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03 Issues & Trends
Cereal Foods World, Vol. 63, No. 3
DOI: https://doi.org/10.1094/CFW-63-3-0114
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Effects of Processing on the Functionality of Cereal Polysaccharides
Ndegwa H. Maina1 and Kati Katina2
Department of Food and Nutrition Science, University of Helsinki, Helsinki, Finland

1 E-mail: henry.maina@helsinki.fi
2 E-mail: kati.katina@helsinki.fi


Abstract

Cereal polysaccharides, which can be divided into starch and nonstarch polysaccharides, are an important source of energy and dietary fiber in the human diet. From an energy perspective, starch is poorly digested in its native form. Thermal treatment is required to induce changes (gelatinization) in the native starch granule structure that render starch molecules more accessible for digestion by enzymes. However, the increasing occurrence of type 2 diabetes, which is due, in part, to consumption of high levels of rapidly digestible, refined starches, has led to increased demand for low glycemic index (GI) foods. The role of cereal fibers in the prevention of many chronic diseases is well established in the literature, which has led to dietary recommendations that call for increased intake of whole grain products or products rich in cereal fibers. In response, food manufacturers are tailoring processing conditions to develop food structures that deliver the desired physiological functionality (e.g., high fiber, low GI, cholesterol lowering effects, etc.) while maintaining good sensory properties. This article highlights the influence of common cereal processing operations, such as milling, fermentation, baking, and extrusion, on the predominant functional cereal polysaccharides: arabinoxylan and β-glucan.




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References

  1. Ames, N., Storsley, J., and Tosh, S. Effects of processing on physicochemical properties and efficacy of β-glucan from oat and barley. Cereal Foods World 60:4, 2015.
  2. Andersson, A. A. M., Armö, E., Grangeon, E., Fredriksson, H., Andersson, R., and Åman, P. Molecular weight and structure units of (13, 14)-β-glucans in dough and bread made from hull-less barley milling fractions. J. Cereal Sci. 40:195, 2004.
  3. Andersson, A. A. M., Courtin, C. M., Delcour, J. A., Fredriksson, H., Schofield, J. D., Trogh, I., Tsiami, A. A., and Åman, P. Milling performance of north European hull-less barleys and characterization of resultant millstreams. Cereal Chem. 80:667, 2003.
  4. Arcila, J. A., Weier, S. A., and Rose, D. J. Changes in dietary fiber fractions and gut microbial fermentation properties of wheat bran after extrusion and bread making. Food Res. Int. 74:217, 2015.
  5. Bagdi, A., Tömösközi, S., and Nyström, L. Hydroxyl radical oxidation of feruloylated arabinoxylan. Carbohydr. Polym. 152:263, 2016.
  6. Boskov Hansen, H., Andreasen, M., Nielsen, M., Larsen, L., Bach Knudsen, K., Meyer, A., Christensen, L., and Hansen, Å. Changes in dietary fibre, phenolic acids and activity of endogenous enzymes during rye bread-making. Eur. Food Res. Technol. 214:33, 2002.
  7. Djurle, S., Andersson, A. A., and Andersson, R. Milling and extrusion of six barley varieties, effects on dietary fibre and starch content and composition. J. Cereal Sci. 72:146, 2016.
  8. Faure, A. M., Knüsel, R., and Nyström, L. Effect of the temperature on the degradation of β-glucan promoted by iron(II). Bioact. Carbohydr. Dietary Fibre 2:99, 2013.
  9. Johansson, L., Virkki, L., Anttila, H., Esselström, H., Tuomainen, P., and Sontag-Strohm, T. Hydrolysis of β-glucan. Food Chem. 97:71, 2006.
  10. Katina, K., Laitila, A., Juvonen, R., Liukkonen, K. H., Kariluoto, S., Piironen, V., Landberg, R., Åman, P., and Poutanen, K. Bran fermentation as a means to enhance technological properties and bioactivity of rye. Food Microbiol. 24:175, 2007.
  11. Kivelä, R., Nyström, L., Salovaara, H., and Sontag-Strohm, T. Role of oxidative cleavage and acid hydrolysis of oat beta-glucan in modelled beverage conditions. J. Cereal Sci. 50:190, 2009.
  12. Mäkelä, N., Sontag-Strohm, T., and Maina, N. H. The oxidative degradation of barley β-glucan in the presence of ascorbic acid or hydrogen peroxide. Carbohydr. Polym. 123:390, 2015.
  13. Rakha, A., Åman, P., and Andersson, R. Characterisation of dietary fibre components in rye products. Food Chem. 119:859, 2010.
  14. Rieder, A., Ballance, S., and Knutsen, S. H. Viscosity based quantification of endogenous β-glucanase activity in flour. Carbohydr. Polym. 115:104, 2015.
  15. Rieder, A., Holtekjølen, A. K., Sahlstrøm, S., and Moldestad, A. Effect of barley and oat flour types and sourdoughs on dough rheology and bread quality of composite wheat bread. J. Cereal Sci. 55:44, 2012.
  16. Rumpagaporn, P., Kaur, A., Campanella, O. H., Patterson, J. A., and Hamaker, B. R. Heat and pH stability of alkaliextractable corn arabinoxylan and its xylanasehydrolyzate and their viscosity behavior. J. Food Sci. 77(1):H23, 2012.
  17. Vatandoust, A., Ragaee, S., Wood, P. J., Tosh, S. M., and Seetharaman, K. Detection, localization, and variability of endogenous β-glucanase in wheat kernels. Cereal Chem. 89:59, 2012.
  18. Zhang, M., Bai, X., and Zhang, Z. Extrusion process improves the functionality of soluble dietary fiber in oat bran. J. Cereal Sci. 54:98, 2011.