Hostname: page-component-cd9895bd7-p9bg8 Total loading time: 0 Render date: 2024-12-18T17:57:15.543Z Has data issue: false hasContentIssue false

Supplementing sow diets with palm oil during late gestation and lactation: effects on milk production, sow hormonal profiles and growth and development of her offspring

Published online by Cambridge University Press:  02 May 2018

J. Laws
Affiliation:
Faculty of Natural Sciences, Imperial College London, TN25 5AH, Wye, Kent, UK
D. T. Juniper*
Affiliation:
School of Agriculture, Policy and Development, University of Reading, Reading RG6 6AR, UK
I. J. Lean
Affiliation:
Faculty of Natural Sciences, Imperial College London, TN25 5AH, Wye, Kent, UK
E. Amusquivar
Affiliation:
Facultad de Farmacia, Universidad San Pablo-CEU, Boadilla del Monte, 28668 Madrid, Spain
E. Herrera
Affiliation:
Facultad de Farmacia, Universidad San Pablo-CEU, Boadilla del Monte, 28668 Madrid, Spain
P. F. Dodds
Affiliation:
Faculty of Natural Sciences, Imperial College London, TN25 5AH, Wye, Kent, UK
L. Clarke
Affiliation:
Faculty of Natural Sciences, Imperial College London, TN25 5AH, Wye, Kent, UK
*
Get access

Abstract

The supplementing of sow diets with lipids during pregnancy and lactation has been shown to reduce sow condition loss and improve piglet performance. The aim of this study was to determine the effects of supplemental palm oil (PO) on sow performance, plasma metabolites and hormones, milk profiles and pre-weaning piglet development. A commercial sow ration (C) or an experimental diet supplemented with 10% extra energy in the form of PO, were provided from day 90 of gestation until weaning (24 to 28 days postpartum) in two groups of eight multiparous sows. Gestation length of PO sows increased by 1 day (P<0.05). Maternal BW changes were similar throughout the trial, but loss of backfat during lactation was reduced in PO animals (C: −3.6±0.8 mm; PO: −0.1±0.8 mm; P<0.01). Milk fat was increased by PO supplementation (C day 3: 8.0±0.3% fat; PO day 3: 9.1±0.3% fat; C day 7: 7.8±0.5% fat; PO day 7: 9.9±0.5% fat; P<0.05) and hence milk energy yield of PO sows was also elevated (P<0.05). The proportion of saturated fatty acids was greater in colostrum from PO sows (C: 29.19±0.31 g/100 g of fat; PO: 30.77±0.36 g/100 g of fat; P<0.01). Blood samples taken on 105 days of gestation, within 24 h of farrowing, day 7 of lactation and at weaning (28±3 days post-farrowing) showed there were no differences in plasma concentrations of triacylglycerol, non-esterified fatty acids, insulin or IGF-1 throughout the trial. However, circulating plasma concentrations of both glucose and leptin were elevated during lactation in PO sows (P<0.05 and P<0.005, respectively) and thyroxine was greater at weaning in PO sows (P<0.05). Piglet weight and body composition were similar at birth, as were piglet growth rates throughout the pre-weaning period. A period of 7 days after birth, C piglets contained more body fat, as indicated by their lower fat-free mass per kg (C: 66.4±0.8 arbitrary units/kg; PO: 69.7±0.8 arbitrary unit/kg; P<0.01), but by day 14 of life this situation was reversed (C: 65.8±0.6 arbitrary units/kg; PO: 63.6±0.6 arbitrary units/kg; P<0.05). Following weaning, PO sows exhibited an increased ratio of male to female offspring at their subsequent farrowing (C: 1.0±0.3; PO: 2.2±0.2; P<0.05). We conclude that supplementation of sow diets with PO during late gestation and lactation appears to increase sow milk fat content and hence energy supply to piglets. Furthermore, elevated glucose concentrations in the sow during lactation may be suggestive of impaired glucose homoeostasis.

Type
Research Article
Copyright
© The Animal Consortium 2018 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Almond, KL, Fainberg, HP, Lomax, MA, Bikker, P, Symonds, ME and Mostyn, A 2015. Substitution of starch for palm oil during gestation: impact on offspring survival and hepatic gene expression in the pig. Reproduction, Fertility and Development 27, 10571064.Google Scholar
Averette, LA, Odle, J, Monaco, MH and Donovan, SM 1999. Dietary fat during pregnancy and lactation increases milk fat and insulin-like growth factor I concentrations and improves neonatal growth rates in swine. Journal of Nutrition 129, 21232129.Google Scholar
Averette, GL, Odle, J, Soede, J and Hansen, JA 2002. Dietary medium- or long- chain triglycerides improve body condition of lean-genotype sows and increase suckling pig growth. Journal of Animal Science 80, 3844.Google Scholar
Cools, A, Maes, D, Decaluwe, R, Buyse, J, van Kempen, TATG, Liesegang, A and Janssens, GPJ 2014. Ad libitum feeding during the peripartal period affects body condition, reproduction results and metabolism of sows. Animal Reproduction Science 145, 130140.Google Scholar
Department for Environment, Food and Rural Affairs 2003. Code of recommendations for the welfare of livestock. Retrieved on 14 February 2005 from http://www.defra.gov.uk/animalh/welfare/farmed/pigs/pigcode.pdf) Google Scholar
De Rensis, F, Gherpelli, M, Superchi, P and Kirkwood, RN 2005. Relationships between backfat depth and plasma leptin during lactation and sow reproductive performance after weaning. Animal Reproduction Science 19, 95102.Google Scholar
Dourmad, JY 1991. Effect of feeding level in the gilt during pregnancy on voluntary feed intake during lactation and changes in body composition during gestation and lactation. Livestock Production Science 27, 309319.Google Scholar
EM-Scan 1992. Information bulletin: EM-SCAN Small Animal TOBEC Body Composition Analyser Technical Brief. EM-SCAN, Inc., Springfield, IL, USA.Google Scholar
Estienne, MJ, Harper, AF, Barb, CR and Azain, MJ 2000. Concentrations of leptin in serum and milk collected from lactating sows differing in body composition. Domestic Animal Endocrinology 19, 275280.Google Scholar
Folch, J, Lees, M and Sloane-Stanlet, GH 1957. A simple method for the isolation and purification of total lipids from animal tissues. Journal of Biological Chemistry 226, 497509.Google Scholar
Johnston, LJ, Pettigrew, JE and Rust, JW 1993. Response of maternal line sows to dietary protein concentration during lactation. Journal of Animal Science 71, 21512156.Google Scholar
Klaver, J, van Kempen, GJM, de Lange, PGB, Verstegen, MWA and Boer, H 1981. Milk composition and daily yield of different milk components as affected by sow condition and lactation/feeding regimen. Journal of Animal Science 52, 10911097.Google Scholar
Lauridsen, C, Christensen, TB, Halekoh, U and Jensen, SK 2007. Alternative fat sources to animal fat for pigs. Lipid Technology. 19, 156159.Google Scholar
Lauridsen, C and Danielsen, V 2004. Lactational dietary fat levels and sources influence milk composition and performance of sows and their progeny. Livestock Production Science 91, 95105.Google Scholar
Laws, J, Amusquivar, E, Laws, A, Herrera, E, Lean, IJ, Dodds, PF and Clarke, L 2009. Supplementation of sow diets with oil during gestation: Sow body condition, milk yield and composition. Livestock Science 123, 8896.Google Scholar
Laws, J, Laws, A, Lean, I, Dodds, PF and Clarke, L 2007. Growth and development of offspring following supplementation of sow diets with oil during early to mid-gestation. Animal. 1, 14821489.Google Scholar
Lepage, G and Roy, CC 1984. Improved recovery of fatty acids through direct transesterifacation without prior extraction or purification. The Journal of Lipid Research 27, 114120.Google Scholar
Lepage, G and Roy, CC 1986. Direct transesterification of all classes of lipids one step reaction. The Journal of Lipid Research 27, 114120.Google Scholar
Meikle, DB, Drickamer, LC, Vessey, SH, Arthur, RD and Rosenthal, TL. 1996. Dominance rank and parental investment in swine (Sus scrofa domesticus). Ethology 102, 969978.Google Scholar
Mitchell, AD and Scholz, AM. 2001. Techniques for measuring body composition of swine. In Swine nutrition, 2nd edition (ed. AJ Lewis and LL Southern), pp. 917960. CRC Press, Boca Raton, FL, USA.Google Scholar
Mullan, BP and Williams, IH 1989. The effect of body reserves at farrowing on the reproductive performance of first litter sows. Animal Production 48, 449457.Google Scholar
Quiniou, N, Richard, S, Mourot, I and Etienne, M 2008. Effect of dietary fat or starch supply during gestation and/or lactation on the performance of sows, piglets’ survival and on the performance of progeny after weaning. Animal 2, 16331644.Google Scholar
Ren, P, Yang, XJ, Cui, SQ, Kim, JS, Menon, D and Baidoo, SK 2017. Effects of different feeding levels during three short periods of gestation on gilt and litter performance, nutrient digestibility, and energy homeostasis in gilts. Journal of Animal Science 95, 12321242.Google Scholar
Rosenfeld, CS, Grimm, KM, Livingston, KA, Brokman, AM, Lamberson, WE and Roberts, RM 2003. Striking variation in the sex ratio of pups born to mice according to whether maternal diet is high in fat or carbohydrate. Proceedings of the National Academies of Science USA 100, 46284632.Google Scholar
Rosenfeld, CS and Roberts, RM 2004. Maternal diet and other factors affecting offspring sex ratio: a review. Biology of Reproduction 71, 10631070.Google Scholar
Rosero, DS, Boyd, RD, McCulley, M, Odle, J and van Heugten, E 2016. Essential fatty acid supplementation during lactation is required to maximize the subsequent reproductive performance of the modern sow. Animal Reproduction Science 168, 151163.Google Scholar
Seerley, RW, Griffin, FM and Campbell, HC 1978. Effect of sows dietary energy source on sows milk and piglet carcass composition. Journal of Animal Science 46, 10091017.Google Scholar
Skrzypczak, E, Waśkiewicz, A, Beszterda, M, Goliński, P, Szulc, K, Buczyński, J and Babicz, M 2015. Impact of fat and selected profiles of fatty acids contained in the colostrum and milk of sows of native breeds on piglet rearing. Animal Science Journal 86, 8391.Google Scholar
Shurson, GC, Hogberg, MG, DeFever, N, Radecki, SV and Miller, ER 1986. Effects of adding fat to the sow lactation diet on lactation and rebreeding performance. Journal of Animal Science 62, 672680.Google Scholar
Summer, A, Saleri, M, Malacarne, S, Bussolati, V, Beretti, A, Sabbioni, P and Superchi, P 2009. Leptin in the sow: influence on the resumption of cycle activity after weaning and on the piglet gain. Livestock Science. 124, 107111.Google Scholar
Tanghe, S and De Smet, S 2013. Does sow production and piglet performance benefit from the addition of n-3 polyunsaturated fatty acids to the maternal diet? The Veterinary Journal 197, 560569.Google Scholar
Tantasuparuk, W, Dalin, AM, Lundeheim, N, Kunavongkrit, A and Einarsson, S 2001. Body weight loss during lactation and its influence on weaning to service interval and ovulation rate in Landrace and Yorkshire sows in the tropical environment of Thailand. Animal Reproduction Science 65, 273281.Google Scholar
Teye, GA, Sheard, PR, Whittington, FW, Nute, GR, Stewart, A and Wood, JD 2006. Influence of dietary oils and protein level on pork quality 1. Effects on muscle fatty acid composition, carcass, meat and eating quality. Meat Science 73, 157165.Google Scholar
Tilton, SL, Miller, PS, Lewis, AJ, Reese, DE and Ermer, PM 1999. Addition of fat to the diets of lactating sows: I. Effects on milk production and composition and carcass composition of the litter at weaning. Journal of Animal Science 77, 24912500.Google Scholar
Triver, RL and Willard, DE 1973. Natural selection of parental ability to vary the sex ratio of offspring. Science 179, 9092.Google Scholar
Tummaruk, P, Sumransap, P and Jiebna, N 2014. Fat and whey supplementation influence milk composition, backfat loss, and reproductive performance in lactating sows. Tropical Animal Health Production 46, 753758.Google Scholar
Van der Peet-Schwering, CMC, Kemp, B, Binnendijk, GP, den Hartog, LA, Vereijken, PFG and Verstegen, MWA 2004. Effects of additional starch or fat in late-gestating high non-starch polysaccharide diets on litter performance and glucose tolerance in sows. Journal of Animal Science 82, 29642971.Google Scholar
Von Eder, K and Kirchgessner, M 1997. The effect of dietary fats on plasma concentrations of thyroid hormones in the pig. Zeitschrift fur Tierphysiologie Tierernahrung und Futtermittelkunde 77, 149152.Google Scholar
Wang, J, Yang, M, Cao, M, Lin, Y, Che, L, Duraipandiyan, V, Al-Dhabi, NA, Fang, Z, Xu, S, Feng, B, Liu, G and Wu, D 2016. Moderately increased energy intake during gestation improves body condition of primiparous sows, piglet growth performance, and milk fat and protein output. Livestock Science 194, 2330.Google Scholar