phosphorus levels on the mechanical properties of various bones in swine. Journal of Animul Science 52, 13191329.CrossRefGoogle ScholarPubMed
Cromwell, G. L. (1980). Biological availability of phosphorus for pigs. Feedstuffs 52, 3842.Google Scholar
Cromwell, G. L. (1989). Requirements, biological availability of calcium, phosphorus for swine evaluated. Feedstufs 60, 1625.Google Scholar
Hays, V. W. (1976). Phosphorus in Swine Nutrition. Des Moines, Iowa: National Feed Ingredients Association.Google Scholar
John, M. K. (1970). Colorimetric determination of phosphorus in soil and plant materials with ascorbic acid. Soil Science 109, 214220.CrossRefGoogle Scholar
Jongbloed, A. W. (1987). Phosphorus in the feeding of pigs. PhD Thesis, Drukkerij de Boer, Lelystad.Google Scholar
McLean, F. C. & Urist, M. R. (1968). Bone: Fundamentals ofthe Physiology ofSkeletul Tissue, 3rd ed. Chicago: University of Chicago Press.Google Scholar
National Research Council (1988). Nutrient Requirements of Swine. Washington, DC: National Academy Press.Google Scholar
Standing Committee on Agriculture (1987). Feeding Standards, for Australian Livestock. Pigs. East Melbourne: CSIRO Press.Google Scholar
Underwood, E. J. (1966). The Mineral Nutrition of Livesrock. Aberdeen: The Central Press (Aberdeen) Ltd.Google Scholar