with the collaboration of Iranian Food Science and Technology Association (IFSTA)

Document Type : Research Article

Authors

Department of Food Science and Technology, Faculty of Agriculture, Ferdowsi University of Mashhad, Mashhad, Iran.

Abstract

Introduction: Grains are important food sources for human diet because of high protein content. There are different kinds of grains used as food worldwide. Today herbal proteins play an important role as food sources in societies. Herbal protein sources are actually strategic points for improving national dietary all over the world. (Mashayekh et al, 2008). Food experts are becoming more open to Quinoa, because of high protein content, (Dallagnol et al., 2013). FAO compares Quinoa grain with concentered milk powder considering high nutritional facts, and called grains as multi vitamin (FAO, quinoa, 2011). According to scientific reports quinoa grain can be replaced with rice in national dietary (Ferreira et al, 2015. Oelk et al., 1992). Quinoa originally cultivated in South America (barazil, Chile, Peru etc.) and known as semi-cereals (Schoenlechner&Berghofe2010).Furthermore, Quinoa flour is a highly nutritional alternative to feed animals as well as in the production of foods which are suitable for patients with celiac disease and gluten-sensitive patient worldwide. (Dallagnol et al, 2013). From the technological point of view, functional properties hold an important position, Water and oil absorption capacity, protein solubility, gelatinization capacity, foam ability and foam stability are the most important functional properties. (Kaur and Singh, 2007. Ameri shahrabi, 1390). Functional properties are affected by different parameters such as protein network structure, lipid, carbohydrate, temperature and pH, respectively. (Alukoand Yada, 1995). This study proposed to investigate the physicochemical properties of Quinoa flour of three different varieties and monitor the effect of pH on their functional characteristics
 
Materials and methods: three different variety of Quinoa grain, originated and cultivated in Peru, were used for experiments, varieties were black (BLACK COLLANA), white (SALCEDO INIA) and red (PASANKALLA), respectively. Grains were grind by 75 degree in mesh and refrigerated during storage. Carbohydrate, fat, ash, moisture content and protein were measured by AACC, (2003) methods. Functional properties were also measured using scientific methods, Owusu-Apenten, (2002), Kaur and Singh (2007) and customized Adebowale et al, (2005) method which used to measure protein solubility, Water and oil absorption capacity, foam ability and foam stability, respectively. Emulsion capacity and emulsion stability were measured using majzoobi et al, (2012) method.
 
Results and discussion: chemical properties are important in both technological and nutritional aspects, chemical characteristics were observed and reported for three studied varieties. Protein solubility known as the first criteria in protein functional properties (Asadpour et al., 2010), this parameter is influenced by pH and the least value were observed in pH=4.5 (protein isoelectric point). Water and oil absorption capacity is one of the most important characteristics in flours (Kinsella, 1979), this parameter is a physical phenomenon which is known as oil or water confined in non-polar protein chains that is dependent on protein spatial shape. (Kinsella, 1979؛ Kaur and Singh, 2007؛ Trayunham et al., 2007) responses led to 1.285, 1.475 and 1.295 for white, red and black varieties, respectively. Foam ability and foamstability, actually known as volume increase caused by fast stirring and usually results in convenient rheological properties in products texture like ice cream and bread.this parameter refers to the ability of protein to make stable foam aginst mechanical and Gravitational stresses and measured in a 90 min. period of time (Oladela & Aina,2007) (Kinsella,1979).  Least responses in this case were observed in pH=4.5 which is an isoelectric range of pH for protein chains. Results were corresponded by responses of El Nasri and El Tinay (2007), Lawal) 2004(, Taghizadeh et al, (2017) and Asadpour et al (2010) about other semi-cereal grains. Last metered parameter was emulsifying ability and emulsion stability, emulsifying in protein structure is an equilibrium between hydrophilic and hydrophobic parts of protein and affected by alkaline range of pH (Ragab et al., 2003( this parameter is influenced by protein solubility which is in the least measures in isoelectric point (Feizi et al., 2013). Results had shown that foam stability would decrease during time passes. This may be due to the coupling of dispersed phase particles (oil droplets) over time. Concerning the effect of pH on emulsion stability, the results showed that the stability values at alkaline pH were higher than that of acidic pH, so that this stability at pH = 9 was significantly different from other pHs. Among the three varieties of quinoa, the amount of protein in the black variety (16.81%) was higher than the other varieties, which could be further investigated as a potential protein source. In addition, results indicate functional properties are influenced by pH, which means out of iso electric point, protein solubility increase and other fictional properties were improve followed.
 

Keywords

AACC (2003b). American Association of Cereal Chemists.Approved Method 08-03,8th ed., St. Paul, MN, USA.
Adebowale, Y. A., Adeyemi, I. A., and Oshodi, A. A., 2005. Functional and physicochemical properties of flours of six Mucuna species. African Journal of Biotechnology 4 (12): 1461-1468.
Aluko, R.E. & Yada, R.Y. 1995. Structure-function relationship of cowpea (Vigna
unguiculata) globulin isolate: influence of pH and NaCl on physicochemical and functional
properties. Food Chemistry, 53: 259-265.
Ameri shahrabi, Badiei, ehsani, Maftoon, azad, sarmadi zadeh, 2011,
Investigating the functional and Thermal Properties of Concentrate and Protein Isolated from Chickpea and Soybean, Journal of Nutrition Sciences and Food Technology of Iran,. (6) 49-58 (in Farsi)
Amza, T. Amadou, I. Zhu, K. and Zhou, H. 2011. Effect of extraction and isolation on physicochemical and functional properties of an underutilized seed protein: Gingerbread plum (Neocarya macrophylla). Food Research International, 44: 553 – 559.
Arogundade L.A., Akinfenwa M.O., and Salawu A.A. 2004.Effect of NaCl and its partial or complete replacement with KCl on some functional properties of defatted Colocynthis citrullus L. seed flour. Food Chemistry, 84: 187–193.
Asadpour, A, Jafari, S.M, sadeghi A, ghorbani, m, 2010. Determination of soluble protein and water absorption capacity of flour from different beans, Iranian Food Science and Technology Research Journal Vol. 6, No. 3, Fall, 2010, p. 184-192 (in Farsi)
Asadpour, A, Jafari, S.M, sadeghi A, ghorbani, m, 2011, Determination of Emulsion and Fouling Capacity and Effect of Acidity and Ionic Power on the Properties of Different Flours from Different Beans,. Iranian Food Science and Technology Research Journal Vol. 7, No. 1, 2011, p. 80-91(in Farsi)
Bakhsh Moghaddam, F, Milani, A, Mortazavi, S.M, Meshkani, S.M (2010), .The Effect of Extraction Methods on Chickpea Protein Isolated Functional Properties, Journal of Food Science and Technology, Vol38, (10), 11-20(in Farsi)
Berghofer, E. and Schoenlechner, R. 2010. Pseudocereals–an overview. Departament of Food Science and Technology, University of Natural Resources and Applied Life Sciences, Vienna-Austria.
Boye J, Zare F, Pletch A. 2010. Pulse protein: Processing, characterization, functional properties and application in food and feed. Food Research International 43: 414–431.
Boye J.I., Aksay S., Roufik S., Ribereau S., Mondor M., Farnworth E. Rajamohamed S.H. 2010.Comparison of the functional properties of pea, chickpea and lentil protein concentrates processed using ultra filtration and isoelectric precipitation techniques. Journal of Food Research International 43: 537 –546.
Dallagnol, A. M., Pescuma, M., De Valdez, G. F. and Rollan, G. "Fermentation of quinoa and wheat slurries by Lactobacillus plantarum CRL 778: proteolytic activity." Appl Microbiol Biotechnol 97 (2013): 3129-3140.
Damodaran, S. 1996. Functional properties. Food proteins: properties and characterization. VCH, New York, pp 167–234.
Du, S., Jiang, H., Yu, X., Jane, J. 2012. Physicochemical and functional properties of whole legume flour. LWT - Food Science and Technology, 55, 308-313.
El Nasri, N. A., & El Tinay, A. H. 2007. Functional properties of fenugreek (Trigonella foenum graecum) protein concentrate. Food Chemistry, 103, 582–589.
FAO, Quinoa: "An ancient crop to contribute to world food security". Regional Office for Latin America and the Caribbean. July (2011).
Feizi, S, Varidi, M, zareie, F, varidi, M, 2013, Investigation Chemical Composition, Color Parameters and Functional Properties of Fenugreek Flour and Comparison with Soybean Flour, Journal of Research and Innovation in Food Science and Technology,. (2)2, 121-138 (in Farsi)
Ferreira, D. S., Pallone, J. A. L., and Poppi, R. J. "Direct analysis of the main chemical constituents in Chenopodium quinoa grain using Fourier transform near-infrared spectroscopy." Food Control 48 (2015): 91-95.
Ferreira, D. S., Pallone, J. A. L., and Poppi, R. J. "Direct analysis of the main chemical constituents in Chenopodium quinoa grain using Fourier transform near-infrared spectroscopy." Food Control 48 (2015): 91-95.
Hung, S. C., & Zayas, J. F. 1991.Emulsifying capacity and emulsionstability of milkproteins and corn germ protein flour. Journal ofFood Science, 56, 1216–1223.
Jancurova, M., Minarovicova, L. and Dandar, A. 2009. Quinoa–a review. Czech Journal of Food Sciences. 27(2): 71-79.
Joshi, A. U., Liu, C., Sathe, S. K. 2015. Functional properties of select seed flours.LWT - Food Science and Technology 60: 325-331.
Kanu, P. J., Kerui, Z., Ming, Z. H., Haifeng, Q., Kanu, J. B., and Kexue, Z. 2007. Sesame protein 11: Functional properties of sesame (Sesamum indicum L.) protein isolate as influenced by PH, temperature, time and ratio of flour to water during its production. Asian Journal of Biochemistry, 5: 289-301.
Kaur M, Singh Sandha K. 2010. Functional, thermal and pasting characteristics of flours from different lentil (Lens culinaris) cultivars. Journal of food science and technology-mysore 47(3):273–278.
Kaur, M., Singh, N.2007. Characterization of protein isolates from different Indian chickpea cultivars. Food Chemistry, 102: 366-74.
Kinsella, J. E. 1979. Functional properties of soy protein. Journal of American Oil Chemists Society, 56: 242–249.
Lawal, O. S. 2004, Functionality of African locust bean (Parkia biglobossa) protein isolate: effects of pH, ionic strength and various protein concentrations. Journal of Food Chemistry, 86: 345-355.
Lilian E. A. J. 2009. Chapter 1 Quinoa (Chenopodium quinoa Willd.): Composition, Chemistry, Nutritional, and Functional Properties. Advances in Food and Nutrition Research Volume 58, Pages 1-3
M. Taghizadeh, B. Shokrollahi, F.Hamedi, 2016 Evaluation the physicochemical and mechanical properties of bittervetch seed (Viciaervilia) and the functional properties of its flour, Iranian Food Science and Technology Research Journal Vol. 13, No. 1, p. 38- 52(in Farsi)
Majzoobi, M.., Abedi, E., Farahnaki, A., Aminlari, M. 2012. Functional properties of acetylatedglutenin and gliadin at varying pH values. Food Chemistry, 133:1402–1407.
Maruatona, G. N., Duodu, K. G., Minnaar, A. 2010. Physicochemical, nutritional and functional properties of marama bean flour. Food chemistry, 121, 400-405.
Oelk, E. A., Puntnam, D. H., Teynor, T. M., and E. S., Oplinger Feb 1992. Alternative Field Crops Manual, Quinoa. University of Wisconsin Extension, Cooperative Extension.
Oladele, A. K. and J. O. Aina (2007). "Chemical composition and functional properties of flour produced from two varieties of tigernut (Cyperusesculentus)." African Journal of Biotechnology 6(21): 2473-2476.
Owusu-Apenten, R. K. 2002. Food protein analysis Quantitative effects on processing. Marcel Dekker, Inc. Basel. New York.
Piornos, J. A., Burgos-Diaz, C., Ogura, T., Morales, E., Rubilar, M., Maureira-Butler, E., Salvo-Garrido, H. 2015. Functional and physicochemical properties of a protein isolate from AluProt-CGNA: A novel protein-rich lupin variety (Lupinus luteus). Food Research International, 76(3): 719–724.
Ragab, D. M., Babiker, E. E., & El Tinay, A. H. (2003). Fractionation, solubility and functional properties of cowpea (Vigna unguiculata) proteins as affected by pH and/or salt concentration. Food Chemistry, 84, 207–212.
Ravaghi, M, Mazaheri, M, Asoodeh, A., 2010, Evaluation of performance characteristics of four types of soybean flour in Iran, Journal of Food Science and Technology, Vol6, (3), 1-7(in Farsi)
Sathe, S. K., Salunkhe, D. K. 1981. Functional properties ofgreat northern bean proteins: emulsion, foaming, viscosity and gelation properties. Journal of Food Science, 46: 71-75.
Seena, S. K. Sridhar, R. 2005, Physiochemical, functional and cooking properties of Canavalia, Journal of Food Chemistry, 32: 406 – 412.
Sepahvand, N, Kahbazi, M, 2010, Quinoa, a valuable plant to food security and sustainable agriculture in Iran, 11th Iranian Congress of Plant Breeding and Plant Breeding, Research Institute of Environmental Sciences, Shahid Beheshti University, Tehran,. Pp1811-1814 (in Farsi)
Shokrollahi, Mohebi, Varidi, M, 2013, Evaluation of the effect of temperature, frying time and the addition of lentil flour to batter formulation on the physicochemical and qualitative characteristics of fried crust using a shell model (DFCM),. Iranian Food Science and Technology Research Journal Vol. 10, No. 3, p. 266- 275 (in Farsi)
Traynham, T.L., Myers, D.J., Carriquiry, A.L., Johnson, L.A., and Amer, J. 2007. Evaluation of water holding capacity for wheat–soy flour blends. Journal of the American Oil Chemists' Society, 84: 151–155.
Vadivel, V. and Janardhanan K. 2001. Nutritional and anti-nutritional attributes of the under-utilized legume, Cassia floribunda Cav. Food Chemistry 73: 209-215.
CAPTCHA Image