Reduction of acrylamide in Petit Beurre and Madar biscuits using whey protein powder and sodium bicarbonate

Niazmand, Razieh; Khechumian, Arpa; Shahidi Noghabi, Mostafa

doi:10.22101/JRIFST.2015.11.22.431

Reduction of acrylamide in Petit Beurre and Madar biscuits using whey protein powder and sodium bicarbonate

Document Type : Original Paper

Authors

¹ Assistant Professor, Department of Food Chemistry, Research Institute of Food Science and Technology, Mashhad, Ira

² MSc. Graduated Student, Department of Food Science &Technology, Islamic Azad University, Damghan Branch, Semnan, Iran

³ Assistant Professor, Department of Food Chemistry, Research Institute of Food Science and Technology, Mashhad, Iran

10.22101/JRIFST.2015.11.22.431

Abstract

Acrylamide is a chemical compound which starchy foods such as biscuits are prone to formation. Since biscuit is one of the most consumed floury products specially for children, the objective of this research is to assay the effect of the replacement of whey protein powder with dried milk in the 3 levels (25, 75 and 100 %), and the effect of the replacement of ammonium hydrogen carbonate and baking powder with sodium hydrogen carbonate on acrylamide, reducing sugar, protein, moisture, pH and acidity content on Petit Beurre and Madar biscuits were investigated. By increasing whey protein powder replacement in both kinds of biscuits, pH, only in samples which were completely produced by dried milk powder and whey protein powder, was considerable. In this phase protein content had decreasing, while acidity and reducing sugar had increasing procedure. The content of acrylamide in Madar and Petit Beurre biscuit samples produced by 100 % whey protein powder, in comparison with control, decreased 11.9 % and 4.1 % respectively, which may be related to the decrease of protein content in formulation. The content of pH and acidity respectively decreased and increased by replacing sodium hydrogen carbonate with baking powder. By using sodium hydrogen carbonate in both biscuit samples the content of reducing sugar considerably decreased. The minimum and maximum amount of acrylamide was observed in the samples containing sodium hydrogen carbonate and ammonium hydrogen carbonate, respectively.

Keywords

References

استاندارد ملی ایران. 1385. کیک- ویژگی‌ها و روش‌های آزمون. شماره 2553. تجدید نظر سوم.

استاندارد ملی ایران. 1387. پنیر و فرآورده‌های آن- پودر آب پنیر- ویژگی‌ها و روش‌های آزمون. شماره 6959، تجدید نظر اول.

استاندارد ملی ایران. 1388. بیسکویت- ویژگی‌ها و روش‌های آزمون. شماره 37. تجدید نظر ششم.رجب زاده، ن. 1386. مبانی فناوری غلات. جلد دوم. نوبت چاپ دوم. انتشارات دانشگاه تهران. 572 صفحه.

Amrein, T.M., Schonbachler, B., Escher, F. & Amado, R. 2004. Acrylamide in gingerbread: critical factors for formation and possible ways for reduction. Journal of Agricultural and Food Chemistry, 52: 4282- 4288.

Arribas-Lorenzo, G. Fogliano, V. & Morales, F. J. 2009. Acrylamide formation in a cookie system as influenced by the oil phenol profile and degree of oxidation. European Food Research Technology, 229: 63–72.

Biedermann, M., Biedermann-Berm, S. & Noti, A. 2002. Two GC-MS methods for the analysis of acrylamide in foodstuffs. Mitteilungen aus Lebensmitteluntersuchung und Hygiene, 93: 638- 652.

Boroushaki, M.T., Nikkhah, E., Kazemi, A., Oskooei, M. & Raters, M. 2010. Determination of acrylamide level in popular Iranian brands of potato and corn products. Food and Chemical Toxocology, 10: 2581- 2584.

Claus, A., Carle, R. & Schieber, A. 2008. Acrylamide in cereal products: a review. Journal of Cereal Science, 47: 118–133.

Claus, A., Mongili, M., Weisz, G., Schieber, A. & Carle, R. 2008. Impact of formulation and technological factors on the acrylamide content of wheat bread and bread rolls. Journal of Cereal Science, 47: 546- 554.

Codex alimentarius, 2003. Discussion paper on acrylamide. Available from: http://www.codexalimentarius.com/CX/FAC 04/36/34, Rotterdam, Netherlands.

EL-Saied, M.H., Sharaf, A.M., Abul-Fadl M.M. & EL-Badry, N. 2008. Reduction of acrylamide formation in fried potato strips by different pre-frying treatments. World Journal of Dairy & Food Sciences 3 (1): 17-24.

Erdogdu, S. B., Palazoglu, T. K., Gokmen, V., Senyuva, H. Z. & Ekiz. H. I. 2007. Reduction of acrylamide formation in French fries by microwave pre-cooking of potato strips. Journal of the Science of Food and Agriculture, 87: 133–137.

Friedman, M. & Levin, C.E. 2008. Review of methods for the reduction of dietary content and toxicity of acrylamide. Journal of Agricultural and Food Chemistry, 56: 6113- 6140.

Graf, M., Amrein, T.M., Graf, S., Szalay, R., Escher, F., & Amado, R. 2006. Reducing the acrylamide content of a semi-finished biscuit on industrial scale. LWT, 39: 724- 728

Granda, C. 2005. Kinetics of acrylamide formation in potato chips. Journal of Biological and Agricultural Engineering, 92: 78- 82.

Hollnagel, A., & Kroh, L.W. 1998. Formation of R-dicarbonyl fragments from mono and disaccharides under caramelization and Maillard reaction conditions. Z Lebensm. Unters. Forsch. As Food Research Technology, 207: 50- 54.

Keramat, J., Lebali, A., Prost, C., & Jafari, M. 2011. Acrylamid in baking products: Journal of Food Bioprocess Technology, 4: 530- 543.

Ledl, F., & Schleicher, E. 1990. New aspects of the Maillard reaction in foods and in the human body. Angewandte Chemie International Edition in English, 29 (6): 565- 594.

Mavropoulou, I.P., & Kosikowski, F.V. 1972. Composition, solubility, and stability of whey powders. Journal of Dairy Science, 56: 1128- 1134.

Mustafa, A. 2008, Acrylamide in Bread Precursors, Formation and Reduction. Doctoral thesis, Swedish University of Agricultural Sciences. Uppsala. Sweden.

Ou, S., Shi, J., Huang, C., Zhang, G., Teng, J., Jiang, Y. & Yang B. 2010. Effect of antioxidants on elimination and formation of acrylamide in model reaction systems. Journal of Hazardous Materials, 182: 863–868.

Parzefall, W. 2008. Mini-review of toxicity of dietary acrylamide. Food and Chemical Toxicology, 46: 1360- 1364.

Pedreschi, F. Kaack, K. & Granby, K. 2008. The effect of asparaginase on acrylamide formation in French fries. Food Chemistry, 109 (2): 386–392.

Pedreschi, F., Granby K. & Risum, J. 2010. Acrylamide mitigation in potato chips by using NaCl. Food Bioprocess Technology, 3: 917–921.

Piloty, M. & Baltes, W. 1979. Investigations on the reaction of amino acids with R-dicarbonyl compounds. 1. Reactivity of amino acids in the reaction with R-dicarbonyl compounds (in German). Z. Lebensm.-Unters.-Forsch, 168: 368- 373.

Salazar, R., Arambula-Villa, G., Vazquez-Landaverde, P.A., Hidalgo, F. & Zamora, R. 2012. Mitigating effect of Amaranth (Amarantus hypochondriacus) protein on acrylamide formation in foods. Food Chemistry, 135: 2293- 2298.

Sirot V., Hommet, F., Tard, A. & Leblanc, J. 2012. Dietary acrylamide exposure of the French population: results of the Second French Total Diet Study, Food and Chemical Toxicology, 50 (3-4): 889–894.

Watt, B.K. & Merill, A.L. 1963. Composition of foods. Raw, processed, prepared. U.S. Deptartment of Agriculture. Agricultural handbook. No. 8. 190 pp.