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RESEARCH ARTICLE
Contents Vol 49(12)

Measures of growth and feed efficiency and their relationships with body composition and carcass traits of growing pigs

P. F. Arthur A D , L. R. Giles A B , G. J. Eamens A , I. M. Barchia A and K. J. James A C
+ Author Affiliations
- Author Affiliations

A New South Wales Department of Primary Industries, Elizabeth Macarthur Agricultural Institute, Camden, NSW 2570, Australia.

B Present address: 26 Werombi Road, Camden, NSW 2570, Australia.

C Present address: 22 Woodbury Street, Woodford, NSW 2778, Australia.

D Corresponding author. Email: paul.arthur@dpi.nsw.gov.au

Animal Production Science 49(12) 1105-1112 https://doi.org/10.1071/AN09061
Submitted: 12 April 2009  Accepted: 29 July 2009   Published: 16 November 2009

Abstract

Data from 53 hybrid (mainly Large White × Landrace) pigs, comprising 18 males, 18 females and 17 castrates, were used to examine the relationships among growth and feed efficiency traits measured in the growing animal, and their relationships with body composition and carcass traits at two target liveweight (90 and 120 kg) endpoints. The data were from individually penned pigs involved in a longitudinal experiment that started when the pigs were 32.4 ± 3.2 kg liveweight and 70 ± 1 days of age (mean ± s.d.). Weekly feed intake and liveweight, and body components data measured at 60, 90 and 120 kg by computed tomography scanning were used. Growth traits studied were: start of test liveweight, average daily gain (ADG), Kleiber ratio and relative growth rate. The feed efficiency traits were daily feed intake (DFI), feed conversion ratio (FCR) and residual feed intake. Body components and carcass traits were the weight of the body components (lean, fat, bone and skin tissues) and their percentages relative to liveweight. Three models were used for residual feed intake. The standard model (RFIstd) had metabolic weight and ADG as explanatory variables for feed intake, RFIadg had only ADG as explanatory variable, and the other (RFIfat) had percentage fat at 60 kg target liveweight included in the standard model. The RFIadg model resulted in R2 values of 36.9, 72.1 and 19.1% for males, females and castrates, respectively. The corresponding R2 values for the RFIstd model were 63.7, 72.1 and 37.1%, and those for the RFIfat model were 86.1, 80.0 and 71.9%. These results indicate that RFIfat may be a better trait to use for efficiency of feed utilisation, especially in castrates. There were significant interrelationships among growth traits (r = –0.46 to 0.98), and also among feed efficiency traits (r = 0.44 to 0.76). Of the feed efficiency traits studied, only FCR was significantly correlated with all the growth traits (r = 0.33 to –0.61), and DFI was correlated with start liveweight (r = 0.43) and ADG (r = 0.57). Growth traits per se were not correlated with body composition and carcass traits at each of the weight-constant target endpoints; however, feed intake was. High DFI was associated with high percentage fat (r = 0.39 to 0.49) and low percentage lean (r = –0.40 to –0.52) at both 90 and 120 kg target liveweights. As with DFI, high FCR, RFIadg and RFIstd were associated with high percentage fat and low percentage lean at both 90 and 120 kg target liveweights. There were no significant correlations between RFIfat and the body components and carcass traits. These results will enable the development of programs aimed at reducing feed costs and improving the economic value of the pig carcass.


Acknowledgements

The authors acknowledge the financial support provided by Australian Pork Limited and Pig Improvement Co. Australia. The contributions of former NSW DPI staff members PJ Nicholls, LJ Barker and D Nicholson are gratefully appreciated.


References


Akridge JT, Brorsen BW, Whipker LD, Forrest JC, Kuel CH, Schinckel AP (1992) Evaluation of alternative techniques to determine pork carcass value. Journal of Animal Science 70, 18–28. [Verified 20 November 2008]

Bergh L, Scholtz MM, Erasmus GJ (1992) Identification and assessment of the best animals: the Kleiber ratio (growth rate/metabolic mass) as a selection criterion for beef cattle. Proceedings of the Australian Association of Animal Breeding and Genetics 10, 338–340. open url image1

de Haer LCM, de Vries AG (1993) Effects of genotype and sex on the feed intake pattern of group housed growing pigs. Livestock Production Science 36, 223–232.
Crossref | GoogleScholarGoogle Scholar | open url image1

de Haer LCM, Luiting P, Aarts HLM (1993) Relations among individual (residual) feed intake, growth performance and feed intake pattern of growing pigs in group housing. Livestock Production Science 36, 233–253.
Crossref | GoogleScholarGoogle Scholar | open url image1

de Lange CFM, Morel PCH, Birkett SH (2003) Modelling chemical and physical body composition of the growing pig. Journal of Animal Science 81, E159–E165. open url image1

Fitzhugh HA, Taylor StCS (1971) Genetic analysis of degree of maturity. Journal of Animal Science 33, 717–725. open url image1

Foster WH, Kilpatrick DJ, Heaney IH (1983) Genetic variation in the efficiency of energy utilization by the fattening pig. Animal Production 37, 387–393. open url image1

Gilbert H, Bidanel JP, Gruand J, Caritez JC, Billon Y, Guillouet P, Lagant H, Noblet J, Sellier P (2007) Genetic parameters for residual feed intake in growing pigs, with emphasis on genetic relationships with carcass and meat quality traits. Journal of Animal Science 85, 3182–3188.
Crossref | GoogleScholarGoogle Scholar | open url image1

Giles LR, Eamens GJ, Arthur PF, Barchia IM, James KJ, Taylor RD (2009) Differential growth and development of pigs as assessed by X-ray computed tomography. Journal of Animal Science 87, 1648–1658.
Crossref | GoogleScholarGoogle Scholar | open url image1

Gunsett FC (1984) Linear index selection to improve traits defined as ratios. Journal of Animal Science 59, 1185–1193. open url image1

Henman D (2003) Nutritional management in integrated pig units. In ‘Perspectives in pig science’. (Eds J Wiseman, MA Varley, B Kemp) pp. 11–132. (Nottingham University Press: Nottingham, UK)

Herd RM, Oddy VH, Richardson EC (2004) Biological basis for variation in residual feed intake in beef cattle. 1. Review of potential mechanisms. Australian Journal of Experimental Agriculture 44, 423–430.
Crossref | GoogleScholarGoogle Scholar | open url image1

Hoque MA, Kadowaki H, Shibata T, Oikawa T, Suzuki K (2007a) Genetic parameters for measures of the efficiency of gain of boars and their relationships with its component traits in Duroc pigs. Journal of Animal Science 85, 1873–1879.
Crossref | GoogleScholarGoogle Scholar | open url image1

Hoque MA, Suzuki K, Kadowaki H, Shibata T, Oikawa T (2007b) Genetic parameters for feed efficiency traits and their relationships with growth and carcass traits in Duroc pigs. Journal of Animal Breeding and Genetics 124, 108–116.
Crossref | GoogleScholarGoogle Scholar | open url image1

Johnson ZB, Chewning JJ, Nugent RA (1999) Genetic parameters for production traits and measures of residual feed intake in Large White swine. Journal of Animal Science 77, 1679–1685. open url image1

Kouba M, Bonneau M, Noblet J (1999) Relative development of subcutaneous, intermuscular, and kidney fat in growing pigs with different body compositions. Journal of Animal Science 77, 622–629. open url image1

Labroue F, Guéblez R, Sellier P, Meunier-Salaün MC (1994) Feeding behaviour of group-housed Large White and Landrace pigs in French central test stations. Livestock Production Science 40, 303–312.
Crossref | GoogleScholarGoogle Scholar | open url image1

Mrode RA, Kennedy BW (1993) Genetic variation in measures of food efficiency in pigs and their genetic relationships with growth rate and backfat. Animal Production 56, 225–232. open url image1

Nguyen NH, McPhee CP, Wade CM (2005) Responses in residual feed intake in lines of Large White pigs selected for growth rate on restricted feeding (measured on ad libitum individual feeding). Journal of Animal Breeding and Genetics 122, 264–270.
Crossref | GoogleScholarGoogle Scholar | open url image1

Nkrumah JD, Basarab JA, Wang Z, Li C, Price MA, Okine EK, Crews DH, Moore SS (2007) Genetic and phenotypic relationships of feed intake and measures of efficiency with growth and carcass merit of beef cattle. Journal of Animal Science 85, 2711–2720.
Crossref | GoogleScholarGoogle Scholar | open url image1

Rauw WM, Soler J, Tibau J, Reixach J, Gomez Raya I (2006) The relationship between residual feed intake and feed intake behaviour in group-housed Duroc barrows. Journal of Animal Science 84, 956–962. open url image1

Steel RGD , Torrie JH (1960) ‘Principles and procedures of statistics.’ (McGraw Hill Book Company: New York)

Szabo CC, Babinszky L, Verstegen MWA, Vangen O, Jansman AJM, Kanis E (1999) The application of digital imaging techniques in the in vivo estimation of the body composition of pigs: a review. Livestock Production Science 60, 1–11.
Crossref | GoogleScholarGoogle Scholar | open url image1

Wagner JR, Schinckel AP, Chen W, Forrest JC, Coe BL (1999) Analysis of body composition changes of swine during growth and development. Journal of Animal Science 77, 1442–1466. open url image1