Edible Utilization of Xanthan- guar Oleogels as a Shortening Replacement in Sponge Cake: Physicochemical Properties
محورهای موضوعی :Mohammad Noshad 1 , Mohammad Hojjati 2 , Mina Hassanzadeh 3 , Reza Zadeh-dabbagh 4 , Marjan HosseinKhani 5
1 - Department of Food Science & Technology, Agricultural Sciences and Natural Resources University of Khuzestan, Mollasani, Iran
2 - Department of Food Science & Technology, Agricultural Sciences and Natural Resources University of Khuzestan, Mollasani, Iran
3 - Department of Food Science & Technology, Agricultural Sciences and Natural Resources University of Khuzestan, Mollasani, Iran
4 - Food and Drugs Affairs of Ahvaz Jundishapur University of Medical Sciences, Ahvaz, Iran
5 - Food and Drugs Affairs of Ahvaz Jundishapur University of Medical Sciences, Ahvaz, Iran
کلید واژه: Physicochemical properties, Xanthan gum, Sponge cake, Guar gum, Oleogels,
چکیده مقاله :
The present study aims at using xanthan and guar gums in producing and application of oleogels (Ole-XG) as an alternative to shortenings on quality properties of sponge cake (Oleo-cake). The influence of xanthan and guar gums on rheological, thermal and structure properties and fatty acid compositions of the oleogels was evaluated. Results showed that application of xanthan and guar gums oleogels has no effect on the amount and type of fatty acids. The use of guar gum in xanthan solution with short spacing peaks can show higher intensity than with long spacing peaks. They enhanced both elastic modulus and viscous moduli and the strain-thinning behaviour for storage modulus in high strain amplitudes. As substitution of shortening with oleogels is increased to 75%, firmness, cohesiveness and chewiness of cake samples were decreased. Results showed that substituting the shortening with oleogels increased L* and a* colour values. Sensory analysis showed that substituting the shortening with oleogels up to 75% increased overall acceptability of cakes.
1. Kim J.Y., Lim J., Lee J., Hwang H.S., Lee S., 2017. Utilization of oleogels as a replacement for solid fat in aerated baked goods: Physicochemical, rheological, and tomographic characterization. Journal of Food Science. 82(2), 445-452.
2. Lim J., Hwang H.S., Lee S., 2017. Oil-structuring characterization of natural waxes in canola oil oleogels: Rheological, thermal, and oxidative properties. Applied Biological Chemistry. 60(1), 17-22.
3. Pehlivanoğlu H., Demirci M., Toker O.S., Konar N., Karasu S., Sagdic O., 2018. Oleogels, a promising structured oil for decreasing saturated fatty acid concentrations: Production and food-based applications. Critical reviews in Food science and Nutrition. 58(8), 1330-1341.
4. Zulim Botega D.C., Marangoni A.G., Smith A.K., Goff H.D., 2013. The potential application of rice bran wax oleogel to replace solid fat and enhance unsaturated fat content in ice cream. Journal of Food Science. 78(9), 1334-1339.
5. Singh A., Auzanneau F.I., Rogers M., 2017. Advances in edible oleogel technologies–A decade in review. Food Research International. 97, 307-317.
6. Mert B., Demirkesen I., 2016. Evaluation of highly unsaturated oleogels as shortening replacer in a short dough product. LWT-Food Science and Technology. 68, 477-484.
7. Mert B., Demirkesen I., 2016. Reducing saturated fat with oleogel/shortening blends in a baked product. Food Chemistry. 199, 809-816.
8. Martins A.J., Vicente A.A., Cunha R.L., Cerqueira M.A., 2018. Edible oleogels: an opportunity for fat replacement in foods. Food & Function. 9(2), 758-773.
9. Patel A.R., Cludts N., Sintang M.D.B., Lesaffer A., Dewettinck K., 2014. Edible oleogels based on water soluble food polymers: preparation, characterization and potential application. Food & Function. 5(11), 2833-2841.
10. Nussinovitch A., 1997. Hydrocolloid applications: gum technology in the food and other industries., Springer science & business media.
11. Hager A.S., Arendt E.K., 2013. Influence of hydroxypropylmethylcellulose (HPMC), xanthan gum and their combination on loaf specific volume, crumb hardness and crumb grain characteristics of gluten-free breads based on rice, maize, teff and buckwheat. Food Hydrocolloids. 32(1), 195-203.
12. Casas J.A., Mohedano A.F., García‐Ochoa F., 2000. Viscosity of guar gum and xanthan/guar gum mixture solutions. Journal of the Science of Food and Agriculture. 80(12), 1722-1727.
13. Doublier J., Launay B., 1981. Rheology of galactomannan solutions: comparative study of guar gum and locust bean gum. Journal of Texture Studies. 12(2), 151-172.
14. Schorsch C., Garnier C., Doublier J.L., 1997. Viscoelastic properties of xanthangalactomannan mixtures: comparison of guar gum with locust bean gum. Carbohydrate polymers. 34(3), 165-175.
15. Beikzadeh M., Peighambardoust S., Beikzadeh S., Homayouni-Rad A., 2017. Effect of inulin, oligofructose and oligofructose-enriched inulin on physicochemical, staling, and sensory properties of prebiotic cake. Journal of Agricultural Science and Technology. 19, 1241-1252.
16. Espert M., Constantinescu L., Sanz T., Salvador A., 2019. Effect of xanthan gum on palm oil in vitro digestion. Application in starch-based filling creams. Food Hydrocolloids. 86, 87-94.
17. Hashemi Gahruie H., Moosavi Nasab M., Ziaee E., 2015. Application of response surface methodology for xanthan gum and biomass production using Xanthomonas campestris. Journal of Chemical Health Risks. 5(3), 167-177.
18. Martínez-Ruvalcaba A., Chornet E., Rodrigue D., 2007. Viscoelastic properties of dispersed chitosan/xanthan hydrogels. Carbohydrate Polymers. 67(4), 586-595.
19. Sagiri S., Singh V.K., Pal K., Banerjee I., Basak P., 2015. Stearic acid based oleogels: a study on the molecular, thermal and mechanical properties. Materials Science and Engineering: C. 48, 688-699.
20. Öğütcü M., Yılmaz E., 2015. Characterization of hazelnut oil oleogels prepared with sunflower and carnauba waxes. International Journal of Food Properties. 18(8), 1741-1755.
21. Zetzl A.K., Gravelle A.J., Kurylowicz M., Dutcher J., Barbut S., Marangoni A.G., 2014. Microstructure of ethylcellulose oleogels and its relationship to mechanical properties. Food Structure. 2(1-2), 27-40.
22. Salehi F., Kashaninejad M., Akbari E., Sobhani S.M., Asadi F., 2016. Potential of sponge cake making using infrared–hot air dried carrot. Journal of Texture Studies. 47(1), 34-39.
23. Ratnayake W.N., Hansen S.L., Kennedy M.P., 2006. Evaluation of the CP-Sil 88 and SP-2560 GC columns used in the recently approved AOCS official method Ce 1h-05: Determination of cis-, trans-, saturated, monounsaturated, and polyunsaturated fatty acids in vegetable or non-ruminant animal oils and fats by capillary GLC method. Journal of the American oil chemists' society. 83(6), 475-488.
24. Rodríguez‐García J., Puig A., Salvador A., Hernando I., 2012. Optimization of a sponge cake formulation with inulin as fat replacer: structure, physicochemical, and sensory properties. Journal of Food Science. 77(2), 189-197.
25. Nourmohammadi E., Peighambardoust S.H., 2015. A comprehensive study on the effect of maltitol and oligofructose as alternative sweeteners in sponge cakes. InternationalJournal of Food Engineering. 11(4), 557-562.
26. Beikzadeh S., Peighardoust S., Beikzadeh M., Javar-Abadi M.A., Homayouni-Rad A., 2016. Effect of psyllium husk on physical, nutritional, sensory and staling properties of dietary prebiotic sponge cake. Czech Journal of Food Sciences. 34(6), 534-540.
27. Nourmohammadi E., Peighambardoust S.H., 2016. New concept in reduced‐calorie sponge cake production by xylitol and oligofructose. Journal of Food Quality. 39(6), 627-633.
28. Elia M., 2011. A procedure for sensory evaluation of bread: protocol developed by a trained panel. Journal of Sensory Studies. 26(4), 269-277.
29. Turabi E., Sumnu G., Sahin S., 2008. Optimization of baking of rice cakes in infrared–microwave combination oven by response surface methodology. Food and Bioprocess Technology. 1(1), 64-73.
30. Sánchez R., Franco J., Delgado M., Valencia C., Gallegos C., 2011. Thermal and mechanical characterization of cellulosic derivatives-based oleogels potentially applicable as bio-lubricating greases: Influence of ethyl cellulose molecular weight. Carbohydrate polymers. 83(1), 151-158.
31. Patel A.R., Rajarethinem P.S., Grędowska A., Turhan O., Lesaffer A., De Vos W.H., Van de Walle D., Dewettinck K., 2014. Edible applications of shellac oleogels: spreads, chocolate paste and cakes. Food & Function. 5(4), 645-652.
32. Gallego R., Arteaga J., Valencia C., Franco J., 2013. Rheology and thermal degradation of isocyanate-functionalized methyl cellulose-based oleogels. Carbohydrate Polymers. 98(1), 152-160.
33. Jang A., Bae W., Hwang H.S., Lee H.G., Lee S., 2015. Evaluation of canola oil oleogels with candelilla wax as an alternative to shortening in baked goods. Food Chemistry. 187, 525-529.
34. Yılmaz E., Öğütcü M., 2015. The texture, sensory properties and stability of cookies prepared with wax oleogels. Food & Function. 6(4), 1194-1204.
35. Zambrano F., Despinoy P., Ormenese R., Faria E., 2004. The use of guar and xanthan gums in the production of ‘light’low fat cakes. International Journal of Food Science & Technology. 39(9), 959-966.
36. Pușcaș A., Mureșan V., Socaciu C., Muste S., 2020. Oleogels in Food: A Review of Current and Potential Applications. Foods. 9(1), 1-27.
