Whole Grains and Health. Группа авторов
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36 Dick, J.W., Shuey, W.C., and Banasik, O.J. (1977). Adjustment of rheological properties of flour by fine grinding and air classification Cereal Chemistry, 54, 246–255.
37 Doehlert, D.C., and Moore, W.R. (1997). Composition of oat bran and flour prepared by three different mechanisms of dry milling. Cereal Chemistry, 74, 403–406.
38 Edelmann, M., Kariluoto, S., Nyström, L., and Piironen, V. (2012). Folate in oats and its milling fractions. Food Chemistry, 135, 1938–1947.
39 Escobar, J., Loran, S., Gimenez, I., Ferruz, E., Herrera, M., Herrera, A., and Arino, A. (2013). Occurrence and exposure assessment of Fusarium mycotoxins in maize germ, refined corn oil and margarine. Food and Chemical Toxicology, 62, 514–520.
40 Eugster, W. (2005). Avantages commerciaux réalisés grâce au process de décorticage “Peeling.” Industrie des Céréales, 143, 31–32.
41 Evers, A.D., and Bechtel, D.B. (1988). Microscopic structure of the wheat grain. In Wheat : Chemistry and Technoloy (ed. Y. Pomeranz), pp. 47–95 AACC.
42 Evers, A.D., Blakeney, A.B., and O’Brien, L. (1999). Cereal structure and composition. Australian Journal of Agricultural Research, 50, 629–650.
43 Evers, A.D., and Millar, S. (2002). Cereal grain structure and development: Some implications for quality. Journal of Cereal Science, 36, 261–284.
44 Fang, X.Z., and Moreau, R.A. (2014). Extraction and demulsification of oil from wheat germ, barley germ, and rice bran using an aqueous enzymatic method. Journal of the American Oil Chemists Society, 91, 1261–1268.
45 Fellers, D.A., Mossman, A.P., Johnston, P.H., and Wheeler, E.L. (1976). Mechanical debranning of whole‐kernel wheat. III. Composition, cooking characteristics, and storage stability. Cereal Chemistry, 53, 308–317.
46 Friedman, M. (2013). Rice brans, rice bran oils, and rice hulls: Composition, food and industrial uses, and bioactivities in humans, animals, and cells. Journal of Agricultural and Food Chemistry 61, 10626–10641.,
47 Gelmez, N., Kincal, N.S., and Yener, M.E. (2009). Optimization of supercritical carbon dioxide extraction of antioxidants from roasted wheat germ based on yield, total phenolic and tocopherol contents, and antioxidant activities of the extracts. Journal of Supercritical Fluids, 48, 217–224.
48 Gerschwiler, O., Eugster, W., and Zwahlen, U. (2006). Method and device for husking and degerminating cereals. A.G., B. US Patent application publication US 2006/0053764 A.
49 Gimenez, I., Herrera, M., Escobar, J., Ferruz, E., Loran, S., Herrera, A., and Arino, A. (2013). Distribution of deoxynivalenol and zearalenone in milled germ during wheat milling and analysis of toxin levels in wheat germ and wheat germ oil. Food Control, 34, 268–273.
50 Girardet, N., and Webster, F.H. (2011). Oat milling : specification, storage, and processing. In Oats: Chemistry and technology (ed. F.H. Webster), pp. 301–319. AACC.
51 Gomez, M., Pardo, J., Oliete, B., and Caballero, P. (2009). Effect of the milling process on quality characteristics of rye flour. Journal of the Science of Food and Agriculture, 89, 470–476.
52 Gomez, M., Ruiz‐Paris, E., and Oliete, B. (2011). Influence of wheat milling on low‐hydration bread quality developed by sheeting rolls. Food Science and Technology International, 17, 256–265.
53 Greffeuille, V., Abecassis, J., Bar L’Helgouach, C., and Lullien‐Pellerin, V. (2005). Differences in the aleurone layer fate between hard and soft common wheats at grain milling. Cereal Chemistry, 82, 138–143.
54 Greffeuille, V., Abecassis, J., Barouh, N., Villeneuve, P., Mabille, F., Bar L’Helgouac’h, C., and Lullien‐Pellerin, V. (2007). Analysis of the milling reduction of bread wheat farina: physical and biochemical characterisation. Journal of Cereal Science, 45, 97–105.
55 Greffeuille, V., Abecassis, J., Rousset, M., Oury, F.X., Faye, A., Bar L'Helgouac’h, C., and Lullien‐Pellerin, V. (2006). Grain characterization and milling behaviour of near‐isogenic lines differing by hardness. Theoretical and Applied Genetics, 114, 1–12.
56 Harris, P.J., Chavan, R.R., and Ferguson, L.R. (2005). Production and characterisation of two wheat‐bran fractions: an aleurone‐rich and a pericarp‐rich fraction. Molecular Nutrition & Food Research, 49, 536–545.
57 He, J.B., Penson, S., Powers, S.J., Hawes, C., Shewry, P.R., and Tosi, P. (2013). Spatial patterns of gluten protein and polymer distribution in wheat grain. Journal of Agricultural and Food Chemistry, 61, 6207–6215.
58 Hell, J., Kneifel, W., Rosenau, T., and Böhmdorfer, S. (2014). Analytical techniques for the elucidation of wheat bran constituents and their structural features with emphasis on dietary fiber – A review. Trends in Food Science & Technology, 35, 102–113.
59 Hemery, Y., Chaurand, M., Holopainen, U., Lampi, A.M., Lehtinen, P., Piironen, V., Sadoudi, A., and Rouau, X. (2011a). Potential of dry fractionation of wheat bran for the development of food ingredients, part I: Influence of ultra‐fine grinding. Journal of Cereal Science, 53, 1–8.
60 Hemery, Y., Holopainen, U., Lampi, A.M., Lehtinen, P., Nurmi, T., Piironen, V., Edelmann, M., and Rouau, X. (2011b). Potential of dry fractionation of wheat bran for the development of food ingredients, part II: Electrostatic separation of particles. Journal of Cereal Science, 53, 9–18.
61 Hemery, Y., Lullien‐Pellerin, V., Rouau, X., Abecassis, J., Samson, M.F., Aman, P., von Reding, W., Spoerndli, C., and Barron, C. (2009). Biochemical markers: Efficient tools for the assessment of wheat grain tissue proportions in milling fractions. Journal of Cereal Science, 49, 55–64.
62 Hemery, Y., Rouau, X., Lullien‐Pellerin, V., Barron, C., and Abecassis, J. (2007). Dry processes to develop wheat fractions and products with enhanced nutritional quality. Journal of Cereal Science, 46, 327–347.
63 Hemery, Y.M., Anson, N.M., Havenaar, R., Haenen, G., Noort, M.W.J., and Rouau, X. (2010). Dry‐fractionation of wheat bran increases the bioaccessibility of phenolic acids in breads made from processed bran fractions. Food Research International, 43, 1429–1438.
64 Heneen, W.K., Karlsson, G., Brismar, K., Gummeson, P.O., Marttila, S., Leonova, S., Carlsson, A.S., Bafor, M., Banas, A., Mattsson, B., Debski, H., and Stymne, S. (2008). Fusion of oil bodies in endosperm of oat grains. Planta, 228, 589–599.
65 Hentschel, V., Kranl, K., Hollmann, J., Lindhauer, M.G., Boehm, V., and Bitsch, R. (2002). Spectrophotometric determination of yellow pigment content and evaluation of carotenoids by high‐performance liquid chromatography in durum wheat grain. Journal of Agricultural and Food Chemistry, 50, 6663–6668.
66 Hettiarachchy, N.S., Ju, Z.Y., Siebenmorgen, T., and Sharp, R.N. (2000). Rice : production, processing and utilization. In Handbook of Cereal Science and Technology, Second Edition, Revised and Expanded (eds. K. Kulp and J.G. Ponte), pp. 203–221. Dekker.
67 Hoije, A., Grondahl, M., Tommeraas, K., and Gatenholm, P. (2005). Isolation and characterization of physicochemical and material properties of arabinoxylans from barley husks. Carbohydrate Polymers, 61, 266–275.
68 Hsi‐Mei, L. (1999). A simple procedure for the measurement of wheat germ in the milling products by fluorescence spectroscopy. Food Science and Agricultural Chemistry, 1, 47–54.
69 Izydorczyk, M.S., Jacobs, M.S., and Dexter, J.E. (2003). Distribution and structural variation of nonstarch polysaccharides in milling fractions of