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American Journal of Food and Nutrition
ISSN (Print): 2374-1155 ISSN (Online): 2374-1163 Website: https://www.sciepub.com/journal/ajfn Editor-in-chief: Mihalis Panagiotidis
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Issue 2, Volume 11
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American Journal of Food and Nutrition. 2023, 11(2), 55-58
DOI: 10.12691/ajfn-11-2-4
Open AccessArticle

The Effect of a Natural Physical Field of Nano Silica on Preserving Food Safety, and Security

Hesham Mohamed Abdal-Salam Yehia1, and Said Mahmoud Said2

1Department of Biotechnology, HST Company, Cairo, Egypt

2Department of Biotechnology, HST Company

Pub. Date: August 03, 2023
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Cite this paper:
Hesham Mohamed Abdal-Salam Yehia and Said Mahmoud Said. The Effect of a Natural Physical Field of Nano Silica on Preserving Food Safety, and Security. American Journal of Food and Nutrition. 2023; 11(2):55-58. doi: 10.12691/ajfn-11-2-4

Abstract

Nano silica is a type of nanomaterial that is composed of very small particles of silicon dioxide. Due to their small size, nano silica particles have unique properties that make them potentially useful in a variety of applications, including food preservation. When used in food, nano silica can act as an anti-caking agent, a carrier for flavors and nutrients, and a coating or packaging material to prevent spoilage. This study explores the potential of nano silica, a type of nanomaterial, to preserve food safety and security. The method involves the preparation of nano silica particles from a reliable commercial source and the characterization of these particles using techniques e.g., scanning electron microscopy (SEM), and transmission electron microscopy (TEM). Nano silica has been shown to inhibit the growth of microorganisms and have antioxidant properties that can extend the shelf life of food. This study confirms that nano silica can help to preserve food safety and security by inhibiting the growth of bacteria and other microorganisms that can cause foodborne illness. Nano silica particles can penetrate the cell walls of microorganisms, disrupting their cellular processes. In addition, nano silica has been found to have antioxidant properties that can help to prevent the oxidation of fats and oils in food. This can help to extend the shelf life of foods that are prone to spoilage due to lipid oxidation, such as nuts, seeds, and oils.

Keywords:
Food safety Silica nanoparticles Food security Sustainable Development Goals (SDGs)

Creative CommonsThis work is licensed under a Creative Commons Attribution 4.0 International License. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/

References:

[1]  Bajpai, V. K., Kamle, M., Shukla, S., Mahato, D. K., Chandra, P., Hwang, S. K., ... & Han, Y. K. (2018). Prospects of using nanotechnology for food preservation, safety, and security. Journal of food and drug analysis, 26(4), 1201-1214.‏
 
[2]  Rhazi, L., Depeint, F., & Ayerdi Gotor, A. (2022). Loss in the intrinsic quality and the antioxidant activity of sunflower (Helianthus annuus L.) oil during an industrial refining process. Molecules, 27(3), 916.‏
 
[3]  Gupta, V., Mohapatra, S., Mishra, H., Farooq, U., Kumar, K., Ansari, M. J., ... & Iqbal, Z. (2022). Nanotechnology in cosmetics and cosmeceuticals—A review of latest advancements. Gels, 8(3), 173.‏
 
[4]  Onyeaka, H., Passaretti, P., Miri, T., & Al-Sharify, Z. T. (2022). The safety of nanomaterials in food production and packaging. Current Research in Food Science, 5, 763-774.‏
 
[5]  Dheyaaldin, M. H., Mosaberpanah, M. A., & Alzeebaree, R. (2022). Performance of fiber-reinforced alkali-activated mortar with/without nano silica and nano alumina. Sustainability, 14(5), 2527.‏
 
[6]  Daniel, A. I., Fadaka, A. O., Gokul, A., Bakare, O. O., Aina, O., Fisher, S., ... & Klein, A. (2022). Biofertilizer: the future of food security and food safety. Microorganisms, 10(6), 1220.‏
 
[7]  Manzoor, A., Khan, S., Dar, A. H., Pandey, V. K., Shams, R., Ahmad, S., ... & Pandiselvam, R. (2023). Recent insights into green antimicrobial packaging towards food safety reinforcement: A review. Journal of Food Safety, e13046.‏
 
[8]  Yehia, H. M. A. S., & Said, S. M. (2021b). Drinking water treatment: pH adjustment using natural physical field. Journal of Biosciences and Medicines, 9(6), 55-66.
 
[9]  Gayathiri, K., & Praveenkumar, S. (2023). Elucidating the effects of dispersion methods on agglomerated nano silica particles in aqueous environment. Materials Today: Proceedings.
 
[10]  Nigam, M., & Verma, M. (2023). Effect of nano-silica on the fresh and mechanical properties of conventional concrete. Forces in Mechanics, 10, 100165.
 
[11]  Zhou, Y., Li, L., Han, K., Wang, L., Cao, Y., Ma, D., & Wang, X. (2022). A polyvalent broad-spectrum Escherichia phage Tequatrovirus EP01 capable of controlling Salmonella and Escherichia coli contamination in foods. Viruses, 14(2), 286.‏
 
[12]  Javanmardi, Z., Saba, M. K., Nourbakhsh, H., & Amini, J. (2023). Efficiency of nanoemulsion of essential oils to control Botrytis cinerea on strawberry surface and prolong fruit shelf life. International Journal of Food Microbiology, 384, 109979.‏
 
[13]  Shah, M. Z. U., Sajjad, M., Hou, H., ur Rahman, S., & Shah, A. (2022). Copper sulfide nanoparticles on titanium dioxide (TiO2) nanoflakes: a new hybrid asymmetrical Faradaic supercapacitors with high energy density and superior lifespan. Journal of Energy Storage, 55, 105651.‏
 
[14]  Yehia, H. M., & Said, S. M. (2021a). Effects of the addition of titanium dioxide; sodium silicate and silica nanoparticles on the elimination of bacteria and viruses in a physical field. Am J Biomed Res, 9(2), 24-29.‏
 
[15]  Uikey, P., & Vishwakarma, K. (2016). Review of zinc oxide (ZnO) nanoparticles applications and properties. International Journal of Emerging Technology in Computer Science & Electronics, 21(2), 239-42.‏
 
[16]  Vinodh, R., Sasikumar, Y., Kim, H. J., Atchudan, R., & Yi, M. (2021). Chitin and chitosan based biopolymer derived electrode materials for supercapacitor applications: A critical review. Journal of Industrial and Engineering Chemistry, 104, 155-171.‏
 
[17]  Solans, C., Izquierdo, P., Nolla, J., Azemar, N., & Garcia-Celma, M. J. (2005). Nano-emulsions. Current opinion in colloid & interface science, 10(3-4), 102-110.‏
 
[18]  Nandiyanto, A. B. D., Kim, S. G., Iskandar, F., & Okuyama, K. (2009). Synthesis of spherical mesoporous silica nanoparticles with nanometer-size controllable pores and outer diameters. Microporous and Mesoporous Materials, 120(3), 447-453.‏
 
[19]  Yehia, H. M. A. S., Said, S. M., & Ragb, N. G. E. R. (2022). Silica nanoparticles in targeted human cancer therapy. Medical Journal of Cell Biology, 10(1), 7-17.‏
 
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