Growth and food intake curves for group-housed gilts and castrated male pigs

S. Andersen; B. Pedersen

doi:10.1017/S1357729800015356

Abstract

Polynomial models with random regression coefficients were used to describe cumulated food intake and gain as a function of number of days on test for gilts and castrated male pigs which were on test from 30 to 115 kg live weight. Growth rate and daily food intake were expressed as the derivative of the curves. The applied models allowed a separation of between and within animal variation. Confidence limits for average curves and prediction limits for individual curves were also obtained. A similar model was used to describe gain as a function of cumulated food intake. From this function food efficiency was obtained. The application of the results in stochastic simulation models is discussed.

Growth rate and daily food intake had a more curvilinear progress for castrated males than for gilts. It was estimated that 98% of the castrated males and 96% of the gilts had a lower growth rate at day 80 than at day 50; 74% of the castrated males and 48% of the gilts had a lower daily food intake at day 100 than at day 80. On average food efficiency of gilts was higher than food efficiency of castrated males and the difference increased through the test period.

References

Carroll, R. J. and Ruppert, D. 1988. Transformation and weighting in regression. Chapman and Hall, New York.CrossRef Google Scholar

Crowder, M. J. and Hand, D. J. 1991. Analysis of repeated measures. Chapman and Hall, New York.Google Scholar

Diggle, P. J., Liang, K.-Y. and Zeger, S. L. 1994. Analysis of longitudinal data. Clarendon Press, Oxford.Google Scholar

Efron, B. 1987. Bootstrap confidence interval s and bootstrap approximations (with discussion). Journal of the American Statistical Association. 82: 171–200.CrossRef Google Scholar

Emmans, G. C. 1995. Way s of describing pig growth and food intake using equations. Pig News and Information 16: 113N–116N.Google Scholar

Fowler, V. R. 1980. Growth in mammals for meat production. In Growth in animals (ed. Lawrence, T. L. J.), pp. 249–263. Butterworths, London.CrossRef Google Scholar

Gelfand, A. E., Hills, S. E., Racine-Poon, A. and Smith, A. F. M. 1990. Illustration of Bayesian inference in norma l data models using Gibbs sampling. Journal of the American Statistical Association. 85: 977–985.CrossRef Google Scholar

Kanis, E. and Koops, W. J. 1990. Daily gain, food intake and food efficiency in pigs during the growing period. Animal Production 50: 353–364.Google Scholar

Knap, P. W. 1995. Use of automatic systems for feed consumption control in national programmes for genetic improvements in pigs. XIV Symposium del Asociacion de Porcinocultura Cientifica (ANAPORC), Barcelona, 8–9 November 1995.Google Scholar

Mrode, R. A. and Kennedy, B. W. 1993. Geneti c variation i n measures of food efficiency in pigs and their genetic relationships with growth rate and backfat. Animal Production. 56: 225–232.Google Scholar

Parks, J. R. 1982. A theory of feeding and growth of animals. Springer-Verlag, Berlin.CrossRef Google Scholar

Schaeffer, L. R. and Dekkers, J. C. M. 1994. Random regressions in animal model s for test-day production in dairy cattle. Proceedings of the fifth world congress on genetics applied to livestock production, Guelph, vol. 18, pp. 443–446.Google Scholar

Taylor, St C. S. 1985. Use of genetic size-scaling in evaluation of animals growth. Journal of Animal Science 61: (suppl. 2) 118–143.CrossRef Google Scholar

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Koenen, E. P. C. Groen, A. F. and Gengler, N. 1999. Phenotypic variation in live weight and live-weight changes of lactating Holstein-Friesian cows. Animal Science, Vol. 68, Issue. 1, p. 109.

Uribe, H. Schaeffer, L. R. Jamrozik, J. and Lawlor, T. J. 2000. Genetic evaluation of dairy cattle for conformation traits using random regression models. Journal of Animal Breeding and Genetics, Vol. 117, Issue. 4, p. 247.

Meyer, Karin 2000. Random regressions to model phenotypic variation in monthly weights of Australian beef cows. Livestock Production Science, Vol. 65, Issue. 1-2, p. 19.

Knap, P. W. 2000. Time trends of Gompertz growth parameters in ‘meat-type’ pigs. Animal Science, Vol. 70, Issue. 1, p. 39.

Schnyder Hofer and Künzi 2001. Impact of variation in length of individual testing periods on estimation of (co)variance components of a random regression model for feed intake of growing pigs. Journal of Animal Breeding and Genetics, Vol. 118, Issue. 4, p. 235.

Tor, M. Estany, J. Villalba, D. Cubiló, D. Tibau, J. Soler, J. Sanchez, A. and Noguera, J. L. 2001. A within‐breed comparison of RYR1 pig genotypes for performance, feeding behaviour, and carcass, meat and fat quality traits. Journal of Animal Breeding and Genetics, Vol. 118, Issue. 6, p. 417.

Miller, Gay Song, Yanghoon and Bahnson, Peter 2001. An economic model for estimating batch finishing system profitability with an application in estimating the impact of preventive measures for porcine respiratory disease complex. Journal of Swine Health and Production, Vol. 9, Issue. 4, p. 169.

Estany, J. Villalba, D. Tibau, J. Soler, J. Babot, D. and Noguera, J. L. 2002. Correlated response to selection for litter size in pigs: I. Growth, fat deposition, and feeding behavior traits1. Journal of Animal Science, Vol. 80, Issue. 10, p. 2556.

Lewis, R.M. and Brotherstone, S. 2002. A genetic evaluation of growth in sheep using random regression techniques. Animal Science, Vol. 74, Issue. 1, p. 63.

Schulze, V. Roehe, R. Bermejo, J.Lorenzo Looft, H. and Kalm, E. 2002. Genetic associations between observed feed intake measurements during growth, feed intake curve parameters and growing–finishing performances of central tested boars. Livestock Production Science, Vol. 73, Issue. 2-3, p. 199.

Berry, D.P Buckley, F Dillon, P Evans, R.D Rath, M and Veerkamp, R.F 2003. Estimation of genotype×environment interactions, in a grass-based system, for milk yield, body condition score, and body weight using random regression models. Livestock Production Science, Vol. 83, Issue. 2-3, p. 191.

Wolter, B. F. Ellis, M. Corrigan, B. P. DeDecker, J. M. Curtis, S. E. Parr, E. N. and Webel, D. M. 2003. Effect of restricted postweaning growth resulting from reduced floor and feeder-trough space on pig growth performance to slaughter weight in a wean-to-finish production system1. Journal of Animal Science, Vol. 81, Issue. 4, p. 836.

Schaeffer, L.R. 2004. Application of random regression models in animal breeding. Livestock Production Science, Vol. 86, Issue. 1-3, p. 35.

Arango, J. A. Cundiff, L. V. and Van Vleck, L. D. 2004. Covariance functions and random regression models for cow weight in beef cattle1. Journal of Animal Science, Vol. 82, Issue. 1, p. 54.

Doeschl-Wilson, A. B. Whittemore, C. T. Knap, P. W. and Schofield, C. P. 2004. Using visual image analysis to describe pig growth in terms of size and shape. Animal Science, Vol. 79, Issue. 3, p. 415.

Brumm, M. C. 2004. The effect of space allocation on barrow and gilt performance123. Journal of Animal Science, Vol. 82, Issue. 8, p. 2460.

Huisman, A.E. and van Arendonk, J.A.M. 2004. Genetic parameters for daily feed intake patterns of growing Dutch Landrace gilts. Livestock Production Science, Vol. 87, Issue. 2-3, p. 221.

Strathe, A.B. Sørensen, H. and Danfær, A. 2009. A new mathematical model for combining growth and energy intake in animals: The case of the growing pig. Journal of Theoretical Biology, Vol. 261, Issue. 2, p. 165.

Cai, W. Wu, H. and Dekkers, J. C. M. 2010. Longitudinal Analysis of Body Weight and Feed Intake in Selection Lines for Residual Feed Intake in Pigs. Asian-Australasian Journal of Animal Sciences, Vol. 24, Issue. 1, p. 17.

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Growth and food intake curves for group-housed gilts and castrated male pigs

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Growth and food intake curves for group-housed gilts and castrated male pigs

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