Essential Fatty Acids

doi:10.1017/CHOL9780521402149.100

IV.C.1 - Essential Fatty Acids

from IV.C - Proteins, Fats, and Essential Fatty Acids

Published online by Cambridge University Press: 28 March 2008

Jacqueline Dupont

Edited by

Kenneth F. Kiple and

Kriemhild Coneè Ornelas

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Kenneth F. Kiple: Affiliation:
Bowling Green State University, Ohio

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Summary

The history of the scientific documentation of the need for fat in the diet began with the early nineteenth-century work of Michel Eugene Chevreul (Mayer and Hanson 1960). He showed that lard contained a solid fat, which he termed stearine, and a liquid fat he called elaine (later shown to be the isomer of oleine), and in 1823, this work was published in a treatise, Chemical Investigations of Fats of Animal Origin. Chevreul also crystallized potassium stearate, naming it ‘mother-of-pearl’ and calling its acidified product “margarine” (from the Greek word for mother-of-pearl). In addition, Chevreul isolated various acids from fats and distinguished them on the basis of their melting points.

Meanwhile in 1822, Edmund Davy had reported that iodine would react with fats, and by the end of the century, work by L. H. Mills and Baron Hubl led to the procedure devised by J.J.A. Wijs in 1898 for determining a fat’s “iodine value” or “iodine number” – a measure of the extent to which a fat is unsaturated, based on its uptake of iodine. Highly saturated coconut oil, for example, has an iodine number of 8 to 10, whereas that of highly unsaturated linseed oil ranges from 170 to 202.

Phospholipids were described in 1846 by N. T. Gobley, who found that egg yolk had a substance that contained nitrogen and phosphorus in addition to glycerol and fatty acids. He named it lecithin. The nitrogenous base was shown to be choline by A. Strecker in 1868, and J.W. L. Thudichem described kephalin in 1884 (Mayer and Hanson 1960).

Type: Chapter
Information: The Cambridge World History of Food , pp. 876 - 882

DOI: https://doi.org/10.1017/CHOL9780521402149.100 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2000

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References

Alexander, C. S., and Ziene, L.. 1961. Fat infusions. Toxic effects and alterations in fasting serum lipids following prolonged use. Archives of Internal Medicine 107.CrossRef Google Scholar PubMed

Bergstrom, S. 1972. Introduction, International Conference on Prostaglandins, 1972. In Advances in the Biosciences 9.Google Scholar

Bergstrom, S., and Carlson, L. A.. 1965. Lipid mobilization in essential fatty acid deficient rats. Acta Physiologica Scandinavica 64.CrossRef Google Scholar PubMed

Bergstrom, S., Dressler, F., Ryhage, R., et al. 1962. Prostaglandin and related factors. VIII. The isolation of two further prostaglandins from sheep prostate glands. Arkiv Kemi 19.Google Scholar

Bivins, B. A., Rapp, R. P., Record, K., et al. 1980. Parenteral safflower oil emulsion (Liposyn 10%). Safety and effectiveness in treating or preventing essential fatty acid deficiency in surgical patients. Annals of Surgery 203.Google Scholar

Bjerve, K. S. 1989. N-3 fatty acid deficiency in man. Journal of Internal Medicine 225 (Supplement 1).Google Scholar

Burr, G. O. 1942. Significance of the essential fatty acids. Federation Proceedings 1.Google Scholar

Burr, G. O., and Burr, M. M.. 1929. A new deficiency disease produced by the rigid exclusion of fat from the diet. The Journal of Biological Chemistry 82.Google Scholar

Burr, G. O., and Burr, M. M.. 1930. On the nature and the role of fatty acids essential in nutrition. The Journal of Biological Chemistry 86.Google Scholar

Bush, R. A., Malnoe, A., Reme, C. E., and Williams, T. P.. 1994. Dietary deficiency of N-3 fatty acids alters rhodopsin content and function in rat retina. Investigative Ophthalmology and Visual Science 35.Google Scholar PubMed

Carlson, S. E., Werkman, S. H., Rhodes, P. G., and Tolley, E. A.. 1993. Visual acuity development in healthy preterm infants: Effect of marine-oil supplementation. American Journal of Clinical Nutrition 58.CrossRef Google Scholar PubMed

Cook, H. W., Byers, D. M., St, F. B.. Palmer, C., et al. 1991. Alternate pathways in the desaturation and chain elongation of linolenic acid, 18: 3(n-3), in cultured glioma cells. Journal of Lipid Research 32.Google Scholar

Cornbleet, T. 1935. Use of maize oil (unsaturated fatty acids) in the treatment of eczema. Archives of Dermatology and Syphilology 31.CrossRef Google Scholar

Cunnane, S. C., Ryan, M. A., Craig, K. S., et al. 1995. Synthesis of linoleate and alpha-linolenate by chain elongation in the rat. Lipids 30.CrossRef Google Scholar PubMed

Dudrick, S. J., Wilmore, D. W., Vars, H. M., and Rhoads, J. E.. 1968. Long-term total parenteral nutrition with growth, development, and positive nitrogen balance. Surgery 64.Google Scholar PubMed

Dupont, J., and Dowd, M. K.. 1990. Icosanoid synthesis as a functional measurement of essential fatty acid requirement. Journal of the American College of Nutrition 9.CrossRef Google Scholar PubMed

Evans, H. M., and Burr, G. O.. 1927a. A new dietary deficiency with highly purified diets. Proceedings of the Society for Experimental Biology and Medicine 24.Google Scholar

Evans, H. M., and Burr, G. O.. 1927b. A new dietary deficiency with highly purified diets. II. Supplementary requirement of diet of pure casein, sucrose, and salt. Proceedings of the Society for Experimental Biology and Medicine 25.Google Scholar

Evans, H. M., and Burr, G. O.. 1928. A new dietary deficiency with highly purified diets. III. The beneficial effect of fat in diet. Proceedings of the Society for Experimental Biology and Medicine 25.Google Scholar

Evans, H. M., and Lepkovsky, S.. 1932a. Vital need of the body for certain unsaturated fatty acids. I. Experiments with fatfree diets in which sucrose furnishes the sole source of energy. The Journal of Biological Chemistry 96.Google Scholar

Evans, H. M., and Lepkovsky, S.. 1932b. Vital need of the body for certain unsaturated fatty acids. II. Experiments with high fat diets in which saturated fatty acids furnish the sole source of energy. The Journal of Biological Chemistry 96.Google Scholar

Evans, H. M., and Lepkovsky, S.. 1932c. Vital need of the body for certain unsaturated fatty acids. III. Inability of the rat organism to synthesize the essential unsaturated fatty acids. The Journal of Biological Chemistry 99.Google Scholar

Evans, H. M., Lepkovsky, S., and Murphy, E. A.. 1934a. Vital need of the body for certain unsaturated fatty acids. IV. Reproduction and lactation upon fat-free diets. The Journal of Biological Chemistry 106.Google Scholar

Evans, H. M., Lepkovsky, S., and Murphy, E. A.. 1934b. Vital need of the body for certain unsaturated fatty acids. V. Reproduction and lactation upon diets containing saturated fatty acids as their sole source of energy. The Journal of Biological Chemistry 106.Google Scholar

Evans, H. M., Lepkovsky, S., and Murphy, E. A.. 1934c. Vital need of the body for certain unsaturated fatty acids. VI. Male sterility on fat-free diets. The Journal of Biological Chemistry 106.Google Scholar

Fulco, A. J., and Mead, J. F.. 1959. Metabolism of essential fatty acids. VIII. Origin of 5, 8, 11-eicosatrionic acid in the fatdeficient rat. The Journal of Biological Chemistry 234.Google Scholar

Hallberg, D., Schuberth, O., and Wretlind, A.. 1966. Experimental and clinical studies with fat emulsion for intravenous nutrition. Nutra Dieta 8.Google Scholar PubMed

Hansen, A. E. 1933. Serum lipid changes and therapeutic effect of various oils in infantile eczema. Proceedings of the Society for Experimental Biology and Medicine 31.Google Scholar

Hansen, A. E., Adam, D. J. D., Boelsche, A. N., et al. 1957. Manifestations of fat deficiency in infants. Federation Proceedings 16.Google Scholar

Hansen, A. E., and Wiese, H. F.. 1951. Fat in the diet in relation to nutrition of the dog: I. Characteristic appearance and gross changes of animals fed diets with and without fat. Texas Reports on Biology and Medicine 9.Google Scholar PubMed

Hansen, A. E., and Wiese, H. F.. 1954. Essential fatty acids and human nutrition: II. Serum level for unsaturated fatty acids in poorly-nourished infants and children. Journal of Nutrition 52.CrossRef Google Scholar PubMed

Hansen, H. S., and Jensen, B.. 1985. Essential function of linoleic acid esterified in acylglucosylceramide and acylceramide in maintaining the epidermal water permeability barrier. Evidence from feeding studies with oleate, linoleate, arachidonate, columbinate and a-linolenate. Biochimica and Biophysica Acta 834.Google Scholar

Hayek, M. G., Mura, C., Wu, D., et al. 1997. Enhanced expression of inducible cyclooxygenase with age in murine macrophages. Journal of Immunology 159.Google Scholar PubMed

Holman, R. T. 1964. Nutritional and metabolic interrelationships between fatty acids. Federation Proceedings 23.Google Scholar PubMed

Holman, R. T. 1973. Essential fatty acid deficiency in humans. In Dietary lipids and postnatal development, ed. Galli, C.. New York.Google Scholar

Hwang, D. H., and Rhee, S. H.. 1999. Receptor-mediated signaling pathways: Potential targets of modulation by dietary fatty acids. American Journal of Clinical Nutrition 70.CrossRef Google Scholar PubMed

Hwang, D. H., Mathias, M. M., Dupont, J., and Meyer, D. L.. 1975. Linoleate enrichment of diet and prostaglandin and prostaglandin metabolism in rats. Journal of Nutrition 105.CrossRef Google Scholar PubMed

Jensen, C. L., Chen, H., Fraley, J. K., et al. 1996. Biochemical effects of dietary linoleic/α-linolenic acid ratio in term infants. Lipids 31.CrossRef Google Scholar PubMed

Mathias, M. M., and Dupont, J.. 1985. Quantitative relationship between dietary linoleate and prostaglandin (icosanoid) biosynthesis. Lipids 20.CrossRef Google Scholar

Mayer, J., and Hanson, S. D.. 1960. Michel Eugene Chevreul – A biographical sketch. Journal of Nutrition 72.CrossRef Google Scholar

McAmis, A. J., Anderson, W. E., and Mendel, L. B.. 1929. Growth of rats on “fat-free” diets. The Journal of Biological Chemistry 82.Google Scholar

Neuringer, M., Anderson, G. J., and Connor, W. E.. 1988. The essentiality of n-3 fatty acids for the development and function of the retina and brain. Annual Review of Nutrition 8.CrossRef Google Scholar PubMed

Neuringer, M., Reisbick, S., and Janowsky, J.. 1994. The role of n-3 fatty acids in visual and cognitive development: Current evidence and methods of assessment. Journal of Pediatrics 125.CrossRef Google Scholar PubMed

Niswender, G. D., Akbar, A. M., and Nett, T. M.. 1975. Use of specific antibodies for quantification of steroid hormones. Methods in Enzymology 36, Part A.CrossRef Google Scholar PubMed

Paulsrud, J. R., Pensler, L., Whitten, C. F., et al. 1972. Essential fatty acid deficiency in infants by fat-free intravenous feeding. American Journal of Clinical Nutrition 25.CrossRef Google Scholar PubMed

Poovaiah, B. P., Tinoco, J., and Lyman, R. L.. 1976. Influence of diet on conversion of 14C1-linolenic acid to docosahexaenoic acid in the rat. Lipids 11.CrossRef Google Scholar PubMed

Reiser, R., Gibson, B., Carr, M. J., and Lamp, B. G.. 1951. The synthesis and interconversions of polyunsaturated fatty acids by the laying hen. The Journal of Nutrition 44.CrossRef Google Scholar

Rieckehoff, I. G., Holman, R. T., and Burr, G. O.. 1949. Polyethenoid fatty acid metabolism. Effect of dietary fat on polyethenoid fatty acids in rat tissues. Archives of Biochemistry 20.Google Scholar

Sprecher, H., Luthria, D. L., Mohammed, B. S., and Baykousheva, S. P.. 1995. Reevaluation of the pathways for the biosynthesis of polyunsaturated fatty acids. Journal of Lipid Research 36.Google Scholar PubMed

Stein, T. P., Buzby, G. P., Hargrove, W. C. III, et al. 1980. Essential fatty acid deficiency in patients receiving simultaneous parenteral and oral nutrition. Journal of Parenteral and Enteral Nutrition 4.CrossRef Google Scholar PubMed

Steinberg, G., Slaton, W. H., Howton, D. R., and Mead, J. F.. 1956. Metabolism of essential fatty acids. IV. Incorporation of linoleate into arachidonic acid. The Journal of Biological Chemistry 220.Google Scholar PubMed

Tinoco, J., Babcock, R., Hincenbergs, R., et al. 1978. Linolenic acid deficiency: Changes in fatty acid patterns in female and male rats raised on a linolenic acid-deficient diet for two generations. Lipids 13.CrossRef Google Scholar PubMed

Tinoco, J., Miljanich, P., and Medwadowski, B.. 1977. Depletion of docosahexaenoic acid in retinal lipids of rats fed a linolenic acid-deficient, linoleic-acid containing diet. Biochimica and Biophysica Acta 486.Google Scholar PubMed

Tinoco, J., Williams, M. A., Hincenbergs, I., and Lyman, R. L.. 1971. Evidence for nonessentiality of linolenic acid in the diet of the rat. Journal of Nutrition 101.CrossRef Google Scholar PubMed

Wapnick, S., Norden, D. A., and Venturas, D. J.. 1974. Essential fatty acid deficiency in patients with lesions of the gastrointestinal tract. Gut 15.CrossRef Google Scholar PubMed

White, H. B., Turner, M. D., Turner, A. C., and Miller, R. C.. 1973. Blood lipid alterations in infants receiving intravenous fat-free alimentation. The Journal of Pediatrics 83.Google Scholar PubMed

Widmer, C., and Holman, R. T.. 1950. Polyethenoid fatty acid metabolism. II. Deposition of polyunsaturated fatty acids in fat-deficient rats upon single fatty acid supplementation. Archives of Biochemistry 25.Google Scholar

Wiese, H. F., Gibbs, R. H., and Hansen, A. E.. 1954. Essential fatty acids and human nutrition: I. Serum level for unsaturated fatty acids in healthy children. Journal of Nutrition 52.CrossRef Google Scholar PubMed

Wiese, H. F., and Hansen, A. E.. 1953. Semimicromethod for unsaturated fatty acids of blood serum. Journal of Biological Chemistry 202.Google Scholar

Wiese, H. F., Hansen, A. E., and Adams, D. J. D.. 1958. Essential fatty acids in infant nutrition. I. Linoleic acid requirement in terms of serum di-, tri- and tetraenoic acid levels. Journal of Nutrition 66.Google Scholar PubMed

Wolfram, G., Eckart, J., Walther, B., Zollner, N.. 1978. Factors influencing essential fatty acid requirement in total parenteral nutrition (TPN). The Journal of Parenteral and Enteral Nutrition 2.CrossRef Google Scholar