Utilization of Concentrated Buttermilk in Functional Processed Cheese Manufacturing and Studying Some of its Physicochemical Properties

Authors

  • Kifah, S. Doosh Department of Food Science, College of Agriculture, University of Baghdad, Baghdad, Iraq
  • Layla, A. Alhusyne Department of Food Science, College of Agriculture, University of Baghdad, Baghdad, Iraq
  • Baha, N. Almosawi Department of Food Science, College of Agriculture, University of Baghdad, Baghdad, Iraq

DOI:

https://doi.org/10.3923/pjn.2014.33.37

Keywords:

Concentrate buttermilk, organoleptic properties, processed cheese

Abstract

This investigation was carried out to study the effect of utilizing concentrate butter milk (CBM) which prepared by exposure of butter milk to heat treatment (100 ºC) for different time 15, 30 and 60 min, treatments T1, T2 and T3 respectively in preparing of processed cheese (PC), in addition to control treatment (C) which PC prepared without CBM. The CBM was added to base blend during cooking stage. The prepared samples were analyzed for chemical and sensory properties, at zero time and during storage period of 4 weeks at 6±1ºC. The results reveled that there were significant differences in the chemical composition for fat%, protein%, ash% and moisture% and no significant differences in sensory evaluation which conducted at zero time for color, taste and flavor, texture and bitterness between control and treated PC, while PC treatments stay more acceptable than control PC at all storage periods, especially cheese treatments T2 and T3. The obtained results showed that T2 and T3 treatments were quit low development of both peroxide value (POV) and acid degree value (ADV) of fat during some stages of storage, which have retained their validity according to the scale of accepted level of POV and ADV as even after 4 weeks of storage period. The microbiology study reveled that there was no growth of yeast, Mold and Coliform bacteria in treatments and control PC at all period of storage while the total count of viable bacteria was less in PC of treatments than control PC and all of were in the limited scale of acceptance. Finally using CBM in processed cheese makes this dairy product useful as a functional food.

References

Al-Husine, L., 2011. Manufacturing modified processed chesse and studing some of chemical and physical properties. Food Ind Nutr. Sci., 1: 235-241.

Ali, A. and A. Al-Dahhan, 2013. Effect of emulsifying salt percentages of processed cheese made from developed aushari cheese. Egyt. J. Appl. Sci., 28: 133-144.

Al-Khalayleh, N. and A. Taefor, 2011. A study of manufacturing processed cheese spread by using local cheese (White, Kashkawan, Karesh) as row materials. J. Damasks Univ. Agric. Sci., 27: 391-403.

AOAC., 2000. Official Methods of Analysis of the Association of Official Analytical Chemists. 17th Edn., Association of Official Analytical Chemists, Washington, DC., USA., Pages: 234.

Berger, W., H. Klostermeyer, K. Merkenich and G. Uhlmann, 1989. Processed Cheese Manufacture: A Joha Guide. BK Ladenburg, Ladenburg, Germany.

Cogan, T.M., 1980. Heat resistant lipases and proteinases and the quality of dairy product. Int. Dairy Fed. Doc., 118: 19-26.

Deeth, H.C. and C.H. Fitz-Gerald, 2006. Lipolytic Enzymes and Hydrolytic Rancidity. In: Advanced Dairy Chemistry Volume 2 Lipids, Fox, P.F. and P.L.H. McSweeney (Eds.). Springer, USA., ISBN-13: 9780387263649, pp: 481-556.

Elling, J.L., S.E. Duncan, T.W. Keenan, W.N. Eigel and J. Boling, 1996. Composition and microscopy of reformulated creams from reduced-cholesterol butteroil. J. Food Sci., 61: 48-53.

El-Sayed, M.M., A.A. Askar, L.F. Hamzawi, A.F. Fatma, A.G. Mohamed, S.M. El-Sayed and I.M. Hamed, 2010. Utilization of buttermilk concentrate in the manufacture of functional processed cheese spread. J. Am. Sci., 6: 876-882.

Fong, B.Y., C.S. Norris and A.K. MacGibbon, 2007. Protein and lipid composition of bovine milk-fat-globule membrane. Int. Dairy J., 17: 275-288.

Kapoor, R., L.E. Metzger, A.C. Biswas and K. Muthukummarappan, 2007. Effect of natural cheese characteristics on process cheese properties. J. Dairy Sci., 90: 1625-1634.

Ling, E.R., 2008. A Text Book of Dairy Chemistry. Vol. 2, Chapman and Hall Ltd., London, UK.

Mistry, V., 2001. Low fat cheese technology. Int. Dairy J., 11: 413-422.

Morin, P., M. Britten, R. Jimenez-Flores and Y. Pouliot, 2007. Microfiltration of buttermilk and washed cream buttermilk for concentration of milk fat globule membrane components. J. Dairy Sci., 90: 2132-2140.

Mulder, H. and P. Walstra, 1974. The Milk Fat Globule. Centre for Agricultural Publishing and Documentation, Wageningen, Netherland, pp: 33-52.

Nelson, J.A. and G.M. Trout, 1964. Judging Dairy Products. The Olsen Publishing Company, Milwaukee.

Noh, S.K. and S.L. Koo, 2006. Milk sphingomyelin is more effective than egg sphingomyelin in inhibiting intestinal absorption of cholesterol and fat in rats. J. Nutr., 134: 2611-2616.

Pinto, S., A.K. Rathour, J.P. Prajapati, A.H. Jana and M.J. Solanky, 2007. Utilization of whey protein concentrate in processed cheese spread. Nat. Prod. Radiance, 6: 398-401.

Renner, E., G. Schaafsma and K.J. Scott, 1989. Micronutritiens in Milk. In: Micronutritiens in Milk and Milk Based Food Products, Renner, E. (Ed.)., Elsevier Applied Science, Essex, pp: 1-70.

Rombaut, R., J.V. Camp and K. Dewettinck, 2006. Phospho- and sphingolipid distribution during processing of milk, butter and whey. Int. J. Food Sci. Technol., 41: 435-443.

Rueda, R., J.L. Sabatel, J. Maldonado, J.A. Molina-Font and A. Gil, 1998. Addition of gangliosides to an adapted milk formula modifies levels of fecal Escherichia coli in preterm newborn infants. J. Pediatr., 133: 90-94.

Schmelz, E.M., D.L. Dillehay, S.K. Webb, A. Reiter, J. Adams and A.H. Jr. Merill, 1996. Sphingomyelin consumption suppresses aberrant colonic crypt foci and increases the proportion of adenomas versus adenocarcinomas in CF1 mice treated with 1,2-dimethylhydrazine: implications for dietary sphingolipids and colon carcinogenesis. Cancer Res., 56: 4936-4941.

Schmelz, E.M., M.A. Dombrink-Kurtzman, P.C. Roberts, Y. Kozutsumi, T. Kawasaki and A.H. Jr. Merill, 1998. Induction of apoptosis by fumonisin B1 in HT29 cells is mediated by the accumulation of endogenous free sphingoid bases. Toxicol. Appl. Pharmacol., 148: 252-260.

Sodini, I., P. Morin, A. Olabi and R. Jimenez-Flores, 2006. Compositional and functional properties of buttermilk: A comparison between sweet, sour and whey buttermilk. J. Dairy Sci., 89: 525-536.

Spitsberg, V.L., 2005. Invited review: Bovine milk fat globule membrane as a potential nutraceutical. J. Dairy Sci., 88: 2289-2294.

Sprong, R.C., M.F.E. Hulstein and R. van der Meer, 2002. Bovine milk fat components inhibit food-borne pathogens. Int. Dairy J., 12: 209-215.

Suleiman, T.A.E., M.O.M. Abdalla, N.H.M. El Haj and H.M.O. Elsiddig, 2011. Chemical and microbiological evaluation of processed cheese available in Khartoum market, Sudan. Am. J. Food Nutr., 1: 28-33.

Tamime, A.Y., 2011. Processed Cheese and Analogues: An Overview. 1st Edn., Blackwell Publishing Ltd., UK.

Wong, P.Y.Y. and D.D. Kitts, 2003. A comparison of the butter milk solids functional properties to nonfat dried milk, soy protein isolate, dried egg white and egg yolk powders. J. Dairy Sci., 86: 746-754.

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Published

15.12.2013

Issue

Vol. 13 No. 1 (2014)

Section

Research Article

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How to Cite

S. Doosh, K., A. Alhusyne, L., & N. Almosawi, B. (2013). Utilization of Concentrated Buttermilk in Functional Processed Cheese Manufacturing and Studying Some of its Physicochemical Properties. Pakistan Journal of Nutrition, 13(1), 33–37. https://doi.org/10.3923/pjn.2014.33.37