مروری بر پروتئین هیدرولیز شده‌ی حاصل از ضایعات آبزیان: روش‌های تولید، کاربردها و خواص زیستی آن

نویسندگان
کبری ضیایی 1
سید ولی حسینی 2
1 دانشجوی کارشناسی ارشد فرآوری محصولات شیلاتی، گروه شیلات، دانشکده‌ی کشاورزی و منابع طبیعی دانشگاه تهران، ایران، کرج
2 دانشیار گروه فرآوری محصولات شیلاتی، دانشکده‌ی کشاورزی و منابع طبیعی دانشگاه تهران، ایران، کرج
10.52547/fsct.18.111.383
چکیده
محصولات صید شده از دریا هم جهت مصارف انسانی و هم غیر انسانی مورد استفاده قرار می­گیرند. هرساله میزان زیادی از این محصولات بعد از صید به طرق مختلف عمل­آوری می­شوند که بعد از آن بیش از 50 درصد از آنها به عنوان ضایعات محسوب می­شوند و غیر قابل مصرف هستند. ضایعات حاصل از غذاهای دریایی مانند سر، دم، پوست، استخوان و امعا و احشا، را می­توان با ارزش افزودن به آنها و تولید محصولاتی مانند پودر ماهی، سس ماهی، سیلاژماهی و پروتئین هیدرولیز شده هم برای مصارف انسانی و هم حیوانی مورد استفاده قرار داد. ضایعات منابع ارزشمندی از مواد زیست فعال هستند و فرآورده­های حاصل از آنها قابلیت استفاده در زمینه­های مختلف دارویی، صنایع غذایی و آرایشی-بهداشتی را دارند. پروتئین هیدرولیز شده­ی ماهی (FPH) نیز فرآورده­ی حاصل از هیدرولیز پروتئین ماهی می­باشد که امروزه تولید آن از ضایعات ماهی، از سویی جهت کاهش ضایعات و کمک به حفظ محیط زیست و از سویی دیگر به جهت برخوردار بودن از خواص عملکردی و زیست فعالی فوق­العاده، مورد توجه قرار گرفته است. بنابراین هدف از مطالعه­ی حاضر معرفی این محصول، انواع کاربردها و چالش­های پیش­روی آن می­باشد.
کلیدواژه‌ها
ضایعات
زیست‌فعال
پروتئین هیدرولیز شده
خواص عملکردی

موضوعات

عنوان مقاله English

The review of hydrolyzed protein from fishery by-product: Production methods, application, Biological Properties

نویسندگان English

kobra ziyaei 1
Seyed Vali Hosseini 2
1 university of tehran
2 University of Tehran
چکیده English

According to FAO reports, a huge amount of fish processing by-products (around 50%) are produced every day. Fish processing by-products are mainly head, tail, skin, scale, backbone and viscera. These by-products usually consist of several bioactive materials, such as proteins, enzymes, fatty acids, and biopolymers. Seafood by-products could be a source of healthy food for both human (such as fish sauce, fish protein hydrolysate; FPH) and animals (such as fish meal, fish silage, FPH). Additionally, bioactive substances derived from seafood by-products have been used in various biotechnological, nutritional, pharmaceutical, and biomedical applications. FPH is one of the most important products which is prepared by hydrolysis of underutilized fish or fish processing by-products. Although FPH has been used for agricultural purposes, advanced technological developments have made it possible to apply these FPHs as functional ingredients in food and pharmaceuticals. Likewise, the hydrolysate is also a rich source of biologically active small peptides that have been proved for various therapeutic potentials. This paper will review properties and potential applications of FPH in the human nutrition.

کلیدواژه‌ها English

Fishery by-products
Bioactive compounds
FPH
Functional properties
[1] Love, D.C., Fry, J.P., Milli, M.C., Neff, R.A. 2015. Wasted seafood in the United States: Quantifying loss from production to consumption and moving toward solutions. Global Environmental Change, 35, 116–124.
[2] FAO. 2016. The State of World Fisheries and Aquaculture. World review of fisheries and aquaculture. 243p.
[3] Kristinsson, H.G., Barbara A. R. 2000. Fish Protein Hydrolysates: Production, Biochemical, and Functional Properties. Food Science and Nutrition, 40, 43-81.
[4] Wisuthiphaet, N., Kongruang, S. 2015. Production of Fish Protein Hydrolysates by Acid and Enzymatic Hydrolysis. Journal of Medical and Bioengineering, 4, 466-470.
[5] Kumar Pal, G., Suresh, P.V. 2016. Sustainable valorisation of seafood by-products: Recovery of collagen and development of collagen-based novel functional food ingredients. Innovative Food Science and Emerging Technologies 37, 201–215.
[6] FAO. 2014. The State of World Fisheries and Aquaculture. World review of fisheries and aquaculture. 243 p.
[7] Suresh, P. V., Prabhu, G. N. 2013. Seafood. In M. Chandrasekaran (Ed.), Valorization of food processing by-products. Taylor & Francis, New York: CRC Press 685–736 pp.
[8] Srikanya1, A., Dhanapal, K., Sravani1, K., Madhavi, K., Praveen Kumar, G. 2017. A Study on Optimization of Fish Protein Hydrolysate Preparation by Enzymatic Hydrolysis from Tilapia Fish Waste Mince. International Journal of Current Microbiology and Applied Sciences, 6, 3220-3229.
[9] Halim, N.R.A., Yusof, H.M., Sarbon, N.M. 2016. Functional and bioactive properties of fish protein hydolysates and peptides: A comprehensive review. Trends in Food Science & Technology, 51, 24-33.
[10] Arnesen, J. A., Gildberg, A. 2006. Extraction of muscle proteins and gelatine from cod head. Process Biochemistry, 41, 697-700.
[11] Geirsdottir, M., Sigurgisladottir, S., Hamaguchi, P. Y., Thorkelsson, G., Johannsson, R., Kristinsson, H. G.,
& Kristjansson, M. M. 2011. Enzymatic hydrolysis of blue whiting (Micromesistius poutassou); functional and bioactive properties. Journal of Food Science, 76, C14–C20.
[12] Javadian, S.R., Roshan, A., Ovisipour, M., Keshavarz, M., Nemati, M. 2015. Optimizing the production of kilka (Clupeonella cultiventris) hydrolyzed protein using permode enzyme. Journal of Marine Biology, 26, 83-90.
[13] Parekh, V.J, Rathod, V.K., Pandit, A.B., 2011. Substrate Hydrolysis: Methods, Mechanism, and Industrial. Applications of Substrate Hydrolysis, 103- 118.
[14] Chalamaiah, M., Dinesh kumar, B., Jyothirmayi, T. 2012. Fish protein hydrolysates: proximate composition amino acid composition, antioxidant activities and applications: a review. Food Chemistry, 135, 3020–3038.
[15] Benhabiles, M. S., Abdi, N., Drouiche, N., Lounici, H., Pauss, A., Goosen, M. F. A., Mameri, N. 2012. Fish protein hydrolysate production from sardine solid waste by crude pepsin enzymatic hydrolysis in a bioreactor coupled to an ultrafiltration unit. Material Science and Engineering C, 32, 922–928.
[16] Shahidi, F., 2007. Maximising the value of marin by- product. Boca Raton Booston New York Washangton, DC. 229 – 248 pp.
[17] Villamil,O., Váquiro,H., Solanilla, J.F. 2017. Fish viscera protein hydrolysates: Production, potential applications and functional and bioactive properties. Food Chemistry, 224, 160–171.
[18] Luisa Tavano, O. 2013. Protein hydrolysis using proteases: An important tool for food biotechnology. Journal of Molecular Catalysis B: Enzymatic, 90, 1– 11.
[19] Tsugita, A., Scheffler, J.J. A. 1982. A rapid method for acid hydrolysis of protein with a mixture of trifluoroacetic acid and hydrochloric acid. European Journal of Biochemistry, 124, 585-588.
[20] Tsugita, A., Scheffler, J. 1982. A Rapid Method for Acid Hydrolysis of Protein with a Mixture of Trifluoroacetic Acid and Hydrochloric Acid. Europe Journal Biochem, 124, 585-588.
[21] Mortazavi tabrizi, J., Sheyeh, J., Notash, Sh., Mirzaei, H., Vatan khah, A. 2011. Effect of different levels of multi enzyme on liver enzymes on functional factors in rainbow trout fish (oncorhynchus mykiss). Journal of Veterinary Islamic Azad University, 5, 49-55.
[22] Yang, F., Rustad, T., Xu, Y., Jiang, Q., Xia, W. 2015. Endogenous proteolytic enzymes – A study of their impact on cod (Gadus morhua) muscle proteins and textural properties in a fermented product. Food Chemistry, 172, 551–558.
[23] Hultmann, L., Rustad, T. 2004. Iced storage of Atlantic salmon (Salmo salar) – Effects on endogenous enzymes and their impact on muscle proteins and texture. Food Chemistry, 87, 31–41.
[24] Gaarder, M. Q., Bahuaud, D., Veiseth-Kent, E., Mّrkّre, T., Thomassen, M. S. 2012. Relevance of calpain and calpastatin activity for texture in super-chilled and ice-stored Atlantic salmon (Salmo salar L.) fillets. Food Chemistry, 132, 9–17.
[25] Aspmo, S.I., Horn, S.J., Eijsink, V.G. 2005. Enzymatic hydrolysis of Atlantic cod (Gadus morhua L.) viscera. Process Biochemistry, 40, 1957-1966.
[26] Ketnawa, S., Benjakul, S., Martinez-Alvarez,O., Rawdkuen, S. 2014. Three-phase partitioning and proteins hydrolysis patterns of alkaline proteases derived from fish viscera. Separation and Purification Technology, 132, 174–181.
[27] Bhaskar, N., Mahendrakar, N. S. 2008. Protein hydrolysate from visceral waste proteins of Catla (Catla catla): Optimization of hydrolysis conditions for a commercial neutral protease. Bioresource Technology 99: 4105–4111.
[28] Merza, M., Ewert, J., Baur, C., Appel, D., Blank, D., Stressler, T., Fischer, L., 2015. Wheat gluten hydrolysis using isolated Flavourzyme peptidases:Product inhibition and determination of synergistic effects usingresponse surface methodology. Journal of Molecular Catalysis B: Enzymatic, 122, 218–226.
[29] Valencia, P., Espinoza, K., Pinto, C.M., Almonacid, S. 2015. Novel modeling methodology for the characterization of enzymatichydrolysis of proteins. Process Biochemistry, 50, 589–597.
[30] Borah, A.J., Agarwal, M., Poudyal, M., Goyal, A., Moholkar, V.S. 2016. Mechanistic investigation in ultrasound induced enhancement of enzymatic hydrolysis of invasive biomass species. Bioresource Technology, 213, 342–349.
[31] Hosseini, Sh., Ghoroghi, A., Jamalzadeh, H.R., Safari, R., Hosseini, Sh. 2012. Comparison of produced fish protein hydrolysete from viscera and head of Silver carp (Hypophthalmichthys molitrix) using Alcalase enzyme and internal tissue enzymes. Iranian Scientific Fisheries Journal, 55-62.
[32] Ha, M., Dinbekhit, A., Carne,A., Hopkins, D. 2013. Char,Hemalatha,R. acterisation of kiwifruit and asparagus enzyme extracts , and their activities toward meat protein. Food Chemistry, 136, 989–998.
[33] Benjakul, S., Yarnpakdee, S., Senphan, T., Halldorsdottir, S.M., Kristinsson, H.G. 2014. Fish protein hydrolysates: Production, bioactivities, and applications. In H. G. Kristinsson (Ed.), Chichester, UK: John Wiley & Sons Ltd. 237–281 pp.
[34] Liu,Y., Li,X., Chen,Z., Yu, J., Wang,F., Wang, J., 2014. Characterization of structural and functional properties of fish protein hydrolysates from surimi processing by-products. Food Chemistry, 151, 459–465.
[35] García-Moreno, P.J., Batista,I., Pires, C., Bandarra, N.M., Espejo-Carpio, F.J., Guadix, A.,Guadix, E.M. 2016. Physical and oxidative stability of fish oil-in-water emulsions stabilized with fish protein hydrolysates. Food chemistry 203:124-135.
[36] Venugopal. V., 2016. Marine Enzymes Biotechnology: Production and Industrial Applications, Part II - Marine Organisms Producing Enzymes, Advances in Food and Nutrition Research, Academic Press, 47-69 pp.
[37] Ovissipour, M., Abedian Kenari, A., Motamedzadegan, A., & Nazari, R. M. 2010. Optimization of enzymatic hydrolysis of visceral waste proteins of Yellowfin Tuna (Thunnus albacares). Food and Bioprocess Technology, 5:696–705.
[38] Foh, M.B.K., Kamara, M.T., Amadou, I., Foh, B.M., Wenshui, X. 2011. Chemical and physicochemical properties of Tilapia (Oreochromis niloticus) fish protein hydrolysates and concentrate. International Journal of Biological Chemistry, 5, 21–36.
[39] Moreno, P., Guadix, A., Guadix, E., Jacobsen, Ch. 2016. Phsical and oxidative stability of fish oil- in- water emulsions stabilized with fish protein hydrolysates. Food chemistry, 203, 124-135.
[40] Shabanpour, B., Kordjazi, M., Nazari, Kh., Esmaeili Khariki, M. 2017. Effect of enzymatic hydrolysis time, temperature and enzyme to substrate ratio on antioxidant properties of prawn bioactive peptides. Journal of food science and technology, 14, 31-45.
[41] Taheri, A., Anvar, S. A. A., Ahari, H., Fogliano, V. 2013. Comparison the functional properties of protein hydrolysates from poultry by-products and rainbow trout (Onchorhynchus mykiss) viscera. Iranian Journal of Fisheries Science, 12, 154 – 169.
[42] Nalinanon, S., Benjakul, S., Kishimura, H., Shahidi, F. 2011. Functionalities and antioxidant properties of protein hydrolysates from the muscle of ornate threadfin bream treated with pepsin from skipjack tuna. Food Chemistry, 124, 1354–1362.
[43] Nasri, R., Abdelhedi, O., Jemil, I., Daoued,I., Hamden, Kh., Kallel, Ch., Abdelfattah, E., Senhadji, M., Boualga, A., Nasri, M., Karra-Ch^aabouni, M. 2015. Ameliorating effects of goby fish protein hydrolysates on high-fat-high-fructose diet-induced hyperglycemia, oxidative stress and deterioration of kidney function in rats. Chemico-Biological Interactions, 242, 71-80.
[44] Barrias, C., Oliva-Teles. 2000. The use of locally produced fish meal and other dietary manipulations in practical diets for rainbow trout Oncorhynchus mykiss (Walbaum). Aquaculture Res, 31, 213 – 218.
[45] Toopcham,T., Mes, J.J., Wichers, H.J., Roytrakul, S., Yongsawatdigul, J. 2017. Bioavailability of angiotensin I-converting enzyme (ACE) inhibitory peptides derived from Virgibacillus halodenitrificans SK1-3-7 proteinases hydrolyzed tilapia muscle proteins. Food Chemistry, 220, 190–197.
[46] Xu, H., Mu,Y., Zhang,Y., Li, J., Liang, M., Zheng,K., Wei,Y. 2016. Graded level of fish protein hydrolysate in high plant diets for turbot (Scophthalmus maximus): effects on growth performance and lipid accumulation. Aquaculture, 454, 140- 147.
[47] Ness, K., Nasalakshmi, A.P., Marimuthu, P., Singh, M., Bhetariya, P., Ho, M., Simon, R. 2014. Safety evaluation of fish protein hydrolysate supplementation in malnourished. Regulatory Toxicology and Pharmacology 69: 1–6.
[48] Dervaj, Z., Javadian, S.R., Ovisipour, M., Nemati, M. 2013. The use of Kilka's hydrolyzed protein (Clupeonella cultiventris) as a source of peptone in a bacterial culture medium (Bacillus subtilis, bacillus licheniformis vibrio anguillarum). Journal of aqatic and fisherys, 15, 11-18.
[49] Valencia, P.L., Flores, S.A., Pinto, M.J., Almonacid, S.F. 2016. Analysis of the operational strategies for the enzymatic hydrolysis of food proteins in batch reactor. Journal of Food Engineering, 176, 121 – 127.
[50] Foh, M.B.K., Kamara, M.T., Amadou, I., Foh, M.B., Wenshui, X. 2011. Chemical and physicochemical properties of tilapia (Oreochromis niloticus) Fish Protein Hydrolysate and Concntrate. International Journal of Biological Chemistry, 155, 1-15
مجله علوم و صنایع غذایی ایران
دوره 18، شماره 111 - شماره پیاپی 111
اردیبهشت 1400
صفحه 383-395