مروری بر نانوکپسول سازی در صنایع غذایی: فناوری، کاربردها و چالش‌ها

نویسندگان
محمدیار حسینی 1
محمد کرد 2
1 دانشگاه بناب
2 دانشگاه ایلام
10.22034/FSCT.22.165.212
چکیده
نانوکپسول‌سازی mouseout="msoCommentHide('_com_1')" onmouseover="msoCommentShow('_anchor_1','_com_1')">[MK1] به عنوان یک فناوری نوین در صنایع غذایی، توانایی بالایی در بهبود کیفیت، ایمنی و پایداری محصولات غذایی دارد. این فناوری با محصور کردن ترکیبات زیست‌فعال مانند ویتامین‌ها، آنتی‌اکسیدان‌ها و مواد ضد میکروبی در مقیاس نانو، از تخریب آن‌ها در برابر عوامل محیطی مانند نور، دما و اکسیژن جلوگیری می‌کند و به آزادسازی کنترل‌شده و هدفمند آن‌ها کمک می‌کند. این ویژگی باعث افزایش ماندگاری و اثرگذاری ترکیبات فعال در محصولات غذایی می‌شود. همچنین، نانوکپسول‌ها می‌توانند بهبود تجربه مصرف‌کننده را از طریق آزادسازی تدریجی مواد مغذی و طعم‌دهنده‌ها فراهم کنند. با این حال، استفاده از نانوکپسول‌سازی در صنایع غذایی با چالش‌هایی روبه‌رو است، از جمله هزینه‌های تولید بالا، نگرانی‌های ایمنی مرتبط با نانوذرات و اثرات بلندمدت آن‌ها بر سلامت انسان. مقاله حاضر به بررسی فناوری‌های مختلف نانوکپسول‌سازی، شامل روش‌های فیزیکی، شیمیایی و زیستی، و کاربردهای آن در بهبود پایداری و کیفیت محصولات غذایی می‌پردازد. علاوه بر این، چالش‌های موجود در این فناوری، از جمله مشکلات زیست‌محیطی و محدودیت‌های اقتصادی، مورد ارزیابی قرار می‌گیرد. با وجود مزایای فراوان، تحقیقات بیشتری برای ارزیابی ایمنی و تأثیرات نانوذرات در بلندمدت مورد نیاز است تا استفاده از این فناوری به طور ایمن و مؤثر در صنایع غذایی و دارویی گسترش یابد.



mouseout="msoCommentHide('_com_1')" onmouseover="msoCommentShow('_anchor_1','_com_1')"> [MK1]اصلاح شد(justified)
کلیدواژه‌ها
نانوکپسول
نانوذرات
نانوکپسول سازی
دسترسی زیستی
نانوایمنی

موضوعات

عنوان مقاله English

Nanoencapsulation in food industry: technology, applications and challenges; a review

نویسندگان English

mohammadyar hosseini 1
mohammad kurd 2
1 university of Bonab
2 ilam university
چکیده English

Nanocapsulation, as an innovative technology in the food industry, has great potential to improve the quality, safety, and stability of food products. This technology prevents the degradation of bioactive compounds such as vitamins, antioxidants, and antimicrobial agents by encapsulating them at the nanoscale, protecting them from environmental factors like light, temperature, and oxygen, while facilitating their controlled and targeted release. This feature enhances the shelf life and efficacy of active compounds in food products. Additionally, nanocapsules can improve consumer experiences through the gradual release of nutrients and flavorings. However, the use of nanocapsulation in the food industry faces challenges, including high production costs, safety concerns related to nanoparticles, and their long-term effects on human health. This article reviews various nanocapsulation technologies, including physical, chemical, and biological methods, and their applications in enhancing the stability and quality of food products. Furthermore, the existing challenges in this technology, including environmental issues and economic limitations, will be evaluated. Despite the numerous advantages, further research is needed to assess the safety and long-term impacts of nanoparticles so that the safe and effective use of this technology can be expanded in the food and pharmaceutical industries.

کلیدواژه‌ها English

nanocapsule
Nanoparticles
Nanoencapsulation
Bioavailability
Nano-safety
[1] Shah, A. K., & Dhalla, N. S. (2021). Effectiveness of some vitamins in the prevention of cardiovascular disease: a narrative review. Frontiers in Physiology, 12, 729255.
[2] Sherratt, S. C., Libby, P., Budoff, M. J., Bhatt, D. L., & Mason, R. P. (2023). Role of omega-3 fatty acids in cardiovascular disease: the debate continues. Current atherosclerosis reports, 25(1), 1-17.
[3] Montenegro-Landívar, M. F., Tapia-Quirós, P., Vecino, X., Reig, M., Valderrama, C., Granados, M., ... & Saurina, J. (2021). Polyphenols and their potential role to fight viral diseases: An overview. Science of the Total Environment, 801, 149719.
[4] Li, Meng, et al. "Evidence of flavonoids on disease prevention." Antioxidants 12.2 (2023): 527.
[5] Udenigwe, C. C., Abioye, R. O., Okagu, I. U., & Obeme-Nmom, J. I. (2021). Bioaccessibility of bioactive peptides: Recent advances and perspectives. Current opinion in food science, 39, 182-189.
[6] Enaru, B., Drețcanu, G., Pop, T. D., Stǎnilǎ, A., & Diaconeasa, Z. (2021). Anthocyanins: Factors affecting their stability and degradation. Antioxidants, 10(12), 1967.
[7] Cao, H., Saroglu, O., Karadag, A., Diaconeasa, Z., Zoccatelli, G., Conte‐Junior, C. A., ... & Xiao, J. (2021). Available technologies on improving the stability of polyphenols in food processing. Food Frontiers, 2(2), 109-139.
[8] Lavanya, M., Namasivayam, S. K. R., & John, A. (2024). Developmental formulation principles of food preservatives by nanoencapsulation—fundamentals, application, and challenges. Applied Biochemistry and Biotechnology, 1-31.
[9] Chowdhury, S., Kar, K., & Mazumder, R. (2024). Exploration of different strategies of nanoencapsulation of bioactive compounds and their ensuing approaches. Future Journal of Pharmaceutical Sciences, 10(1), 72.
[10] Arratia-Quijada, J., Nuño, K., Ruíz-Santoyo, V., & Andrade-Espinoza, B. A. (2024). Nano-encapsulation of probiotics: Need and critical considerations to design new non-dairy probiotic products. Journal of Functional Foods, 116, 106192.
[11] Jurić, S., Jurić, M., Siddique, M. A. B., & Fathi, M. (2022). Vegetable oils rich in polyunsaturated fatty acids: Nanoencapsulation methods and stability enhancement. Food reviews international, 38(1), 32-69.
[12] Tahir, A., Shabir Ahmad, R., Imran, M., Ahmad, M. H., Kamran Khan, M., Muhammad, N., ... & Javed, M. (2021). Recent approaches for utilization of food components as nano-encapsulation: a review. International Journal of Food Properties, 24(1), 1074-1096.
[13] Ayyaril, S. S., Shanableh, A., Bhattacharjee, S., Rawas-Qalaji, M., Cagliani, R., & Shabib, A. G. (2023). Recent progress in micro and nano-encapsulation techniques for environmental applications: A review. Results in Engineering, 18, 101094.
[14] Janik, M., Hanula, M., Khachatryan, K., & Khachatryan, G. (2023). Nano-/Microcapsules, Liposomes, and Micelles in Polysaccharide Carriers: Applications in Food Technology. Applied Sciences, 13(21), 11610.
[15] Tomadoni, B., Fabra, M. J., Méndez, D. A., Martínez-Abad, A., & López-Rubio, A. (2022). Electrosprayed Agar Nanocapsules as Edible Carriers of Bioactive Compounds. Foods, 11(14), 2093.
[16] Dabholkar, N., Waghule, T., Rapalli, V. K., Gorantla, S., Alexander, A., Saha, R. N., & Singhvi, G.2021. Lipid shell lipid nanocapsules as smart generation lipid nanocarriers. Journal of Molecular Liquids, 339, 117145.
[17] Yan, X., Chai, L., Fleury, E., Ganachaud, F., & Bernard, J.2021. ‘Sweet as a Nut’: Production and use of nanocapsules made of glycopolymer or polysaccharide shell. Progress in Polymer Science, 120, 101429.
[18] Xu, Y., Chen, H., Zhang, L., & Xu, Y.2023. Clove essential oil loaded chitosan nanocapsules on quality and shelf-life of blueberries. International Journal of Biological Macromolecules, 249, 1260-91.
[19] Ahmad, M., & Gani, A.2021. Ultrasonicated resveratrol loaded starch nanocapsules: Characterization, bioactivity and release behaviour under in-vitro digestion. Carbohydrate Polymers, 251, 117111.
[20] Uche, C. I., Tin Wui Wong, Philipp John.2021. Recent Advances in Spray Drying Technology for the Production of Nanoparticles: A Review. Nanoscale Advances, 3(12): 3465-3480.
[21] Deng, S., Gigliobianco, M. R., Censi, R., & Di Martino, P.2020. Polymeric nanocapsules as nanotechnological alternative for drug delivery system: Current status, challenges, and opportunities. Nanomaterials, 10(5): 847.
[22] González-Reza, R. M., Hernández-Sánchez, H., Quintanar-Guerrero, D., Alamilla-Beltrán, L., Cruz-Narváez, Y., & Zambrano-Zaragoza, M. L.2021. Synthesis, controlled release, and stability on storage of chitosan-thyme essential oil nanocapsules for food applications. Gels, 7(4), 212.
[23] Taylor, T. M., Weiss, J., Davidson, P. M., & Bruce, B. D. (2005). Liposomal Nanocapsules in Food Science and Agriculture. Critical Reviews in Food Science and Nutrition, 45(7–8), 587–605.
[24] Guía-García, J. L., Charles-Rodríguez, A. V., Reyes-Valdés, M. H., Ramírez-Godina, F., Robledo-Olivo, A., García-Osuna, H. T., Cerqueira, M. A., & Flores-López, M. L. (2022). Micro and nanoencapsulation of bioactive compounds for agri-food applications: A review. Industrial Crops and Products, 186: 115198.
[25] Aswathi, V. P., Meera, S., Maria, C. G. A., & et al.2023. Green synthesis of nanoparticles from biodegradable waste extracts and their applications: A critical review. Nanotechnology Reviews, 8: 377–397.
[26] De Conto, D., dos Santos, V., Zattera, A. J.2021. Swelling of biodegradable polymers for the production of nanocapsules and films with the incorporation of essential oils. Polymer Bulletin, 78: 7261–7278.
[27] Kothale, D., Verma, U., Dewangan, N., Jana, P., Jain, A., & Jain, D. (2020). Alginate as promising natural polymer for pharmaceutical, food, and biomedical applications. Current Drug Delivery, 17(9): 755-775.
[28] Maleki, G., Woltering, E. J., & Mozafari, M. R.2022. Applications of chitosan-based carrier as an encapsulating agent in food industry. Trends in Food Science & Technology, 120: 88-99.
[29] Tahir, A., Shabir Ahmad, R., Imran, M., Ahmad, M. H., Kamran Khan, M., Muhammad, N., … Javed, M.2021. Recent approaches for utilization of food components as nano-encapsulation: a review. International Journal of Food Properties, 24(1): 1074–1096.
[30] Pateiro, M., Gómez, B., Munekata, P. E. S., Barba, F. J., Putnik, P., Bursać Kovačević, D., & Lorenzo, J. M.2021. Nanoencapsulation of promising bioactive compounds to improve their absorption, stability, functionality, and the appearance of the final food products. Molecules, 26(6): 1547.
[31] Carrillo-Lopez, L. M., Garcia-Galicia, I. A., Tirado-Gallegos, J. M., Sanchez-Vega, R., Huerta-Jimenez, M., Ashokkumar, M., & Alarcon-Rojo, A. D.2021. Recent advances in the application of ultrasound in dairy products: Effect on functional, physical, chemical, microbiological, and sensory properties. Ultrasonics Sonochemistry, 73: 105467.
[32] Tabrizi, S., Mahdian, E., Mohammadi Sani, A., Sarabi -Jamab, M., Oroojalian, F.2022. Investigation of Antimicrobial Properties of Extract and Nano -extract of Arial Organ of Hypericum Perforatum. Journal of Food Science and Technology (Iran), 19(128): 259-270.
[33] Cerro, D., Rojas, A., Torres, A., Villegas, C., Galotto, M. J., Guarda, A., & Romero, J.2023. Nanoencapsulation of food-grade bioactive compounds using a supercritical fluid extraction of emulsions process: Effect of operational variables on the properties of nanocapsules and new perspectives. LWT, 184: 115115.
[34] Sahoo, M., Vishwakarma, S., Panigrahi, C., & Kumar, J.2021. Nanotechnology: Current applications and future scope in food. Food Frontiers, 2(1): 3-22.
[35] Zabot, G. L., Rodrigues, F. S., Ody, L. P., Tres, M. V., Herrera, E., Palacin, H., Córdova-Ramos, J. S., Best, I., & Olivera-Montenegro, L.2022. Encapsulation of bioactive compounds for food and agricultural applications. Polymers, 14(19): 4194.
[36] Chopde, S., Datir, R., Deshmukh, G., Dhotre, A., & Patil, M.2020. Nanoparticle formation by nanospray drying & its application in nanoencapsulation of food bioactive ingredients. Journal of Agriculture and Food Research, 2, Article 100085.
[37] Seyed Hajizadeh, H., Zahedi, S. M., & Rezaie, S.2021. Effect of nano-encapsulation of rosemary in quality preserving and antioxidative activity of apricot (Prunus armeniaca cv. Tabarzeh) during storage life. Iranian Journal of Food Science and Technology, 18(117): 183-196.
[38] Mohebbat Mohebbi.2020. Chapter 11 - Nanoencapsulation of flavors for beverage manufacturing. In A. Amrane, S. Rajendran, T. A. Nguyen, A. A. Assadi, & A. M. Sharoba (Eds.), Nanotechnology in the beverage industry (pp. 317-336). Elsevier.
[39] Cetinkaya, T., & Ayseli, M. T. (2024). A systematic review on nano-delivery systems enriched with aromatic compounds: Flavor, odor, and chemical quality perspectives in fish. Food Chemistry Advances, 5: 100750.
[40] Soleimanpour, M., Taghizadeh, M., & Fathollahi, I.2020. Nanoencapsulation strategies for improving bioavailability and stability of fat-soluble vitamins. Journal of Food Science and Technology, 57(4): 1311-1320.
[41] Sadr, B., Alizadeh, A., Tabibiazar, M., Hamishehkar, H., & Roufegarinejad, L.2023. Evaluation of the stability of VitD3 loaded zein hydrolysate nanocapsules in orange juice by ultrasound and its effect on the properties of orange juice. Journal of Food Science and Technology, 19(1): 17-29.
[42] Ojeda-Piedra, S. A., Zambrano-Zaragoza, M. L., González-Reza, R. M., García-Betanzos, C. I., Real-Sandoval, S. A., & Quintanar-Guerrero, D. (2022). Nano-Encapsulated Essential Oils as a Preservation Strategy for Meat and Meat Products Storage. Molecules, 27(23): 8187.
[43] Yeganeh, S., & Reyhani Poul, S.2023. Use of nanocapsules carrying astaxanthin from Haematococcus microalgae coated by maltodextrin-sodium caseinate as a substitute for sodium nitrite in formulation of common sausage and evaluating microbial and texture properties of the product. Journal of Food Science and Technology, 19(1): 143-159.
[44] Soni, M., Maurya, A., Das, S., Prasad, J., Yadav, A., Singh, V. K., Singh, B. K., Dubey, N. K., & Dwivedy, A. K.2022. Nanoencapsulation strategies for improving nutritional functionality, safety and delivery of plant-based foods: Recent updates and future opportunities. Plant Nano Biology, 1: 100004.
[45] Tiwari, S., & Dubey, N. K.2022. Nanoencapsulated essential oils as novel green preservatives against fungal and mycotoxin contamination of food commodities. Current Opinion in Food Science, 45: 100831.
[46] Zhu, X., Blanco, E., Bhatti, M., & Borrion, A.2021. Impact of metallic nanoparticles on anaerobic digestion: A systematic review. Science of The Total Environment, 757: 143747.
[47] Rubio, L., Barguilla, I., Domenech, J., Marcos, R., & Hernández, A.2020. Biological effects, including oxidative stress and genotoxic damage, of polystyrene nanoparticles in different human hematopoietic cell lines. Journal of Hazardous Materials, 398: 122900.
[48] Rad, L. M., Arellano, G., Podojil, J. R., O’Konek, J. J., Shea, L. D., & Miller, S. D.2024. Engineering nanoparticle therapeutics for food allergy. Journal of Allergy and Clinical Immunology, 153(3): 549-559.
[49] Lobel, B. T., Baiocco, D., Al-Sharabi, M., Routh, A. F., Zhang, Z., & Cayre, O. J.2024. Current challenges in microcapsule designs and microencapsulation processes: A review. ACS Applied Materials & Interfaces, 16(31): 40326-40355.
[50] Elkalla, E., Khizar, S., Tarhini, M., Lebaz, N., Zine, N., Jaffrezic-Renault, N., … Elaissari, A.2023. Core-shell micro/nanocapsules: from encapsulation to applications. Journal of Microencapsulation, 40(3): 125–156.
[51] Mondéjar-López, M., García-Simarro, M. P., Navarro-Simarro, P., Gómez-Gómez, L., Ahrazem, O., & Niza, E.2024. A review on the encapsulation of “eco-friendly” compounds in natural polymer-based nanoparticles as next generation nano-agrochemicals for sustainable agriculture and crop management. International Journal of Biological Macromolecules, 280(3): 136030.
[52] Kumar, S., Bhuvaneshwari, R., Jain, S., Nirwan, S., Fatima, Z., Kumar, D., Chhikara, B. S., Rathi, B., & Poonam.2024. A systematic review on pesticide-loaded nanocapsules: A sustainable route for pesticide management to enhance crop productivity. Current Nanoscience, 20(3): 280-297.
[53] Kala, S., Sogan, N., Naik, S. N.2020. Impregnation of pectin-cedarwood essential oil nanocapsules onto mini cotton bag improves larvicidal performances. Scientific Reports, 10: 14107.
[54] Liu, L.-W., Ding, Z.-H., Ren, G.-G., Wang, G.-D., Pan, X., Wei, G.-H., Zhou, X., Wu, Z.-B., Jin, Z.-C., Chi, Y. R., & Yang, S.2023. Inorganic nanoparticles-driven self-assembly of natural small molecules in water for constructing multifunctional nanocapsules against plant diseases. Chemical Engineering Journal, 475: 146041.
[55] Ives, C.-S., Martins Feitosa, N., Fukushima, H. C. S., Borra, R. C., Foglio, M. A., Pazini Xavier, R. M., de Melo Hoyos, D. C., de Oliveira Sousa, I. M., Galdino de Souza, G., Lacava Bailone, R., de Andrade Belo, M. A., Correia, S. A. M., Dias Corrêa Junior, J., Pierezan, F., & Malafaia, G.2021. Effects of nanocapsules of poly-ε-caprolactone containing artemisinin on zebrafish early-life stages and adults. Science of The Total Environment, 756: 143851.
[56] Budel, R. G., da Silva, D. A., Moreira, M. P., Dalcin, A. J. F., da Silva, A. F., Nazario, L. R., Majolo, J. H., Lopes, L. Q. S., Santos, R. C. V., Soares, F. A. A., da Silva, R. S., Gomes, P., & Boeck, C. R. 2020. Toxicological evaluation of naringin-loaded nanocapsules in vitro and in vivo. Colloids and Surfaces B: Biointerfaces, 188: 110754.
[57] Hérault, N., Wagner, J., Abram, S. L., Widmer, J., Horvath, L., Vanhecke, D., … Fromm, K. M.2020. Silver-Containing Titanium Dioxide Nanocapsules for Combating Multidrug-Resistant Bacteria. International Journal of Nanomedicine, 15: 1267–1281.