A Lactose-Free Yogurt Using Membrane Systems and Modified Milk Protein Concentrate: Production and Characterization
Authors: Shahram Naghizadeh Raeisi, Ali Alghooneh
Abstract:
Using membrane technology and modification of milk protein structural properties, a lactose free yogurt was developed. The functional, textural and structural properties of the sample were evaluated and compared with the commercial ones. Results showed that the modification of protein in high fat set yogurt resulted in 11.55%, 18%, 20.21% and 7.08% higher hardness, consistency, water holding capacity, and shininess values compared with the control one. Furthermore, these indices of modified low fat set yogurt were 21.40%, 25.41%, 28.15% & 10.58% higher than the control one, which could be related to the gel network microstructural properties in yogurt formulated with modified protein. In this way, in comparison with the control one, the index of linkage strength (A), the number of linkages (z), and time scale of linkages (λrel) of the high fat modified yogurt were 22.10%, 50.68%, 21.82% higher than the control one; whereas, the average linear distance between two adjacent crosslinks (ξ), was 16.77% lower than the control one. For low fat modified yogurt, A, z, λrel, and ξ indices were 34.30%, 61.70% and 42.60% higher and 19.20% lower than the control one, respectively. The shelf life of modified yogurt was extended to 10 weeks in the refrigerator, while, the control set yogurt had a 3 weeks shelf life. The acidity of high fat and low fat modified yogurts increased from 76 to 84 and 72 to 80 Dornic degrees during 10 weeks of storage, respectively, whereas for control high fat and low fat yogurts they increased from 82 to 122 and 77 to 112 Dornic degrees, respectively. This behavior could be due to the elimination of microorganism’s source of energy in modified yogurt. Furthermore, the calories of high fat and low fat lactose free yogurts were 25% and 40% lower than their control samples, respectively. Generally, results showed that the lactose free yogurt with modified protein, despite of 1% lower protein content than the control one, showed better functional properties, nutritional properties, network parameters, and shelf stability, which could be promising in the set yogurt industry.
Keywords: Lactose free, low calorie, network properties, protein modification.
Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 272References:
[1] Da Silva, A.T., de Lima, J.J., Reis, P., Passos, M., Baumgartner, C.G., Sereno, A.B., Krüger, C.C.H., Cândido, L.M.B. (2022). Application of Lactose-Free Whey Protein to Greek Yogurts: Potential Health Benefits and Impact on Rheological Aspects and Sensory Attributes. Foods, 11, 3861.
[2] Lesme, H., Cardinal, M., Famelart, M., Bouhallab, S., & Prost, C. (2020). Yogurts enriched with milk proteins: Texture properties, aroma release and sensory perception. Trends in Food Science and Technology, 98, 140–149.
[3] Amatayakul, T., Sherkat, F., Shah, N.P. (2006). Syneresis in set yogurt as affected by EPS starter cultures and levels of solids, International Journal of Dairy Technology, 59(3), 216-221.
[4] Fang, T., & Guo, M. (2019). Physicochemical, texture properties, and microstructure of yogurt using polymerized whey protein directly prepared from cheese whey as a thickening agent. Journal of Dairy Science, 102(9), 7884–7894.
[5] AOAC. (2005). Official methods of analysis. Arlington: Association of Official Analytical Chemists.
[6] Cheng J, Xie S, Yin Y, Feng X, Wang Sh, Guo M, Ni Ch. (2016). Physiochemical, texture properties, and the microstructure of set yogurt using whey protein–sodium tripolyphosphate aggregates as thickening agents. Journal of the Science of Food and Agriculture, 97(9), 2819-2825.
[7] Alghooneh, A., Razavi, S. M. A., & Kasapis, S. (2019). Classification of hydrocolloids based on small amplitude oscillatory shear, large amplitude oscillatory shear, and textural properties. Journal of Texture Studies, 50(6), 520–538.
[8] Alghooneh, A., Razavi, S. M. A., & Kasapis, S. (2018). Hydrocolloid clustering based on their rheological properties. Journal of Texture Studies, 49(6), 619–638
[9] Razavi, S. M. A., & Alghooneh, A. (2020). Understanding the physics of hydrocolloids interaction using rheological, thermodynamic and functional properties: A case study on xanthan gum-cress seed gum blend. International Journal of Biological Macromolecules.
[10] Alghooneh, A., Razavi, S. M. A., & Behrouzian, F. (2019). Biopolymers interaction elaborating using viscoelastic relaxation spectra, network parameters, and thermodynamic properties, J Texture Stud. 2019;50:493–507
[11] Vollmer, A. H., Kieferle, I., Youssef, N. L., & Kulozik, U. (2021). Mechanisms of structure formation underlying the creaming reaction in a processed cheese model system as revealed by light and transmission electron microscopy. Journal of Dairy Science, 104(9), 9505-9520.
[12] Razavi, S. M. A., & Alghooneh, A. (2020). Understanding the physics of hydrocolloids interaction using rheological, thermodynamic and functional properties: A case study on xanthan gum-cress seed gum blend. International Journal of Biological Macromolecules, 151, 1139–1153.
[13] Li, H., Yang, C. Y., Feng, D., Ren, F., Li, Y., Mu, Z., & Wang, P. (2018). The Use of Trisodium Citrate to Improve the Textural Properties of Acid-Induced, Transglutaminase-Treated Micellar Casein Gels. Molecules, 23(7), 1632.
[14] Lesme, H., Cardinal, M., Loisel, C., Famelart, M., Bouhallab, S., & Prost, C. (2019). Controlled whey protein aggregates to modulate the texture of fat-free set-type yogurts. International Dairy Journal, 92, 28–36.
[15] Hossain, M. S., Keidel, J., Hensel, O., & Diakité, M. (2020). The impact of extruded microparticulated whey proteins in reduced-fat, plain-type stirred yogurt: Characterization of physicochemical and sensory properties. Lebensmittel-Wissenschaft & Technologie, 134, 109976
[16] Guo, Q., Cui, S. W., Wang, Q., Goff, H. D., & Smith, A. (2009). Microstructure and rheological properties of 548 psyllium polysaccharide gel. Food Hydrocolloid, 23, 1542–1547.
[17] Hyun, K., Kim, S. H., Ahn, K. H., & Lee, S. J. (2002). Large amplitude oscillatory shear as a way to classify the complex fluids. Journal of NonNewtonian Fluid Mechanics, 107, 51–65.
[18] Sun, A., & Gunasekaran, S. (2009). Yield stress in foods: Measurements and applications. International Journal of Food Properties, 12, 70–101.
[19] H.G. Sim, K.H. Ahn, S.J. Lee, (2003). Large amplitude oscillatory shear behavior of complex fluids investigated by a network model: a guideline for classification, J. Nonnewton. Fluid Mech. 112, 237–250
[20] Alghooneh, A., Razavi, S. M. A., & Behrouzian, F. (2017). Rheological characterization of hydrocolloids interaction: A case study on sage seed gum-xanthan blends. Food Hydrocolloids, 66, 206–215
[21] Sun, A. and Gunasekaran, S. 2009. Yield stress in foods: measurements and applications. Int. J. Food Prop. 12(1), 70-101.
[22] Razavi, S. M. A., Alghooneh, A., & Behrouzian, F. (2017). Thermo-rheology and thermodynamic analysis of binary biopolymer blend: A case study on sage seed gum-xanthan gum blends. Food Hydrocolloids, 77, 307–321.