Abstract
Introduction:
Adequate nutrition is one of the pillars of public health. Before developing and implementing effective intervention programmes to improve nutrition at the population level, it is important to know the nutritional situation of the target group.
Assessment of energy and nutrient intake:
The estimation of nutrient intake from food consumption requires reliable data on food composition. These data are also the fundamentals of food-based dietary guidelines for healthy nutrition, containing the necessary information on food sources for different nutrients. Furthermore, food composition tables can provide information on chemical forms of nutrients and the presence and amounts of interacting components, and thus provide information on their bioavailability. For some nutrients such as vitamin A, vitamin E and niacin, the concept of equivalence has been introduced to account for differences in the availability and biological activity of different chemical forms.
Non-nutritive food components:
Although most food composition tables focus on energy, macro- and micronutrients, interest in non-nutritive components is increasing. Considering the beneficial effects of biologically active secondary plant cell compounds such as polyphenols and carotenoids, more data on these are needed. On the other hand, there are a number of naturally occurring or ‘man-made’ non-nutritive substances with negative effects, and to control exposure, the main dietary sources must be known. Another aspect is contaminants, which could have detrimental effects on consumers’ health. Among these are agrochemicals, industrial pollutants reaching the food chain and substances formed during food preparation. A valid risk assessment requires data on exposure, and thus on the contents of contaminants in foods. However, these data are highly variable and may significantly differ even within narrowly confined regions.
Current food composition databases are far from complete:
The fact that composition tables generally do not provide information about the origin of substances found in food can also influence their usability. For example, the German Nutrient Data base does not discriminate between naturally occurring and added sucrose impeding the estimation of added sucrose intake that should be limited.
Points of focus: Considering the increasing number of persons relying on community nutrition and catering, healthy menu lines can improve the consumers’ diets and contribute to nutrient supply. The development and implementation of appropriate guidelines also need food composition databases (FCBs) to compose meals. The ever-increasing number of new food preparations and manufactured products has resulted in a need for procedures for regularly updated data. Moreover, there is a lack of data particularly for essential trace elements such as copper, chromium or molybdenum and also vitamin K, as well as the already mentioned non-nutritive components.
Limited comparability between countries is another issue. Regional differences arise especially from the use of local varieties, different soil quality or meteorological aspects. This variability is further increased with composite meals because of variation in recipes.
Conclusion:
Information about food composition is necessary for the assessment of diet quality and the development and application of food-based dietary guidelines, providing a useful tool for the field of public health nutrition. In this regard, more attention should be paid to the preparation, extension and maintenance of FCBs.
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References
Atwater WO, Woods CD (1896). The chemical composition of American food materials. US Department of Agriculture. Office of experiment stations. Washington Bull 28, 1–47.
Birlouez-Aragon I, Morales F, Fogliano V, Pain J-P (2010). The health and technological implications of a better control of neoformed contaminants by the food industry. Pathol Biol 58, 232–238.
Buttriss JL, Benelam B (2010). Nutrition and health claims: the role of food composition data. Eur J Clin Nutr 64 (Suppl 3), S8–S13.
Carpenter KJ (2003). A Short History of Nutritional Science: Part 1 (1785–1885). J Nutr 133, 638–645.
Carpenter KJ (2006). Nutritional studies in Victorian prisons. J Nutr 136, 1–8.
Church SM (2006). The history of food composition databases. Nutr Bull 31, 15–20.
Collomb M, Bisig W, Bütikofer U, Sieber R, Bregy M, Etter L (2008). Seasonal variation in the fatty acid composition of milk supplied to dairies in the mountain regions of Switzerland. Dairy Sci Technol 88, 631–647.
Colom A (2009). HANCP—a new tool for small and mediumsized companies to reformulate processed foods and meals (FOOD PRO-FIT). Abstract of a symposium presented at the 19th International Congress of Nutrition 2009, Bangkok. Ann Nutr Metab 55 (Suppl 1), 65.
Deutsche Gesellschaft für Ernährung (DGE) (2009) Qualitätsstandards für die Betriebsverpflegung [Quality standards for canteen meals] 2nd edn, leaflet, Bonn. Available (in German) at: http://www.jobundfit.de/index.php?id=32&L=0&C=0&G=0.
FAO/WHO (Food and Agriculture Organization of the United Nations/World Health Organization) (2002) Human Vitamin and Mineral Requirements. Report of a Joint FAO/WHO Expert Consultation, Bangkok, Thailand. FAO, Rome, Italy.
Gillespie SJ, Kulkarni KD, Daly AE (1998). Using carbohydrate counting in diabetes clinical practice. J Am Diet Assoc 98, 897–905.
Greenfield H, Southgate DAT (2003). Food Composition Data: Production, Management and Use, 2nd edn. FAO: Rome.
Grunert KG, Wills J (2007). A review of European research on consumer response to nutrition information on food labels. J Publ Health 15, 385–399.
Hecke K, Herbinger K, Veberic K, Trobec M, Toplak H, Stamper F et al. (2006). Sugar-, acid- and phenol contents in apple cultivars from organic and integrated fruit cultivation. Eur J Clin Nutr 60, 1136–1140.
Horwitt MK, Harper AE, Henderson LM (1981). Niacin-tryptophan relationships for evaluating niacin equivalents. Am J Clin Nutr 34, 423–427.
Jakszyn P, Agudo A, Ibáñez R, García-Closas R, Pera G, Amiano P et al. (2004). Development of a food database of nitrosamines, heterocyclic amines, and polycyclic aromatic hydrocarbons. J Nutr 134, 2011–2014.
Kiely M, Black LJ, Plumb J, Kroon PA, Hollman PC, Larsen JC et al., EuroFIR consortium (2010). EuroFIR eBASIS: application for health claims submissions and evaluations. Eur J Clin Nutr 64 (Suppl 3), S101–S107.
Labouze E, Goffi C, Moulay L, Azaïs-Braesco V (2007). A multipurpose tool to evaluate the nutritional quality of individual foods: Nutrimap. Public Health Nutr 10, 690–700.
Livingstone MB, Rennie KL (2009). Added sugars and micronutrient dilution. Obes Rev 10 (Suppl 1), 34–40.
Lobstein T, Davies S (2009). Defining and labelling ‘healthy’ and ‘unhealthy’ food. Public Health Nutr 12, 331–340.
McCance RA, Widdowson EM (1940). The chemical composition of foods. Medical Research Council Special Report Series No. 235. His Majesty's Stationery Office: London.
Merchant AT, Dehghan M (2006). Food composition database development for between country comparisons. J Nutr 5, 2.
Moleschott J (1859). Die Physiologie der Nahrungsmittel. Ein Handbuch der Diätetik. [The physiology of foods. A manual of dietetics] 2nd revised edn, Ferber′sche Universitätsbuchhandlung (Emil Roth): Giessen.
Palmer Zimmerman T, Stumbo P, Chenard C, Braithwaite E, Selley B, Databank Directory Committee of the National Nutrient Databank Conference USA (2008). 2008 International Nutrient Databank Directory. Available at: http://www.healthcare.uiowa.edu/gcrc/nndc/survey.html.
Pietinen P, Valsta LM, Hirvonen T, Sinkko H (2007). Labelling the salt content in foods: a useful tool in reducing sodium intake in Finland. Public Health Nutr 11, 335–340.
Raffo A, La Malfa G, Fogliano V, Maiani G, Quaglia G (2006). Seasonal variations in antioxidant components of cherry tomatoes (Lycopersicon esculentum cv. Naomi F1). J Food Compos Anal 19, 11–19.
Ritchie MR., Cummings JH, Morton MS, Steel CM, Bolton-Smith C, Riches AC (2006). A newly constructed and validated isoflavone database for the assessment of total genistein and daidzein intake. Br J Nutr 95, 204–213.
Variyam JN (2008). Do nutrition labels improve dietary outcomes? Health Econ 17, 695–708.
West CE, Eilander A, van Lieshout M (2002). Consequences of revised estimates of carotenoid bioefficacy for dietary control of vitamin A deficiency in developing countries. J Nutr 132, 2920S–2926S.
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Elmadfa, I., Meyer, A. Importance of food composition data to nutrition and public health. Eur J Clin Nutr 64 (Suppl 3), S4–S7 (2010). https://doi.org/10.1038/ejcn.2010.202
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