Rheological, Physical and Sensory Properties of Mayonnaise Formulated with Sesame Oil
الموضوعات :R. Pazhvand 1 , M. Khavarpour 2
1 - M. Sc. Graduated of the Department of Food Science and Technology, Ayatollah Amoli Branch, Islamic Azad University, Amol, Iran.
2 - Assistant Professor of the Department of Chemical Engineering, Ayatollah Amoli Branch, Islamic Azad University, Amol, Iran.
الکلمات المفتاحية: Mayonnaise, Physical Properties, Rheological, Sensory, Sesame Oil,
ملخص المقالة :
Fat has an important role in creating texture, color and viscosity; but, it might be a source of many diseases in human. Mayonnaise is one of the most widely used sauces that contains fat in its formulation. There is an increase demand in reduction of the amount of fat in the diet or use of unsaturated fat. In the present study, mayonnaise samples containing various amounts of sesame oil were produced. Physical and sensory properties were carried out. Furthermore, the consistency coefficient and flow behavior index were calculated as rheological parameters. All mayonnaise samples fitted by power-low model exhibited non-Newtonian and pseudoplastic behavior. Mayonnaise containing 100% sesame oil showed maximum redness and minimum lightness. The sensory results demonstrated that increasing in the amount of sesame oil led to a reduction in overall acceptability. In conclusion, sesame oil at levels of 20% was recommended to be used in mayonnaise formulation for enhancing the nutritional value of mayonnaise.
Aghdaei, S. A., Aalami, M., Geefan, S. B. & Ranjbar, A. (2014). Application of Isfarzeh seed (Plantago ovate L.) mucilage as a fat mimetic in mayonnaise. Journal of Food Science and Technology, 51(10), 2748-2754.
Amin, M. H. H., Elbeltagy, A. E., Mustafa, M. & Khalil, A. H. (2014). Development of low fat mayonnaise containing different types and levels of hydrocolloid gum. Journal of Agroaliment Processes and Technologies, 20 (1), 54-63.
Aslanzadeh, M., Mizani, M., Alimi, M. & Gerami, A. (2012) Rheological properties of low fat mayonnaise with different levels of modified wheat bran. Journal of Food Bioscience & Technology, 2, 27-34.
Azhagu Saravana Babu, P., Vajiha Aafrin, B., Archana, G., Sabina, K., Sudharsan, K., Radha Krishnan, K., Babuskin, S., Sivarajan, M. & Sukumar, M. (2016). Polyphenolic and phytochemical content of Cucumis sativus seeds and study on mechanism of preservation of nutritional and quality outcomes in enriched mayonnaise. International Journal of Food Science & Technology, 51(6),1417-1424.
Dail, R. V. & Steffe, J. F. (1990). Rheological characterization of crosslinked waxy maize starch solutions under low acid aseptic processing conditions using tube viscometry techniques. Journal of Food Science, 55(6),1660-1665.
Depree, J. & Savage, G. (2001). Physical and flavour stability of mayonnaise. Trends in Food Science & Technology, 12(5), 157-163.
Di Mattia, C., Balestra, F., Sacchetti, G., Neri, L., Mastrocola, D. & Pittia, P. (2015). Physical and structural properties of extra-virgin olive oil based mayonnaise. LWT-Food Science and Technology, 62, 764-770.
Elleuch, M., Besbes, S., Roiseux, O., Blecker, C. & Attia, H. (2007). Quality characteristics of sesame seeds and by-products. Food Chemistry,103(2), 641-650.
Ennouri, M., Evelyne, B., Laurence, M. & Hamadi, A. (2005). Fatty acid composition and rheological behaviour of prickly pear seed oils. Food Chemistry, 93(3), 431-437.
Giacintucci, V., Di Mattia, C., Sacchetti, G., Neri, L. & Pittia, P. (2016). Role of olive oil phenolics in physical properties and stability of mayonnaise-like emulsions. Food Chemistry, 213, 369-377.
Goshawk, J., Binding, D., Kell, D. & Goodacre, R. (1998). Rheological phenomena occurring during the shearing flow of mayonnaise. Journal of Rheology, 42(6), 1537-1553.
Karas, R., Skvarca, M. & Zlender, B. (2002). Sensory quality of standard and light mayonnaise during storage. Food Technology and Biotechnology, 40(2),119-128.
Kostyra, E. & Baryłko-Pikielna, N. (2007). The effect of fat levels and guar gum addition in mayonnaise-type emulsions on the sensory perception of smoke-curing flavour and salty taste. Food Quality and Preference, 18(6), 872-879.
Lee, E. & Choe, E. (2012). Changes in oxidation-derived off-flavor compounds of roasted sesame oil during accelerated storage in the dark. Biocatalysis and Agricultural Biotechnology, 1(1), 89-93.
Lee, J. Y., Kim, M. J. & Choe, E. O. (2008). Study on the changes of tocopherols and lignans and the oxidative properties of roasted sesame oil during manufacturing and storage. Korean Journal of Food Science and Technology, 40(1),15-20.
Liu, H., Xu, X. & Guo, S. D. (2007). Rheological, texture and sensory properties of low-fat mayonnaise with different fat mimetics. LWT-Food Science and Technology, 40(6), 946-954.
McClements, D. J. & Demetriades, K. (1998). An integrated approach to the development of reduced-fat food emulsions. Critical Reviews in Food Science and Nutrition, 38(6), 511-536.
Moslavac, T., Pozderović, A., Pichler, A., Benčić, Đ., Vilušić, M. & Barulek, I. (2012). The effect of exrta virgin olive oil and lemon juice on rheological properties of mayonnaise. MESO. 14(2).
Peressini, D., Sensidoni, A, & de Cindio, B. (1998). Rheological characterization of traditional and light mayonnaises. Journal of Food Engineering, 35(4), 409-417.
Rahmati, K., Tehrani, M. M. & Daneshvar, K. (2014). Soy milk as an emulsifier in mayonnaise: physico-chemical, stability and sensory evaluation Journal of Food Science and Technology, 51(11), 3341-3347.
Saberi, N. & Mohamadifar, M. (2012). The effect of oil type on viscoelastic characteristics of mayonnaise. Journal of Food Technology and Nutrtion, 9(2), 5-16.
Salehi, F. & Kashaninejad, M. (2017). The Effect of Quince Powder on Rheological Properties of Batter and Physico-Chemical and Sensory Properties of Sponge Cake. Journal of Food Biosciences and Technology, 7(1), 1-8.
Sánchez, R., Franco, J., Delgado, M., Valencia, C. & Gallegos, C. (2011). Rheology of oleogels based on sorbitan and glyceryl monostearates and vegetable oils for lubricating applications. Grasas Aceites, 62(3), 328-336.
Shen, R., Luo, S. & Dong, J. (2011). Application of oat dextrine for fat substitute in mayonnaise. Food Chemistry, 126(1), 65-71.
Štern, P., Mikova, K., Pokorný, J. & Valentová, H. (2007). Effect of oil content on the rheological and textural properties of mayonnaise. Journal of Food and Nutrition Research, 46(1), 1-8.
Štern, P., Pokorny, J., Šediva, A. & Panovska, Z. (2008). Rheological and sensory characteristics of yoghurt-modified mayonnaise. Czech Journal of Food Sciences, 26(3), 190-198.
Thaiudom, S. & Khantarat, K. (2011). Stability and rheological properties of fat-reduced mayonnaises by using sodium octenyl succinate starch as fat replacer. Procedia Food Science, 1, 315-321.
Tippetts, M. & Martini, S. (2009). Effect of oil content and processing conditions on the thermal behaviour and physicochemical stability of oil‐in‐water emulsions. International Journal of Food Science & Technology, 44(1), 206-215.
Worrasinchai, S., Suphantharika, M., Pinjai, S. & Jamnong, P. (2006). β-Glucan prepared from spent brewer's yeast as a fat replacer in mayonnaise. Food hydrocolloids, 20(1), 68-78.
Xiong, R., Xie, G. & Edmondson, A. (2000). Modelling the pH of mayonnaise by the ratio of egg to vinegar. Food Control, 11(1), 49-56.
