Physical and Microstructural Characteristics of Kefir Made of Milk and Colostrum
Triana Setyawardani(1*), Juni Sumarmono(2), Kusuma Widayaka(3)
(1) Faculty of Animal Science, Jenderal Soedirman University, Purwokerto, 53123, Indonesia
(2) Faculty of Animal Science, Jenderal Soedirman University, Purwokerto, 53123, Indonesia
(3) Faculty of Animal Science, Jenderal Soedirman University, Purwokerto, 53123, Indonesia
(*) Corresponding Author
Abstract
This research set out to compare the physical and microstructural characteristics of kefir made of milk, colostrum, and milk-colostrum mixes at various proportions. Kefir was made by adding kefir grains to 100% milk (P0), 80% milk + 20% colostrum (P1), 60% milk + 40% colostrum (P3), 40% milk + 60% colostrum (P4), 80% milk + 20% colostrum (P5), and 100% colostrum (P6). Fermentation was allowed under room temperature for 24 hours. The characteristics observed were color values, viscosity, pH, water holding capacity (WHC), syneresis, and microstructure. The result showed that the color of kefir (L* value, lightness); (b* value, yellow-blue), (a*, red-green), and whiteness index (WI) was significantly affected by raw materials. The viscosity of kefir was also affected by the raw materials (p<0.05), in which the kefir made from a mix of 80% milk and 20% colostrum showed the highest viscosity (1524.20 m.Pa.S). However, other characteristics such as pH, WHC, and syneresis were not significantly affected by raw materials. The microstructure of kefir made from 20 to 40% colostrum showed a string and compact protein tissues, while that made from 80 to 100% colostrum showed a clumping gel and concentration dominated by protein and fat tissues. This study demonstrated that milk kefir produced from milk-colostrum mixes posses a yellowish color (b*), low whitenes index, negative a* value, low lightness, whereas kefir made from 100% colostrum showed slightly greenish with low lightness level. Kefir with highest viscosity was produced from combined 80% milk and 20% colostrum. The microstructure of kefir produced from mixes with 40% and 60% colostrum showed a strong, tight, and compact microstructure of protein tissues.
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Amatayakul, T., A. Halmos, F. Sherkat, and N. Shah. 2006. Physical characteristics of yoghurts made using exopolysaccharide-producing starter cultures and varying casein to whey protein ratios. Int. Dairy J. 16: 40-51.
Bensmira, M. and B. Jiang. 2012. Effect of some operating variables on the microstructure and physical properties of a novel Kefir formulation. J. Food. Eng. 108: 579-584.
Cais-Sokolińska, D., J. Wójtowski, and J. Pikul. 2016. Rheological, texture and sensory properties of kefir from mare’s milk and its mixtures with goat and sheep milk. Mljekarstvo: časopis za unaprjeđenje proizvodnje i prerade mlijeka 66: 272-281.
Calderón, F., B. Chauveau-Duriot, P. Pradel, B. Martin, B. Graulet, M. Doreau, and P. Nozière. 2007. Variations in carotenoids, vitamins A and E, and color in cow's plasma and milk following a shift from hay diet to diets containing increasing levels of carotenoids and vitamin E. J.Dairy Sci. 90: 5651-5664.
Corona, O., W. Randazzo, A. Miceli, R. Guarcello, N. Francesca, H. Erten, G. Moschetti, and L. Settanni. 2016. Characterization of kefir-like beverages produced from vegetable juices. LWT-Food Sci.Technol. 66: 572-581.
Delgadillo, J. O. V., M. d. J. L. Lara, C. K. L. Santillan, and C. Bulbarela. 2017. Physicochemical and Rheological Characterization of an Acidic Milk Product: Kefir Concentration Effect. J. Food Sci. Eng. 7: 86-92.
Dimitreli, G., D. Petridis, P. Akakiadou, and S. Chrysalidou. 2014. Effect of protein supplementation, fat globule size and storage time on the rheological and sensory properties of buffalo milk stirred yogurt. J. Food Res. 3: 31.
Dinkçi, N., H. Kesenkaş, F. Korel, and Ö. Kınık. 2015. An innovative approach: cow/oat milk based kefir.
El-Salam, M. H. A., and S. El-Shibiny. 2011. A comprehensive review on the composition and properties of buffalo milk. Dairy Sci.Technol. 91: 663.
Goldstein, I., D. E. Newbury, P. Echlin, D. C. Joy, C. Fiori, and E. Lifshin. 1992. Electron Microscopy and X-Ray Microanalysis. Text for Biologist, Material Scientists and Geologists. Plenum Press, New York.
Gomes, J. J. L., A. M. Duarte, A. S. M. Batista, R. M. F. de Figueiredo, E. P. de Sousa, E. L. de Souza, and R. d. C. R. do Egypto. 2013a. Physicochemical and sensory properties of fermented dairy beverages made with goat's milk, cow's milk and a mixture of the two milks. LWT-Food Sci.Technol. 54: 18-24.
Gomes, J. J. L., A. M. Duarte, A. S. M. Batista, R. M. F. de Figueiredo, E. P. de Sousa, E. L. de Souza, and R. d. C. R. d. E. Queiroga. 2013b. Physicochemical and sensory properties of fermented dairy beverages made with goat's milk, cow's milk and a mixture of the two milks. LWT - Food Science and Technology 54: 18-24.
Górová, R., E. Pavlíková, J. Blaško, B. Meľuchová, R. Kubinec, M. Margetín, and L. Soják. 2011. Temporal variations in fatty acid composition of individual ewes during first colostrum day. Small Rum. Res. 95: 104-112.
Gul, O., I. Atalar, M. Mortas, and M. Dervisoglu. 2018. Rheological, textural, colour and sensorial properties of kefir produced with buffalo milk using kefir grains and starter culture: A comparison with cows’ milk kefir. Int. J. Dairy Technol. 71: 73-80.
Harte, F., Luedecke, B. Sawanson, and G. V. Barbosa-Canovas. 2003. Low-Fat Yogurt Made from Milk Subjected to Combinations of High Hydrostatic Pressure and Thermal Processing. J. Dairy Sci. 66: 1074-1082.
Kasenkas, H. 2011. Antioxidant properties of kefir produced from different cow and soy milk mixtures. J. Agric. Sci. 17: 253-259.
Nguyen, H. T. H., L. Ong, C. Lefèvre, S. E. Kentish, and S. L. Gras. 2014. The microstructure and physicochemical properties of probiotic buffalo yoghurt during fermentation and storage: a comparison with bovine yoghurt. Food Bioprocess Technol. 7: 937-953.
Nurliyani, N. 2017. Properties of Goat Milk Kefir Supplemented with Glucomannan from Porang (Amorphophallus oncophyllus) Tuber. In: International Seminar on Tropical Animal Production (ISTAP). p 419-424.
Öztürk, B. and M. Öner. 1999. Production and evaluation of yogurt with concentrated grape juice. J. Food Sci. 64: 530-532.
Peng, X. and S. Guo. 2015. Texture characteristics of soymilk gels formed by lactic fermentation: A comparison of soymilk prepared by blanching soybeans under different temperatures. Food Hidrocoll. 43: 58-65.
Pereira, R., H. Singh, P. Munro, and M. Luckman. 2003. Sensory and instrumental textural characteristics of acid milk gels. Int. Dairy J. 13: 655-667.
Schkoda, P., A. Hechler, and J. Hinrichs. 2001. Improved texture of stirred fermented milk by integrating fat globules into the gel structure. Milchwissenschaft 56: 85-89.
Setyawardani, T., A. H. Rahardjo, M. Sulistyowati, and S. Wasito. 2014. Physiochemical and organoleptic features of goat milk kefir made of different kefir grain concentration on controlled fermentation. Anim. Prod. 16: 48-54.
Setyawardani, T. and J. Sumarmono. 2015. Chemical and microbiological characteristics of goat milk kefir during storage under different temperatures. J. Indonesian Trop. Anim. Agric. 40: 183-187.
Supavititpatana, P., T. I. Wirjantoro, and P. Raviyan. 2009. Effect of sodium caseinate and whey protein isolate fortification on the physical properties and microstructure of corn milk yogurt. Chiang Mai University (CMU) J. Natural Sci. 8: 247-265.
Vareltzis, P., K. Adamopoulos, E. Stavrakakis, A. Stefanakis, and A. M. Goula. 2016. Approaches to minimise yoghurt syneresis in simulated tzatziki sauce preparation. Int. J. Dairy Technol. 69: 191-199.
Walstra, P., J. T. M. Wouters, and T. J. Geurts. 2006. Dairy Science and Technology. Taylor and Francis Group, Florida, USA.
Wang, H., C. Wang, M. Wang, and M. Guo. 2017. Chemical, physiochemical, and microstructural properties, and probiotic survivability of fermented goat milk using polymerized whey protein and starter culture Kefir Mild 01. J. Food Sci. 82: 2650-2658.
Yoo, S.-H., K.-S. Seong, and S.-S. Yoon. 2013. Physicochemical properties of kefir manufactured by a two-step fermentation. Korean J. Food Sci. Anim. Res. 33: 744-751.
Yovanoudi, M., G. Dimitreli, S. Raphaelides, and K. Antoniou. 2013. Flow behavior studies of kefir type systems. J. Food. Eng. 118: 41-48.
DOI: https://doi.org/10.21059/buletinpeternak.v44i1.49130
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