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The chemical composition of sows during their first lactation

Published online by Cambridge University Press:  02 September 2010

B. P. Mullan
Affiliation:
Animal Science, School of Agriculture, University of Western Australia, Nedlands, Western Australia 6009, Australia
I. H. Williams
Affiliation:
Animal Science, School of Agriculture, University of Western Australia, Nedlands, Western Australia 6009, Australia
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Abstract

It is common for sows in commercial practice to lose body weight during lactation and if the loss is excessive then performance may be impaired. However, there is little information on the composition of this loss of body weight. In a 2 × 2 factorial experiment gilts were given daily either 2·7 (H) or 1·5 (L) kg food during gestation and either a high (H) (mean intakes of 3·4 and 4·9 kg/day for the H-H and L-H groups, respectively) or low (L, 2·0 kg/day) food intakes during a 31-day lactation. Seventy-three animals were slaughtered at various stages over all treatments and body composition determined by chemical analysis. The content of lipid (Li, kg) and protein (Pr, kg) in the empty body were closely related to live weight (LW, kg) and depth of backfat measured by ultrasound (P2, mm); Li = 0·381 LW + 1·042 P2 - 31·099 (R = 0·95) and Pr = 0·11 LW - 013 P2 + 4·46 (R = 0·67). Prediction equations were used to predict the composition of animals from a previous experiment (Mullan and Williams, 1989). Increasing food intake prior to farrowing increased the amount of lipid (67 v. 38 kg), protein (20 v. 17 kg), water (73 v. 63 kg) and ash (5 v. 4 kg) in the empty body at farrowing. For sows given 2·0 kg/day food during lactation about half of the total loss of body weight was lipid (835 and 570 g/day for the H-L and L-L groups, respectively) and proportionately 0-10 was protein tissue (165 and 125 g/day, respectively). When sows were fed to appetite the heaviest animals lost both lipid (520 g/day) and protein (130 g/day) whereas animals in the L-H group maintained their lipid reserves but lost 65 g protein per day. This study demonstrates the considerable amounts of lipid and protein which may be mobilized by the sow during lactation to buffer the nutritional stress through a low intake of food. The body composition of the sow during the first lactation can be accurately predicted from live weight and depth of backfat.

Type
Research Article
Copyright
Copyright © British Society of Animal Science 1990

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