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Effect of offering maize, linseed or tuna oils throughout pregnancy and lactation on sow and piglet tissue composition and piglet performance

Published online by Cambridge University Press:  18 August 2016

J. A. Rooke
Affiliation:
Animal Biology Division, Scottish Agricultural College, Craibstone Estate, Aberdeen AB21 9YA, UK
M. Shanks*
Affiliation:
Animal Biology Division, Scottish Agricultural College, Craibstone Estate, Aberdeen AB21 9YA, UK
S. A. Edwards*
Affiliation:
Animal Biology Division, Scottish Agricultural College, Craibstone Estate, Aberdeen AB21 9YA, UK
*
Present addresses: Animal Biology Division, SAC, Bush Estate, Edinburgh EH9 3JG, UK.
Department of Agriculture, University of Newcastle, Newcastle-upon-Tyne NE1 7RU, UK.
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Abstract

The effects of different dietary essential fatty acids on piglet tissue composition at birth and performance until 7 days post weaning were investigated by offering the sow diets containing (17·5 g oil per kg diet) either maize oil (MO) as a control treatment, tuna oil (TO) as a source of long chain n-3 polyunsaturated fatty acids, particularly 22:6 n-3, or a mixture of maize and linseed oils (LO) which supplied the same amount of n-3 acids as TO but in the form of 18:3 n-3. Ten sows were allocated to each treatment which was offered throughout pregnancy and lactation. Compared with MO, offering TO increased sow plasma and subcutaneous adipose tissue 22: 6 n-3 proportions whereas LO increased 18: 3 n-3 and, to a much lesser extent than TO, 22: 6 n-3. Offering TO to the sow increased the proportions of 20: 5 n-3 and 22: 6 n-3 in piglet brain and liver at birth and decreased the n-6 acids, 20: 4, 22: 4 and 22: 5. LO only increased piglet liver 20: 5 n-3 proportions but to a lesser extent than TO; however, LO also decreased the proportions of 20: 4, 22: 4 and 22: 5 n-6 in piglet tissues. Offering the pregnant sow dietary 18: 3 n-3 therefore increased deposition of 22: 6 n-3 in foetal piglet tissues to a much lesser extent than tuna oil and so it is necessary to offer the sow pre-formed 22: 6 n-3 in order to achieve maximum foetal 22: 6 n-3 deposition. By experimentally allocating piglets at birth, effects of sow nutrition during pregnancy and lactation were separated. Piglets sucking MO or TO sows were heavier than piglets sucking LO sows 7 days post weaning.

Type
Non-ruminant nutrition, behaviour and production
Copyright
Copyright © British Society of Animal Science 2000

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References

Alessandri, J.-M., Goustard, B., Guesnet, P. and Durand, G. 1998. Docosahexaenoic acid concentrations in retinal phospholipids of piglets fed an infant formula enriched with long-chain polyunsaturated fatty acids: effects of egg phospholipids and fish oils with different ratios of eicosapentaenoic acid to docosahexaenoic acid. American Journal of Clinical Nutrition 67: 377385.Google Scholar
Allman, M. A., Pena, M. M. and Pang, D. 1995. Supplementation with flaxseed oil versus sunflowerseed oil in healthy young men consuming a low fat diet: effects on platelet composition and function. European Journal of Clinical Nutrition 49: 169178.Google Scholar
Arbuckle, L. D. and Innis, S. M. 1992. Docosahexaenoic acid in developing brain and retina of piglets fed high or low a -linolenoate formula with and without fish oil. Lipids 27: 8993.Google Scholar
Arbuckle, L. D., MacKinnon, M. J. and Innis, S. M. 1994. Formula 18: 2n-6 and 18: 3 n-3 content and ratio influence long chain polyunsaturated fatty acids in the developing piglet liver and central nervous system. Journal of Nutrition 124: 289298.Google Scholar
Campbell, F. M., Gordon, M. J. and Dutta-Roy, A. K. 1998. Placental membrane fatty acid-binding protein preferentially binds arachidonic and docosahexaenoic acids. Life Sciences 63: 235240.CrossRefGoogle ScholarPubMed
Carlson, S. E., Cooke, R. J., Werkman, S. H. and Tolley, E. A. 1992. First year growth of preterm infants fed standard compared to marine oil n-3 supplemented formula. Lipids 27: 901907.Google Scholar
Carlson, S. E., Werkman, S. H., Peeples, J. M., Cooke, R. J. and Tolley, E. A. 1993. Arachidonic acid status correlates with first year growth in preterm infants. Proceedings of the National Academy of Science 90: 10731077.Google Scholar
Clandinin, M. T., Chappell, J. E., Leong, S., Heim, T., Swyer, P. R. and Chance, G. W. 1980. Intrauterine fatty acid accretion rates in human brain: implications for fatty acid requirements. Early Human Development 4: 121129.Google Scholar
Clandinin, M. T., Wong, K. and Hacker, R. R. 1985. Synthesis of chain elongation-desaturation products of linoleic acid by liver and brain microsomes during development of the pig. Biochemical Journal 226: 303309.CrossRefGoogle ScholarPubMed
Edmond, J., Higa, T. A., Korsak, R. A., Bergner, E. A. and Lee, W.-N. P. 1998. Fatty acid transport and utilization for the developing brain. Journal of Neurochemistry 70: 12271234.Google Scholar
Edwards, S. A. and Pike, I. 1997. Effects of fishmeal on sow reproductive performance. Proceedings of the British Society of Animal Science, 1997, p. 95 (abstr.).Google Scholar
Freese, R. and Mutanen, M. 1997. a -Linolenic acid and marine long-chain n-3 fatty acids differ only slightly in their effects on hemostatic factors in healthy subjects. American Journal of Clinical Nutrition 66: 591598.Google Scholar
Herpin, P., Le Dividich, J. and Amaral, N. 1993. Effect of selection for lean tissue growth on body composition and physiological state of the pig at birth. Journal of Animal Science 71: 26452653.CrossRefGoogle ScholarPubMed
Ide, T., Murata, M. and Sugano, M. 1996. Stimulation of the activities of hepatic fatty acid oxidation enzymes by dietary fat rich in $$a -linolenic acid in rats. Journal of Lipid Research 37: 448463.Google Scholar
Kurlak, L. O. and Stephenson, T. J. 1999. Plausible explanations for effects of long chain polyunsaturated fatty acids (LCPUFA) on neonates. Archives of Diseases in Childhood 80: F148F154.Google Scholar
Lawes Agricultural Trust. 1987. GENSTAT 5 reference manual. Clarendon Press, Oxford.Google Scholar
Leskanitch, C. O. and Noble, R. C. 1999. The comparative roles of polyunsaturated fatty acids in pig neonatal development. British Journal of Nutrition 81: 87106.Google Scholar
Mantzioris, E., James, M. J., Gibson, R. A. and Cleland, L. G. 1994. Dietary substitution with an a -linolenic acid rich vegetable oil increases eicosapentaenoic acid concentrations in tissues. American Journal of Clinical Nutrition 59: 13041309.Google Scholar
Ministry of Agriculture, Fisheries and Food. 1992. Analysis of agricultural materials, second edition. Her Majesty’s Stationery Office, London.Google Scholar
Ministry of Agriculture, Fisheries and Food. 1993. Prediction of the energy value of compound feedingstuffs for farm animals. MAFF Publications, London.Google Scholar
Oeckel, M. J. van, Casteels, M., Warnants, N. and Boucque, C. V. 1997. Omega-3 fatty acids in pig nutrition: implications for zootechnical performance, carcass and fat quality. Archiv für Tierernährung 50: 3142.CrossRefGoogle ScholarPubMed
Passingham, R. E. 1985. Rates of brain development in mammals including man. Brain, Behaviour and Evolution 26: 167175.Google Scholar
Perez Rigau, A., Lindemann, M. D., Kornegay, E. T., Harper, A. F. and Watkins, B. A. 1995. Role of dietary lipids on fetal tissue fatty acid composition and fetal survival in swine at 42 days of gestation. Journal of Animal Science 73: 13721380.Google Scholar
Pettigrew, J. E. 1981. Supplemental dietary fat for peripartal sows. Journal of Animal Science 53: 107117.Google Scholar
Purvis, J. M., Clandinin, M. T. and Hacker, R. R. 1983. Chain elongation-desaturation of linoleic acid during the development of the pig. Implications for the supply of polyenoic fatty acids to the developing brain. Comparative Biochemistry and Physiology 75B: 199204.Google Scholar
Rooke, J. A., Bland, I. M. and Edwards, S. A. 1998. Effect of feeding tuna oil or soyabean oil as supplements to sows in late pregnancy on piglet tissue composition and viability. British Journal of Nutrition 80: 273280.Google Scholar
Rooke, J. A., Bland, I. M. and Edwards, S. A. 1999. Relationships between fatty acid status of sow plasma and that of umbilical cord and plasma and tissues of new-born piglets when sows were fed diets containing tuna oil or soyabean oil in late pregnancy. British Journal of Nutrition 82: 213221.Google Scholar
Ruwe, P. J., Wolverton, C. K., White, M. E. and Ramsay, T. G. 1991. Effect of maternal fasting on fetal and placental lipid metabolism in swine. Journal of Animal Science 69: 19351944.Google Scholar
Saito, M., Ueno, M., Kubo, K. and Yamaguchi, M. 1998. Dose-response effect of dietary docosahexaenoic acid on fatty acid profiles of serum and tissue lipids in rats. Journal of Agriculture and Food Chemistry 46: 184193.Google Scholar
Seerley, R. W. 1989. Survival and postweaning performance of pigs from sows fed fat during late gestation and lactation. Journal of Animal Science 67: 18891894.Google Scholar
Sweasey, D., Patterson, D. S. P. and Glancy, E. M. 1976. Biphasic myelination and the fatty acid composition of cerebrosides and cholesterol esters in the developing central nervous system of the domestic pig. Journal of Neurochemistry 27: 375380.Google Scholar
Taugbol, O., Framstad, T. and Saarem, K. 1993. Supplements of cod liver oil to lactating sows. Influence on milk fatty acid composition and growth performance of piglets. Journal of Veterinary Medicine, Series A 40: 437443.Google Scholar
Thulin, A. J., Allee, G. L., Harmon, D. L. and Davis, D. L. 1989. Utero-placental transfer of octanoic, palmitic and linoleic acids during late gestation in gilts. Journal of Animal Science 67: 738–745.Google Scholar
Turek, J. J., Schoenlein, I. A., Watkins, B. A., Van Alstine, W. G., Clark, L. C. and Knox, K. 1996. Dietary polyunsaturated fatty acids modulate responses of pigs to Mycoplasma hyopneumoniae infection. Journal of Nutrition 126: 15411548.Google Scholar
Varley, M. 1995. The neonatal pig. Development and survival. CAB International, Wallingford, UK.Google Scholar
Whelan, J. 1996. Antagonistic effects of dietary arachidonic acid and n-3 polyunsaturated fatty acids. Journal of Nutrition 126: 1086S1091S.Google Scholar
Wood, J. D. and Enser, M. 1997. Factors influencing fatty acids in meat and the role of antioxidants in improving meat quality. British Journal of Nutrition 78: S49-S60.Google Scholar