Hostname: page-component-cd9895bd7-gxg78 Total loading time: 0 Render date: 2024-12-24T18:51:34.207Z Has data issue: false hasContentIssue false

Reduced-fat Frescal sheep milk cheese with inulin: a first report about technological aspects and sensory evaluation

Published online by Cambridge University Press:  22 July 2019

Joyce Valle Borges
Affiliation:
Mestrado em Ciência e Tecnologia de Leite e Derivados, Universidade Pitágoras Unopar (UNOPAR), Londrina, Brazil
José Augusto de Souza
Affiliation:
Mestrado em Ciência e Tecnologia de Leite e Derivados, Universidade Pitágoras Unopar (UNOPAR), Londrina, Brazil
Rafael Fagnani
Affiliation:
Mestrado em Ciência e Tecnologia de Leite e Derivados, Universidade Pitágoras Unopar (UNOPAR), Londrina, Brazil
Giselle Nobre Costa
Affiliation:
Mestrado em Ciência e Tecnologia de Leite e Derivados, Universidade Pitágoras Unopar (UNOPAR), Londrina, Brazil
Joice Sifuentes dos Santos*
Affiliation:
Mestrado em Ciência e Tecnologia de Leite e Derivados, Universidade Pitágoras Unopar (UNOPAR), Londrina, Brazil
*
Author for correspondence: Joice Sifuentes dos Santos, Email: [email protected]

Abstract

This research paper aimed to evaluate the role of inulin as a fat replacer on the quality of Frescal sheep milk cheese. Sheep milk and its derivatives are a promising niche in the dairy industry, mainly due to increasing interest of consumers in diversified products. Three Frescal sheep milk cheese formulations, namely whole milk cheese (WMC), semi-skimmed cheese (SSC) and semi-skimmed cheese with 5 g/100 g inulin (SSCI) were prepared. Their composition was evaluated and the feasibility of using inulin as a fat substitute was investigated. SSC and SSCI were considered ‘reduced fat’ or ‘reduced calorie’ products. The addition of inulin to SSCI cheeses yielded textural parameters (firmness, adhesiveness, cohesiveness, and gumminess) with intermediate characteristics between SSC and WMC. All the formulations presented scores higher than 7.6 in sensory analysis. In conclusion, the use of inulin in semi-skimmed sheep cheese allowed the production of cheese with texturizing properties similar to whole milk sheep cheese, enabling the development of a foodstuff with lower caloric content and beneficial characteristics valued by consumers.

Type
Research Article
Copyright
Copyright © Hannah Dairy Research Foundation 2019 

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

AOAC (2011) Association of Official Analytical Chemists, 16th Edn. Rockville, USA: Official Methods of Analysis of AOAC International.Google Scholar
Balthazar, CF, Gase, L, Silva, H, Pereira, C, Franco, F, Conte-Júnior, CA, Freitas, MQ and Silva, ACO (2009) Sensory evaluation of ovine milk yoghurt with inulin addition. International Journal of Dairy Technology 67, 110.Google Scholar
Balthazar, CF, Conte Júnior, CA, Moraes, J, Costa, MP, Raices, RSL, Franco, RM, Cruz, AG and Silva, ACO (2016) Physicochemical evaluation of sheep milk yogurts containing different levels of inulin. Journal of Dairy Science 99, 41604168.Google Scholar
Balthazar, CF, Silva, HLA, Cavalcanti, RN, Esmerino, EA, Cappato, LP, Abud, YKD, Moraes, J, Andrade, MM, Freitas, MQ, Sant'Anna, C, Raices, RSL, Silva, MC and Cruz, AG (2017) Prebiotics addition in sheep milk ice cream: a rheological, microstructural and sensory study. Journal of Functional Foods 35, 564573.Google Scholar
Brasil (1998) Ministério da Saúde. Portaria no 27, de 13 de janeiro de 1998. Regulamento Técnico referente à Informação Nutricional Complementar, Brasília-DF.Google Scholar
Brasil (2001) Ministério da Saúde. Resolução RDC no 12, de 02 de Janeiro de 2001. Regulamento técnico sobre padrões microbiológicos para alimentos, Brasília-DF.Google Scholar
Brennan, CS and Tudorica, CM (2008) Carbohydrate-based fat replacers in the modification of the rheological, textural and sensory quality of yoghurt: comparative study of the utilisation of barley beta-glucan, guar gum and inulin. International Journal of Food Science and Technology 43, 824833.Google Scholar
Broadbent, JR, McMahon, DJ, Oberg, CJ and Welker, DL (2001) Use of exopolysaccharide-producing cultures to improve the functionality of low fat cheese. International Dairy Journal 11, 433439.Google Scholar
Buriti, FCA, Rocha, JS and Saad, SMI (2005) Incorporation of Lactobacillus acidophilus in Minas fresh cheese and its implications for textural and sensorial properties during storage. International Dairy Journal 15, 12791288.Google Scholar
Buriti, FCA, Cardarelli, HR and Saad, SMI (2008) Influence of Lactobacillus paracasei and inulin on instrumental texture and sensory evaluation of fresh cream cheese. Revista Brasileira de Ciências Farmacêuticas 44, 7584.Google Scholar
Cardarelli, HR, Buriti, FCA, Castro, IA and Saad, SMI (2008) Inulin and oligofructose improve sensory quality and increase the probiotic viable count in potentially synbiotic petit-suisse cheese. LWT – Food Science and Technology 41, 10371046.Google Scholar
Cunha, CR, Viotto, WH and Viotto, LA (2006) Use of low concentration factor ultrafiltration retentates in reduced fat ‘Minas Frescal’ cheese manufacture: effect on composition, proteolysis, viscoelastic properties and sensory acceptance. International Dairy Journal 16, 215224.Google Scholar
Fadaei, V, Poursharif, K, Daneshi, M and Honarvar, M (2012) Chemical characteristics of low-fat wheyless cream cheese containing inulin as fat replacer. European Journal of Experimental Biology 2, 690694.Google Scholar
Food and Drug Administration (2008) Codex general standard for cheese declaration milkfat. Codex standard 283. Available at http://www.fao.org/input/download/standards/175/CXS_283e.pdf.Google Scholar
Food and Drug Administration (2013) Guidance for Industry: A Food Labeling Guide. Available at https://www.fda.gov/Food/GuidanceRegulation/GuidanceDocumentsRegulatoryInformation/LabelingNutrition/ucm064919.htm.Google Scholar
Fox, PF and Mcsweeney, PLH (1998) Dairy Chemistry and Biochemistry. London: Blackie Academic & Professional, 478p.Google Scholar
Giri, A, Kanawjia, SK and Singh, MP (2017) Effect of inulin on physico-chemical, sensory, fatty acid profile and microstructure of processed cheese spread. Journal of Food Science and Technology 54(8), 24432451.Google Scholar
Kealy, T (2006) Application of liquid and solid rheological technologies to the textural characterization of semi-solid foods. Food Research International 39, 265276.Google Scholar
Koca, N and Metin, M (2004) Textural, melting and sensory properties of low-fat fresh kashar cheeses produced by using fat replacers. International Dairy Journal 14, 365373.Google Scholar
Kocer, D, Hicsasmaz, Z, Bayindirli, A and Katnas, S (2007) Bubble and pore formation of the high-ratio cake formulation with polydextrose as a sugar- and fat-replacer. Journal of Food Engineering 78, 953964.Google Scholar
Masoodi, TA and Shafi, G (2010) Analysis of casein alpha S1 & S2 proteins from different mammalian species. Bioinformation 4, 430435.Google Scholar
Mcmahon, DJ, Alleyne, MC, Fife, RL and Obergt, CJ (1996) Use of fat replacers in low fat Mozzarella cheese. Journal of Dairy Science 79, 19111921.Google Scholar
Meyer, D, Bayarri, S, Tárrega, A and Costell, E (2011) Inulin as texture modifier in dairy products. Food Hydrocolloids 25, 18811890.Google Scholar
Mistry, VV (2001) Low fat cheese technology. International Dairy Journal 11, 413422.Google Scholar
Modzelewska-KapituŁa, M and KŁȩbukowska, L (2009) Investigation of the potential for using inulin HPX as a fat replacer in yoghurt production. International Journal of Dairy Technology 62, 209214.Google Scholar
Monteiro, VF, Leal, NS, Marques, RO, Fernandes, S and Siqueira, ER (2013) Characterization and sensory evaluation of cheese frescal milk of ewes supplemented with flaxseed oil. In: XVI Simpósio Paranaense de Ovinocultura, Pato Branco-PR, pp. 14.Google Scholar
Nair, KK, Kharb, S and Thompkinson, DK (2010) Inulin dietary fiber with functional and health attributes—A review. Food Reviews International 26, 189203.Google Scholar
O'Connor, TP and O'Brien, NM (2011) Fat replacers. In Fuquay, JW (ed.), Butter and Other Milk fat Products. Oxford: Elsevier, pp 528532.Google Scholar
Park, YW, Juárez, M, Ramos, M and Haenlein, GFW (2007) Physico-chemical characteristics of goat and sheep milk. Small Ruminant Research 68, 88113.Google Scholar
Paseephol, T, Small, DM and Sherkat, F (2008) Rheology and texture of set yogurt as affected by inulin addition. Journal of Texture Studies 39, 617634.Google Scholar
Rodríguez-García, J, Salvador, A and Hernando, I (2014) Replacing fat and sugar with inulin in cakes: bubble size distribution, physical and sensory properties. Food and Bioprocess Technology 7, 964974.Google Scholar
Salvatore, E, Pes, M, Falchi, G, Pagnozzi, D, Furesi, S, Fiori, M, Roggio, T, Addis, MF and Pirisi, A (2014) Replacement of fat with long-chain inulin in a fresh cheese made from caprine milk. International Dairy Journal 34, 15.Google Scholar
Tungland, BC and Meyer, D (2002) Nondigestible oligo- and polysaccharides (dietary fiber): their physiology and role in human health and food. Comprehensive Reviews in Food Science and Food Safety 1, 90109.Google Scholar
Verbeke, W (2006) Functional foods: consumer willingness to compromise on taste for health? Food Quality and Preference 17, 126131.Google Scholar
Whittier, EO (1929) Buffer intensities of milk and milk constituents: I. The buffer action of casein in milk. Journal of Biology and Chemistry 83, 7988.Google Scholar