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Antimicrobial Potentials of Iron Oxide and Silver Nanoparticles Green-Synthesized in Fusarium solani | ||
| Journal of Chemical Health Risks | ||
| دوره 13، شماره 1، خرداد 2023، صفحه 95-104 اصل مقاله (587.68 K) | ||
| نوع مقاله: Original Article | ||
| شناسه دیجیتال (DOI): 10.22034/jchr.2021.1928198.1293 | ||
| نویسندگان | ||
| Masoomeh Sasani1؛ Ebrahim Fataei* 1؛ Reza Safari1، 2؛ Fatemeh Nasehi1؛ Marzieh Mosayyebi1 | ||
| 1Department of Environment, Ardabil Branch, Islamic Azad University, Ardabil, Iran | ||
| 2Caspian Sea Ecology Research Center, Iranian Fisheries Research Institute, Agricultural Research, Education and Extension Organization, Sari, Iran | ||
| چکیده | ||
| The current study aimed to synthesize, characterize and determine the antibacterial activity of iron oxide (Fe3O4 NPs) and silver nanoparticles (AgNPs) green-synthesized using Fusarium solani. Fungal mass was applied to produce NPs, followed by analyzing NPs using scanning electron microscopy, X-ray diffraction, and Fourier transform infrared spectroscopy. Theantimicrobial test was performed by the agar well diffusion method and the microdilution protocol (determining the minimum inhibitory concentration or MIC and the minimum bactericidal concentration or MBC) against Staphylococcus aureus, Bacillus cereus, Pseudomonas aeruginosa and Escherichia coli. The highest optical densities for produced AgNPs and Fe3O4 NPs were detected at 420 and 215 nm, with a spherical shape and size of 27.5-58.3 nm and a cubic-spherical shape and size of 55.3-84.2 nm, respectively. Ag NPs had more antibacterial activity than Fe3O4 NPs, but they were not significantly different in most cases. The most sensitive and resistant bacteria were S. aureus and P. aeruginosa for both NPs, with the MIC of 10 and 40 μg ml-1 as well as the MBC of 20 and 80 μg ml-1 for Ag NPs against S. aureus and P. aeruginosa, respectively. The results were weaker for Fe3O4 NPs than for Ag NPs, with the MIC of 20 μg ml-1 for B. cereus and S. aureus, and 40 μg ml-1 for P. aeruginosa and E. coli, with the MBC of 40 and 80 μg ml-1, respectively. The antibacterial properties of the produced NPs indicated that these antimicrobial agents were highly reactive and prevented the growth of unwanted microorganisms. | ||
| کلیدواژهها | ||
| Green Synthesis؛ Silver Nanoparticles؛ Iron Oxide Nanoparticles؛ Fusarium solani؛ Antibacterial Properties | ||
| مراجع | ||
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1. Singh P., Singh H., Kim Y.J., Mathiyalagan R., Wang C., Yang D.C., 2016. Extracellular synthesis of silver and goldnanoparticles by Sporosarcina koreensis DC4 andtheir biological applications. Enzyme Microb Technol. 86, 75-83.
2. Kaviya S., Santhanalakshmi J., Viswanathan B., Muthumary J., Srinivasan K., 2011. Biosynthesis of silver nanoparticlesusing citrus sinensis peel extract and itsantibacterial activity. Spectrochim Acta Mol Biomol Spe. 79, 594-98.
3. Kim S.H., Lee H.S., Ryu D.S., Choi S.J., Lee D.S., 2011. Antibacterial activity of silver-nanoparticles againstStaphylococcus aureus and Escherichia coli. Korean J Microbiol Biotechnol. 39(1), 77-85.
4. Sundaram P.A., Augustine R., Kannan M., 2012. Extracellular Biosynthesis of Iron Oxide Nanoparticles by Fusarium solani Strains Isolated from Rhizosphere Soil. Biotechnology and Bioprocess Engineering. 17, 835-840.
5. Jianrong C., Yuqing M., Nongyue H., Xiaohua W., Sijiao L., 2004. Nanotechnology andbiosensors. Biotech Adv. 22, 505-18.
6. Nanda A., Saravanan M., 2009. Biosynthesis of silver nanoparticles from Staphylococcus aureus and its antimicrobialactivity against MRSA and MRSE. Nanomedicine. 5(4), 452-456.
7. Ahmad A., Mukherjee P., Senapati S., Mandal D., Islam Khan M., Kumar R., 2003. Extracellular biosynthesis of silvernanoparticles using the fungus Fusarium oxysporum. Colloids Surf B Biointerfaces. 28(4), 313-318.
8. Pourali P., Baseri Salehi M., Afsharnezhad S., Behravan J., 2013. Biological production and assessment of the antibacterial activity of gold nanoparticles. Journal of Microbial World. 6(3), 198-211.
9. Husseiny S.M., Salah T.A., Anter H.A., 2015. Biosynthesis of size controlled silver nanoparticles by Fusarium oxysporum, their antibacterial and antitumor activities. Beni-Suef University Journal of Basic and Applied Sciences. 4, 225-231.
10. Tabassum Khan N.T., Jameel M., Jameel J., 2017. Silver Nanoparticles biosynthesis by Fusarium oxysporum and determination of its antimicrobial potency. J Nanomedine Biotherapeutic Discov. 7(1), 1-3.
11. Mahmoud W.M., Abdelmoneim T.S., Elazzazy A.M., 2015. The impact of silver nanoparticles produced by Bacilluspumilus as antimicrobial and nematicide. Frontiers in Microbiology. 7, 1-9.
12. Maghsoudy N., Aberoomand Azar P., Saber Tehrani M., 2019. Biosynthesis of Ag and Fe nanoparticles using Erodium cicutarium; study, optimization, and modeling of the antibacterial properties using response surface methodology. Journal of Nanostructure in Chemistry. 9, 203–216.
13. Garmasheva I., KovalenkoN., VoychukS., 2016. Lactobacillus species mediated synthesis of silver nanoparticles and their antibacterial activity against opportunistic pathogens in vitro. BioImpacts. 6(4), 219-223.
14. Omrani M., Fataei E., 2018. Synthesizing Colloidal Zinc Oxide Nanoparticles for Effective Disinfection; Impact on the Inhibitory Growth of Pseudomonas aeruginosa on the Surface of an Infectious Unit, Pol. J Environ Stud. 27(4), 1639-1645.
15. Gudikandula K., Charya Maringanti S., 2016. Synthesis of silver nanoparticles by chemical and biological methods and their antimicrobial properties, Journal of Experimental Nanoscience. 11(9), 714-721.
16. Begam J.N., 2016. Biosynthesis and characterization of silver nanoparticles (AgNPs) using marine bacteria against certain human pathogens. J. Nasrin /International Journal of Advances in Scientific Research. 2(7), 152-156.
17. Ghani S., Rafiee B., Sadeghi D., Ahsani M., 2017. Biosynthesis of Iron Nano-Particles by Bacillus Megaterium and Its Anti-Bacterial Properties. J Babol Univ Med Sci. 19(7), 13-19.
18. Abdul Fatima R., Subhi H.T., Taher N.A., 2019. Activity of Iron oxide nanoparticles on bacterial biofilm formation. Journal of pharmaceutical Sciences and Research. 11(3), 1126-1130.
19. Matei A., Matei S., Matei G.M., 2020. Biosynthesis of silver nanoparticles mediated by culture filtrate of lactic acid bacteria, characterization and antifungal activity. Research Article Pharmaceutical Biotechnology. 4(2), 97-103.
20. John M.S., Nagoth J.A., Ramasamy A.M., 2020. Synthesis of Bioactive Silver Nanoparticles by a Pseudomonas Strain Associated with the Antarctic Psychrophilic Protozoon Euplotes focardii. Marine Drugs. 18(38), 1-13.
21. Çelik S., Oltulu M., Jafarian Barough M., Mohammadi Aloucheh R., 2021. Application of Nanomaterials for Increase of Compressive Strength on Granular Soils to Attain Minimal Damage to the Environment, Anthropogenic Pollution. 5(1), 105-111.
22. Vanaja M., Annadurai G., 2013. Coleus aromaticus leaf extract mediated synthesis of silver nanoparticles and its bactericidal activity. Appl Nanosci. 3, 217–223.
23. Das J., Das M.P., Velusamy P., 2013. Sesbania grandiflora leaf extract mediated green synthesis of antibacterial silver nanoparticles against selected human pathogens. Spectrochim Acta Part A Mol Biomol Spectrosc. 104, 265-270.
24. Singh D., Rathod V., Ninganagouda S., Hiremath J., Singh A.K., Mathew J., 2014. Optimization and characterization of silver nanoparticle by endophytic fungi Penicillium sp. isolated from Curcuma longa (turmeric) and application studies against MDR Escherichia coli and Staphylococcus aureus. Hindawi Publish Corpor Bioinorg Chem Appl. 2014, 1-8.
25. Magdi H.M., Mourad M.H.E., Abd El-Aziz M.M., 2014. Biosynthesis of silver nanoparticles using fungi and biological evaluation of mycosynthesized silver nanoparticles. Egypt J Exp Biol. 10(1), 1–12.
26. Cho K.H., Park J.E., Osaka T., Park S.G., 2005. The study of antimicrobial activity and preservative effects of nanosilver ingredient. Elecrtochemica Acta. 51(5), 956-960.
27. Panyala N.R., Pena-Mendez E.M., Havel J., 2008. Silver or silver nanoparticles: a hazardous threat to the environment and human health. J Appl Biomed. 6(3), 117–129.
28. Safarkar R., Ebrahimzadeh Rajaei G., Khalili-arjaghi S., 2020. The study of antibacterial properties of iron oxide nanoparticles synthesized using the extract of lichen Ramalina sinensis. Asian Journal of Nanoscience and Materials. 3, 157-166.
29. Khalili Arjaghi S., Kashfi Alasl M., Sajjadi N., Fataei E., Ebrahimzadeh Rajaei G., 2021. Green Synthesis of Iron Oxide Nanoparticles by RS Lichen Extract and its Application in Removing Heavy Metals of Lead and Cadmium, Biological Trace Element Research. 199(2), 763-768.
30. Khalili Arjaghi S., Ebrahimzadeh Rajaei G., Sajjadi N., Kashfi Alasl M., Fataei E., 2020. Removal of Mercury and Arsenic Metal Pollutants from Water Using Iron Oxide Nanoparticles Synthesized from Lichen Sinensis Ramalina Extract. Journal of Health. 11(3), 397-408.
31. Ebrahimzadeh Rajaei G., Khalili Arjaghi S., Fataei E., Sajjadi N., Kashfi Alasl M., 2020. Fabrication and characterization of polymer-based nanocomposite membrane modified by magnetite nanoparticles for Cd and Pb removal from aqueous solutions, Comptes Rendus. Chimie. 23(9-10), 563-574.
32. Rajaei G.E., Aghaie H., Zare K., Aghaie M., 2013. Adsorption of Cu (II) and Zn (II) ions from aqueous solutions onto fine powder of Typha latifolia L. root: kinetics and isotherm studies, Research on Chemical Intermediates. 39(8), 3579-3594.
33. Ebrahimzadeh Rajaei G., Aghaie H., Zare K., Aghaie M., 2021. Adsorption of Ni (II) and Cd (II) ions from aqueous solutions by modified surface of Typha latifolia L. root, as an economical adsorbent. Journal of Physical & Theoretical Chemistry. 9, 137-147. 34. Rezaei-Aghdam E., Shamel A., Khodadadi-Moghaddam M., Rajaei G.E., Mohajeri S., 2021. Synthesis of TiO2 and ZnO Nanoparticles and CTAB-Stabilized Fe3O4 nanocomposite: kinetics and thermodynamics of adsorption. Research on Chemical Intermediates. 47, 1759-1774. 35. Nokandeh M., Khoshmanesh B., 2019. Removal of Acid Yellow-36 Dye from textile industries waste water using photocatalytic process (UV/TiO2), Anthropogenic Pollution Journal. 3(2), 10-17.
36. Gooran Ourimi H., Nezhadnaderi M., 2020. Comparison of the application of Heavy metals adsorption methods from aqueous solutions for development of sustainable environment, Anthropogenic Pollution Journal. 4(2), 15-27.
37. Sadr S., Ershad Langroudi A., Nejaei A., Rabiee A., Mansouri N., 2021. Arsenic and Lead Removal from Water by Nano-photocatalytic Systems (A Review). Anthropogenic Pollution Journal. 5(1), 72-80.
38. Rashtbari Y., Américo-Pinheiro J.H.P., Bahrami S., Fazlzadeh M., Arfaeinia H., Poureshgh Y., Efficiency of zeolite coated with zero-valent iron nanoparticles for removal of humic acid from aqueous solutions. Water, Air, & Soil Pollution. 231 (10), ISSN 0049-6979 (In Press).39. Rashtbari Y., Afshin S., Hamzezadeh A., Abazari M., Poureshgh Y., Fazlzadeh M., 2020. Application of powdered activated carbon coated with zinc oxide nanoparticles prepared using a green synthesis in removal of Reactive Blue 19 and Reactive Black-5: adsorption isotherm and kinetic models, Desalination & Water Treatment. 179, 354-367.
40. Ali I., Afshinb S., Poureshgh Y., Azari A., Rashtbari Y., Feizizadeh A., Hamzezadeh A., Fazlzadeh M., 2020. Green preparation of activated carbon from pomegranate peel coated with zero-valent iron nanoparticles (nZVI) and isotherm and kinetic studies of amoxicillin removal in water. Environmental Science and Pollution Research. 27, 36732–36743. | ||
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