Optimization of microencapsulation of fish oil in the coating of sodium caseinate, maltodextrin, whey protein concentrates and modified starch by mixture design method

Document Type : scientific research article

Authors

1 Corresponding Author, Assistant Prof., Dept. of Food Science and Technology, Shahrood Branch, Islamic Azad University, Shahrood, Iran.

2 Assistant Prof., Dept. of Aquatic Science, Hamon International Wetland Research Institute, Zabol Research Institute, Zabol, Iran

3 Ph.D. Graduate of Sea Food Processing, Gorgan University of Agricultural Sciences and Natural Resources, Gorgan, Iran

4 Assistant Prof., Dept. of Sea Food Processing, Gorgan University of Agricultural Sciences and Natural Resources, Gorgan, Iran.

Abstract

The present research was done with the aim of encapsulation of fish oil with a ratio of 3:1 (oil: coating) with coatings of maltodextrin, sodium caseinate, whey protein concentrate and modified starch with different ratios by freeze dryer and in order to achieve the maximum encapsulation efficiency was optimized using a mixture design. Optimizing the concentration of different walls for microencapsulation using numerical and graphical optimization revealed that the optimal wall composition contains maltodextrin (15.16%), sodium caseinate (20%), whey protein concentrate (20%) and modified starch (19.84 %) with the encapsulation efficiency was 89.3 %.The results showed that according to the difference in the wall compositions and their ratios, the particle size, poly dispersity index (PDI), and encapsulation efficiency had different values. So that the size of the particles varied from 0.34 μm to 1.3 μm, and the PDI varied from 0.1 to 0.92. Evaluation of oxidative stability in optimal microcapsule powder and free fish oil stored at 0 and 32% humidity during 21 days of storage showed that encapsulated oil at zero humidity had higher oxidative stability during the storage period. In addition, the increase in humidity in the storage environment of microcapsules increased the intensity of oxidation in the treatments stored in 32% humidity. Therefore, it can be concluded that the use of microencapsulation technique is a practical and effective method to increase the oxidative stability of fish oil for use in the food and drug industry.

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Main Subjects

References

1.Venugopalan, V., Ramadevi Gopakumar, L., Kizhakkeppurath Kumaran, A., Sekhar Chatterjee, N., Soman, V., Peeralil, SH., Mathew, S., McClements, D., & Chandragiri Nagarajarao, R. (2021). Encapsulation and Protection of Omega-3-Rich Fish Oils Using Food-Grade Delivery Systems. Foods. 10, 1566.
2.Jafari, S. M., Assadpoor, E., Bhandari, B., & He, Y. (2008). Nano-particle encapsulation of fish oil by spray drying. Food Res. Int. 41, 172-183.
3.Perez-Palacios, P., Ruiz-Carrascal, J., Solomando, J., de-la-Haba, F., Pajuelo, A., & Antequera, T. (2022). Recent Developments in the Microencapsulation of Fish Oil and Natural Extracts: Procedure, Quality Evaluation and Food Enrichment. Foods. 11, 3291.
4.Jafari, S. M. (2019). Biopolymer Nanostructures for Food Encapsulation Purposes: Volume 1 in the Nanoencapsulation in the Food Industry series (Vol. 1): Academic Press.
5.Mahdavi, S. A., Sadeghi, R., Faridi, A., Hedayati, S., Shaddel, R., Dima, C., & Jafari, S. M. (2022). Nanodelivery systems for d-limonene; techniques and applications. Food Chem. 132479.
6.Madene, A., Jacquot, M., Scher, J., & Desobry, S. (2006). Flavour encapsulation and controlled release – A review. Int. J. Food Sci. Technol. 41 (1), 1-21.
7.Hasani, Sh., Ojagh, M., Hasani, M., & Ghorbani, M. (2019). Sensory and Technological Properties of Developed Functional Bread Enriched by Microencapsulated Fish Oil. Prog. Nutr. 21 (1), 406-415.
8.Goula, A. M., & Adamopoulos, K. G. (2012). A new technique for spray- dried encapsulation of lycopene. Dry. Technol. 30: 6. 641-652.
9.Rocha, G. A., Favaro-Trindade, C. S., & Grosso, C. R. F. 2012. Microencapsulation of lycopene by spray drying: Characterization, stability and application of microcapsules. Food Bioprod. Process. 90 (1), 37-42.
10.Hamed, S. F., Soliman, T. N., Hassan, L. K., & Abo-Elwafa, G. (2019). Preparation of functional yogurt fortified with fish oil-in-water nanoemulsion. Egypt. J. Chem. 62, 301-314.
11.Chen, H., & Zhong, Q. (2014). Processes improving the dispersibility of spray-dried zein nanoparticles using sodium caseinate. Food Hydrocoll. 35, 358-366.
12.Long, Z., Zhao, Q., Liu, T., Kuang, W., Xu, J., & Zhao, M. (2012). Role and properties of guar gum in sodium caseinate solution and sodium caseinate stabilized emulsion. Food Res. Int. 49, 545-552.
13.García-Moreno, P. J., Pelayo, A., Yu, S., Busolo, M., Lagaron, J. M., Chronakis, I. S., & Jacobsen, C. (2018). Physicochemical Characterization and Oxidative Stability of Fish-oil-loaded Electrosprayed Capsules: Combined Use of Whey Protein and Carbohydrates as Wall Materials. J. Food Eng. 231, 42-53.
14.Charles, A. L., Abdillah, A. A., Saraswati, Y. R., Sridhar, K., Balderamos, C., Masithah, E. D., & Alamsjah, M. A. (2021). Characterization of freeze-dried microencapsulation Tuna Fish Oil with arrowroot starch and maltodextrin. Food Hydrocoll.
112, 106281.
15.Damerau, A., Ogrodowska, D., Banaszczyk, P., Dajnowiec, F., Ta´nska, M., & Linderborg, K. M. (2022). Baltic Herring (Clupea harengus membras) oil encapsulation by spray drying using a rice and whey protein blend as a coating material. J. Food Eng. 314, 110769.
16.Jamshidi, A., Antequera, T., Solomando, J. C., & Perez-Palacios, T. (2020). Microencapsulation of oil and protein hydrolysate from fish within a high-pressure homogenized double emulsion. J. Food Sci. Technol. 57, 60-69.
17.Özyurt, G., Durmu, M., Uçar, Y., & Özogul, Y. (2020). The potential use of recovered fish protein as wall material for microencapsulated Anchovy oil. LWT. 129, 109554.
18.Ogrodowska, D., Laaksonen, O., Tanska, M., Konopka, I., & Linderborg, K. M. (2020). Pumpkin oil addition and encapsulation process as methods to improve oxidative stability of fish oil. LWT. 124, 109142.
19.Yilmaz, M. T., Yildiz, O., Yurt, B., Toker, O. S., Karaman, S., & Basturk, A. (2015). A mixture design study to determine interaction effects of wheat,buckwheat, and rice flours in an aqueous model system. LWT - Food Sci. and Technol. 61, 583-589.
20.Bligh, E. G., & Dyer, W. J. (1959). A rapid method for total lipid extraction and purification. Can. J. Biochem. Physiol. 37, 911-917.
21.Gallardo, G., Guida, L., Martínez, V., López, M. C., Bernhardt, D., Blasco, R., Pedroza-Islas, R., & Hermida, L. G. (2013). Microencapsulation of linseed oil by spray drying for functional food application. Food Res. Int.52 (2), 473-482.
22.Carneiro, H. C. F., Tonon, R. V., Grosso, C. R. F., & Hubinger, M. D. (2013). Encapsulation efficiency and oxidative stability of flaxseed oil microencapsulated by spray drying using different combinations of wall materials. J. Food Eng. 115, 443-451.
23.Ojagh, S. M., & Hasani, S. (2018). Characteristics and oxidative stability of fish oil nanoliposomes and its application in functional bread. J. Food Meas. Charact. 12 (2), 1084-1092.
24.Velasco, J., Dobarganes, C., Holgado, F., & Marquez-Ruiz, G. (2009). A follow-up oxidation study in dried microencapsulated oils under the accelerated conditions of the Rancimat test. Food Res. Int. 42, 56–62.
25.Wang, H., Qian, H., & Yao, W. (2012). Melanoidins produced by the Maillard reaction: structure and biological activity. Food Chem. 128 (3), 573-584.
26.International Association of fish Meal Manufacturers (IFFM). (1981). Recommended Method Analysis for Determination of Anisidine Value of Fish Oil, Fish Oil Bultein, NO.8.
27.Saguy, I. S., Shani, A., Weinberg, P., & Garti, N. (1996). Utilization of Jojoba oil for deep fat frying of foods, LWT- Food Sci. Technol. 29 (5-6), 573-577.
28.Azizanbari, C., Ghanbarzadeh, B., Hamishehkar, H., & Hosseini, M. (2013). Gellan-caseinate nanocomplexes as a Carrier of omega-3 fatty acids: Study of particle size, rheological properties and encapsulation efficiency. J. Food Process. Preserv. 5 (2), 19-42.
29.Choi, M. J., Ruktanonchai, U., Min, S. G., Chun, J. Y., & Soottitantawat, A. (2010). Physical characteristics of fish oil encapsulated by β- cyclodextrin using an aggregation method or polycaprolactone using an emulsion–diffusion method. Food Chem. 119, 1694-1703.
30.Bahrani, S., Ghanbarzadeh, B., Hamishekar, H., & Sowti Khiyabani, M. (2013). Nanoencapsulation of omega-3 fatty acids using caseinate-pectin based complexes: FTIR, DSC, particle size, and encapsulation efficiency. Iranian Journal of Nutrition Sciences & Food Technology. 8 (3), 1-15.
31.Legako, J., & Dunford, N. T. (2010). Effect of spray nozzle design on fish oil-whey protein microcapsule properties. Food Sci. 75 (6), 394-400.
32.Hundre, S. Y., Karthik, P., & Anandharamakrishnan, C. (2015). Effect of whey protein isolate and beta cyclodextrin wall systems on stability of microencapsulated vanillin by spray-freeze drying Method. Food Chem.174, 16-24.
33.Ghorbanzade, T., Jafari, S. M., Akhavan, S., & Hadavi, R. (2017). Nano-encapsulation of fish oil in nano-liposomes and its application in fortification of yogurt. Food Chemistry, 216, 146-152.
34.Ho, S., Thoo, Y. Y., Young, D. J., & Siow, L. F. (2017). Inclusion complexation of catechin by β-cyclodextrins: Characterization and storage stability. LWT - Food Sci. and Technol. 86, 555-565.
35.da Rocha Neto, A. C., da Rocha, A. B.d. O., Maraschin, M., Di Piero, R. M., & Almenar, E. (2018). Factors affecting the entrapment efficiency of β-cyclodextrins and their effects on the formation of inclusion complexes containing essential oils. Food Hydrocoll. 77, 509-523.
36.Rakmai, J., Cheirsilp, B., Cid, A., Torrado-Agrasar, A., Mejuto, J. C., & Simal-Gandara, J. (2018). Encapsulation of essential oils by cyclodextrins: characterization and evaluation. Cyclo: A Ver. Ing. 263.
37.Bejrapha, P., Min, S. G., Surassmo, S., & Choi, M. J. (2010). Physicothermal properties of freeze-dried fish oil nanocapsules frozen under different conditions. Dry. Technol. 28 (4), 481-489.
38.Drusch, S., Serfert, Y., Berger, A., Shaikh, M. Q., Ratzke, K., Zaporojtchenko, V., & Schwarz, K. (2012). New insights into the microencapsulation properties of sodium Caseinate and hydrolyzed casein. Food Hydrocoll. 27, 332-338.
39.Chen, Q., McGillivray, D., Wen, J., Zhong, F., & Young Quek, S. (2013). Co-encapsulation of fish oil with phytosterol esters and limonene by milk proteins. J. Food Eng. 117, 505-512.
40.Rahmani-Manglano, N., Guadix, E., Jacobsen, CH., & García-Moreno, P. (2023). Comparative Study on the Oxidative Stability of Encapsulated Fish Oil by Monoaxial or Coaxial Electrospraying and Spray-Drying. Antioxidants. 12, 266.
41.Kavousi, H. R., Fathi, M., & Goli, S. A. H. (2017). Stability enhancement of fish oil by its encapsulation using a novel hydrogel of cress seed mucilage/chitosan. Int. J. Food Prop. 20 (2), 1890-1900.
42.Sun-Waterhouse, D., Zhou, J., Miskelly, G. M., Wibisono, R., & Wadhwa, S. S. (2011). Stability of encapsulated olive oil in the presence of caffeic acid. Food Chem. 126 (3), 1049-1056.
43.Ghorbanzade, T., Akhavan-Mahdavi, S., Kharazmi, M., Ibrahim, S., & Jafari, S. M. (2022). Loading of fish oil into
β-cyclodextrin nanocomplexes for the production of a functional yogurt. Food Chem. 15, 100406.
Journal of Utilization and Cultivation of Aquatics
Volume 12, Issue 3
October 2023
Pages 171-192

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