Hostname: page-component-586b7cd67f-2brh9 Total loading time: 0 Render date: 2024-11-24T03:30:39.178Z Has data issue: false hasContentIssue false

Effect of dairy powders fortification on yogurt textural and sensorial properties: a review

Published online by Cambridge University Press:  04 November 2013

Marie Celeste Karam
Affiliation:
Université de Lorraine, LIBio (Laboratoire d'Ingénierie des Biomolécules), 2 avenue de la Forêt de Haye, BP 172, 54505 Vandoeuvre-lès-Nancy, France
Claire Gaiani*
Affiliation:
Université de Lorraine, LIBio (Laboratoire d'Ingénierie des Biomolécules), 2 avenue de la Forêt de Haye, BP 172, 54505 Vandoeuvre-lès-Nancy, France
Chadi Hosri
Affiliation:
Faculty of Agricultural Sciences, Department of Agricultural Engineering, Holy Spirit University of Kaslik, P.O. Box 446 – Jounieh, Lebanon
Jennifer Burgain
Affiliation:
Université de Lorraine, LIBio (Laboratoire d'Ingénierie des Biomolécules), 2 avenue de la Forêt de Haye, BP 172, 54505 Vandoeuvre-lès-Nancy, France
Joël Scher
Affiliation:
Université de Lorraine, LIBio (Laboratoire d'Ingénierie des Biomolécules), 2 avenue de la Forêt de Haye, BP 172, 54505 Vandoeuvre-lès-Nancy, France
*
*For correspondence; e-mail: [email protected]

Abstract

Yogurts are important dairy products that have known a rapid market growth over the past few decades. Industrial yogurt manufacture involves different processing steps. Among them, protein fortification of the milk base is elemental. It greatly enhances yogurt nutritional and functional properties and prevents syneresis, an undesirable yogurt textural defect. Protein enrichment can be achieved by either concentration process (evaporation under vacuum and membrane processing: reverse osmosis and/or ultrafiltration) or by addition of dairy ingredients. Traditionally, skim milk powder (SMP) is used to enrich the milk base before fermentation. However, increased quality and availability of other dairy ingredients such as milk protein isolates (MPI), milk protein concentrates (MPC) whey protein isolates (WPI) and concentrates (WPC), micellar casein (MC) and caseinates have promoted their use as alternatives to SMP. Substituting different dry ingredients for skim milk powder in yogurt making affects the yogurt mix protein composition and subsequent textural and sensorial properties. This review focuses on various type of milk protein used for fortification purposes and their influence on these properties.

Type
Research Article
Copyright
Copyright © Proprietors of Journal of Dairy Research 2013 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Akalain, AS, Unal, G, Dinkci, N & Hayaloglu, AA 2008 Microstructural, textural, and sensory characteristics of probiotic yogurts fortified with sodium calcium caseinate or whey protein concentrate. Journal of Dairy Science 95 36173628Google Scholar
Amatayakul, T, Sherkat, F & Shah, NP 2006 Physical characteristics of set yoghurt made with altered casein to whey protein ratios and EPS-producing starter cultures at 9 and 14% total solids. Food Hydrocolloids 20 314324CrossRefGoogle Scholar
Ares, G, Gonçalvez, D, Pérez, C, Reolon, G, Segura, N, Lema, P & Gambaro, A 2007 Influence of gelatin and starch on the instrumental and sensory texture of stirred yogurt. International Journal of Dairy Technology 60 263269CrossRefGoogle Scholar
Augustin, MA, Cheng, LJ, Glagovskaia, O, Clarke, PT & Lawrence, A 2003 Use of blends of skim milk and sweet whey protein concentrates in reconstituted yogurt. Australian Journal of Dairy Technology 58 3035Google Scholar
Aziznia, S, Khosrowshahi, A, Madadlou, A & Rahimi, J 2008 Whey protein concentrate and Gum tragacanth as fat replacers in Nonfat Yogurt: chemical, physical, and microstructural properties. Journal of Dairy Science 91 25452552Google Scholar
Berton-Carabin, C, Elias, RJ & Coupland, JN 2013 Reactivity of a model lipophilic ingredient in surfactant-stabilized emulsions: effect of droplet surface charge and ingredient location. Colloids and Sufaces A: Physicochemical and Engineering Aspects 418 6875Google Scholar
Bhullar, YS, Uddin, MA & Shah, NP 2002 Effects of ingredients supplementation on textural characteristics and microstructure of yoghurt. Milchwissenschaft 57 329332Google Scholar
Birollo, GA, Reinheimer, JA & Vinderola, GC 2000 Viability of lactic acid microflora in different types of yoghurt. Food Research International 33 799805Google Scholar
Boudier, JF & Schuck, P 2010 Les laits en poudres. Science des Aliments 29 5160CrossRefGoogle Scholar
Chandan, RC & Shahani, KM 1995 Other fermented dairy products. Biotechnology: Enzymes, Biomass, Food and Feed 9 385418Google Scholar
Chen, H 2002 Formation and properties of casein films and coatings. In Proteins-based Films and Coatings, pp. 181211 (Ed. Gennadios, A). New York: CRC PressGoogle Scholar
Considine, T, Noisuwan, A, Hemar, Y, Wilkinson, B, Bronlund, J & Kasapis, S 2011 Rheological investigations of the interactions between starch and milk proteins in model dairy systems: a review. Food Hydrocolloids 25 20082017Google Scholar
Corredig, M, Sharafbafi, N & Kristo, E 2011 Polysaccharide-protein interactions in dairy matrices, control and design of structures. Food Hydrocolloids 25 18331841Google Scholar
Damin, MR, Alcântara, MR, Nunes, AP & Oliveira, MN 2009 Effects of milk supplementation with skim milk powder, whey protein concentrate and sodium caseinate on acidification kinetics, rheological properties and structure of nonfat stirred yogurt. Food Science and Technology 42 17441750Google Scholar
Dave, RI & Shah, NP 1998 The influence of ingredient supplementation on the textural characteristics of yogurt. Australien Journal of Dairy Technonolgy 53 180184Google Scholar
De Brabandere, AG & De Baerdemaeker, JG 1999 Effects of process conditions on the pH development during yogurt fermentation. Journal of Food Engineering 41 221227CrossRefGoogle Scholar
Everett, DW & McLeod, RE 2005 Interactions of polysaccharide stabilisers with casein aggregates in stirred skim-milk yoghurt. International Dairy Journal 15 11751183Google Scholar
Fabra, MJ, Talens, P & Chiralt, A 2010 Influence of calcium on tensile, optical and water vapour permeability properties of sodium caseinate edible films. Journal of Food Engineering 96 356364CrossRefGoogle Scholar
Gastaldi, E, Lagaude, A, Marchesseau, S & Torodo De la Fuente, B 1997 Acid milk gel formation as affected by total solids content. Journal of Food Science 62 671687Google Scholar
González-Martínez, C, Becerra, M, Cháfer, M, Albors, A, Carot, JM & Chiralt, A 2002 Influence of substituting milk powder for whey powder on yoghurt quality. Trends in Food Science and Technology 13 334340Google Scholar
Guichard, E 2002 Interactions between flavour compounds and food ingredients and their influence on flavor perception. Food Reviews International 18 4970Google Scholar
Guzmán-González, M, Morais, F, Ramos, M & Amigo, L 1999 Influence of skimmed milk concentrate replacement by dry dairy products in a low fat set-type yoghurt model system. I: use of whey protein concentrates, milk protein concentrates and skimmed milk powder. Journal of the Science of Food and Agriculture 79 11171122Google Scholar
Guzmán-González, M, Morais, F & Amigo, L 2000 Influence of skimmed milk concentrate replacement by dry dairy products in a low-fat set-type yoghurt model system. Use of caseinates, co-precipitate and blended dairy powders. Journal of the Science of Food and Agriculture 80 433438Google Scholar
Ha, E & Zemel, MB 2003 Functional properties of whey, whey components, and essential amino acids: mechanisms underlying health benefits for active people (review). Journal of Nutritional Biochemistry 14 251258Google Scholar
Haque, ZU & JI, T 2003 Cheddar whey processing and source: II. Effects on non-fat ice cream and yogurt. International Journal of Food Science and Technology 38 463473Google Scholar
Herrero, AN & Requena, T 2006 The effect of supplementing goats milk with whey protein concentrate on textural properties of set-type yogurt. International Journal of Food Science and Technology 41 8792CrossRefGoogle Scholar
Hussain, R, Gaiani, C & Scher, J 2012 From high milk protein powders to the rehydrated dispersions in variable ionic environments: a review. Journal of Food Engineering 113 486503Google Scholar
Isleten, M & Karagul-Yuceer, Y 2006 Effects of dried dairy ingredients on physical and sensory properties of Nonfat Yogurt. Journal of Dairy Science 89 28652872Google Scholar
Isleten, M & Karagul-Yuceer, Y 2008 Effects of functional dairy based proteins on nonfat yogurt quality. Journal of Food Quality 31 265280Google Scholar
Jaros, D, Rohm, H 2003 The Rheology and Textural Properties of Yoghurt. Cambridge, UK: CRC PressWoodheadGoogle Scholar
Khwaldia, K, Banon, S, Desobry, S & Hardy, J 2004 Mechanical and barrier properties of sodium caseinate-anhydrous milk fat edible films. International Journal of Food Science and Technology 39 403411Google Scholar
Kristo, E, Biliaderis, CG & Tzanetakis, N 2003 Modelling of the acidification process and rheological properties of milk fermented with a yogurt starter culture using response surface methodology. Food Chemistry 83 437446Google Scholar
Krzeminski, A, Groayhable, K & Hinrichs, Jr 2011 Structural properties of stirred yoghurt as influenced by whey proteins. Food Science and Technology 44 21342140Google Scholar
Lakemonda Catriona, MM & van Vliet, T 2007 Acid skim milk gels: the gelation process as affected by preheating pH. International Dairy Journal 18 574584CrossRefGoogle Scholar
Lee, WJ & Lucey, JA 2010 Formation and physical properties of Yogurt. Asian – Australasian Journal of Animal Sciences 23 11271136Google Scholar
Lucas, A, Sodini, I, Monnet, C, Jolivet, P & Corrieu, G 2004 Probiotic cell counts and acidification in fermented milks supplemented with milk protein hydrolysates. International Dairy Journal 14 4753CrossRefGoogle Scholar
Lucey, JA 2004 Formation, structural properties and rheology of acid-coagulated milk gels. In Cheese: chemestry, Physics and Microbiology, Vol. 1, 3rd edition, pp. 105122. London: Elsevier Academic PressGoogle Scholar
Lucey, JA & Singh, H 1998 Formation and physical properties of acid milk gels: a review. Food Research International 30 529542Google Scholar
Lucey, JA, Teo, CT, Munro, PA & Singh, H 1997 Rheological properties at small (dynamic) and large (yield) deformations of acid gels made from heated milk. Journal of Dairy Research 64 591600Google Scholar
Lucey, JA, Tamehana, M, Singh, H & Muuro, PA 1998 a comparison of the formation, rheological properties and microstructure of acid skim milk gels made with a bacterial culture or glucono-δ-lactone. Food Research International 31 147155Google Scholar
Lucey, JA, Munro, PA & Singh, H 1999 Effects of heat treatment and whey protein addition on the rheological properties and structure of acid skim milk gels. International Dairy Journal 9 275279Google Scholar
Marafon, AP, Sumi, A, Granato, D, Alcantara, MR, Tamine, AY & Nogueira de Oliveira, M 2011 Effects of partially replacing skimmed milk powder with dairy ingredients on rheology, sensory profiling, and microstructure of probiotic stirred-type yogurt during cold storage. Journal of Dairy Science 94 53305340Google Scholar
Matumoto-Pintro, PT, Rabiey, L, Robitaille, G & Britten, M 2011 Use of modified whey protein in yoghurt formulations. International Dairy Journal 21 2126Google Scholar
McComas, KA & Gilliland, SE 2003 Growth of probiotic and traditional yogurt cultures in milk supplemented with whey protein hydrolysate. Journal of Food Science 68 20902095Google Scholar
Modler, HW & Kalab, M 1983 Microstructure of yogurt stabilized with milk proteins. Journal of Dairy Science 66 430437Google Scholar
Oldfield, DJ, Singh, H, Taylor, MW & Pearce, KN 2000 Heat-induced interactions of ß-lactoglobulin and α-lactalbumin with the casein micelle in pH-adjusted skim milk. International Dairy Journal 10 509518Google Scholar
Oliveira, MN, Sodini, I, Remeuf, F & Corrieu, G 2001 Effect of milk supplementation and culture composition on acidification, textural properties and microbiological stability of fermented milks containing probiotic bacteria. International Dairy Journal 11 935942Google Scholar
Oliveira, CAF, Fernandes, AM, Neto, OCC, Fonseca, LFL, Silva, EOT & Balian, SC 2002 Composition and sensory evaluation of whole yogurt produced from milk with different somatic cell counts. Australian Journal of Dairy Technology 57 192196Google Scholar
Ozen, AE & Kilic, M 2009 Improvement of physical properties of nonfat fermented milk drink by using whey protein concentrate. Journal of Texture Studies 40 288299Google Scholar
Ozer, BH, Robinson, RK, Grandison, AS & Bell, AE 1998 Gelation properties of milk concentrated by different techniques. International Dairy Journal 8 793799CrossRefGoogle Scholar
Patel, S 2011 Evaluating the Effect of Milk Protein Concentrates (MPC) Fortification on Rheological Properties of Nonfat Set Yogurt Using Vane Rheometry Vol. Master of Science: The Graduate School University of Wisconsin-StoutGoogle Scholar
Peng, Y, Serra, M, Horne, DS & Lucey, JA 2009 Effect of fortification with various types of milk proteins on the rheological properties and permeability of nonfat set yogurt. Journal of Food Science 74 666673Google Scholar
Penna, ALB, Baruffaldi, R & Oliveira, MN 1997 Optimization of yogurt production using demineralized whey. Journal of Food Science 62 846850Google Scholar
Pesic, MB, Barac, MB, Stanojevic, SP, Ristic, MN, Macej, OD & Vrvic, MM 2012 Heat induced casein-whey protein interactions at natural pH of milk: a comparison between caprine and bovine milk. Small Rumin Research 108 7786CrossRefGoogle Scholar
Puvanenthiran, A, Williams, RPW & Augustin, MA 2002 Structure and visco-elastic properties of set yoghurt with altered casein to whey protein ratios. International Dairy Journal 12 383391Google Scholar
Remeuf, F, Mohammed, S, Sodini, I & Tissier, JP 2003 Preliminary observations on the effects of milk fortification and heating on microstructure and physical properties of stirred yogurt. International Dairy Journal 13 773782Google Scholar
Rohm, H 1993 Influence of dry matter fortification on flow properties of yogurt. 1. Evaluation of flow curves. Milchwissenschaft 48 556560Google Scholar
Saint-Eve, A, Lévy, C, Martin, N & Souchon, I 2006 Influence of proteins on the perception of flavored stirred yogurts. Journal of Dairy Science 89 922933Google Scholar
Schkoda, P, Hechler, A & Hinrichs, J 2001 Influence of the protein content on structural characteristics of stirred fermented milk. Milchwissenschaft-Milk Science International 56 1922Google Scholar
Séverin, S and Wenshui, X 2005 Milk biologically active components as nutraceuticals: review. Critical Reviews in Food Science and Nutrition 45 645656Google Scholar
Shaker, RR, Abu-Jdayil, B, Jumah, RY & Ibrahim, SA 2001 Rheological properties of set yogurt during gelation process: II. Impact of incubation temperature. Milchwissenschaft 56 622625Google Scholar
Sodini, I & Béal, C 2003 Fabrication des yaourts et lait fermentés Technique de l'ingénieurGoogle Scholar
Sodini, I, Lucas, A, Oliveira, MN, Remeuf, F & Corrieu, G 2002 Effect of milk base and starter culture on acidification, texture, and probiotic cell counts in fermented milk processing. Journal of Dairy Science 85 24792488CrossRefGoogle ScholarPubMed
Sodini, I, Remeuf, F, Haddad, S & Corrieu, G 2004 The relative effect of milk base, starter, and process on yogurt texture: a review. Critical Reviews in Food Science and Nutrition 44 113137Google Scholar
Sodini, I, Montella, J & Tong, SP 2005 Physical properties of yogurt fortified with various commercial whey protein concentrates. Journal of the Science of Food and Agriculture 85 853859Google Scholar
Sodini, I, Morin, P, Olabi, A & Jiménez-Flores, R 2006 Compositional and functional properties of buttermilk: a comparison between sweet, sour, and whey buttermilk. Journal of Dairy Science 89 525536Google Scholar
Soukoulis, C, Panagiotidis, P, Koureli, R & Tzia, C 2007 Industrial yogurt manufacture: monitoring of fermentation process and improvement of final product quality. Journal of Dairy Science 90 26412654Google Scholar
Tamime, AY & Robinson, RK 2000 Yogurt Science and Technology. Washington, DC: CRC Press WoodheadGoogle Scholar
Tamime, AY & Robinson, RK 2007 Tamime and Robinson's Yoghurt Science and Technology, 3rd edition. Cambridge, UK: CRC PressWoodheadGoogle Scholar
Tamime, AY, Kalab, M & Davies, G 1984 Microstructure of set-style yoghurt manufactured from cow's milk fortified by various methods. Food Microstructure 3 8392Google Scholar
Thomopoulos, C, Tzia, C & Milkas, D 1993 Influence of processing of solids-fortified milk on coagulation time and quality properties of yogurt. Milchwissenschaft 48 426430Google Scholar
Vasbinder, AJ & de Kruif, CG 2003 Casein-whey protein interactions in heated milk: the influence of pH. International Dairy Journal 13 669677Google Scholar
Vasbinder, AJ, van Mil, PJJM, Bot, A & de Kruif, CG 2001 Acid induced gelation of heat treated milk studied by diffusing wave spectroscopy. Colloids and Surfaces B: Biointerfaces 21 245250Google Scholar
Vasbinder, AJ, van de Velde, F & de Kruif, CG 2004 Gelation of casein-whey protein mixtures. Journal of Dairy Science 87 11671176Google Scholar
Verman, AH & Sutherland, JP 2004 Quality of yogurt. Journal of Dairy Science 2 79Google Scholar
Walstra, P, Geurts, TJ, Noomem, A, Jellema, A & Van Boekel, MAJS 1999 Dairy Technology. New York: Marcel Dekker, Inc.Google Scholar
Zhao, QZ, Wang, JS, Zhao, MM, Jiang, YM & Chun, C 2006 Effect of casein hydrolysates on yogurt fermentation and texture properties during storage. Food Technol Biotechnol 44 429434Google Scholar