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Investigation of Antimicrobial and Synergistic effects of doped Zinc Oxide Nanoparticles against Bacillus cereus

Document Type : Research Article

Author

Department of Food Science, Neyshabur Branch, Islamic Azad University, Neyshabur, Iran

Abstract

Introduction: Metal oxide nanoparticles have unique physical and chemical properties. These components have shown antimicrobial effects against a wide range of microorganisms. In order to improve the physical properties of metal oxide nanoparticles, doping other elements with metal oxide nanoparticles is an effective way. Bacillus cereus is a gram-positive bacteria causing food-borne diseases. In this study, the antimicrobial effects of doped zinc oxide nanoparticles with manganese or iron on Bacillus cereus have been studied. To investigate the synergistic effects of the combined nanoparticles with two common biocides, including hydrogen peroxide and sodium hypochlorite, have been used.
 Materials and methods: Co- precipitation method was used to prepare nanoparticles of manganese-zinc oxide and iron-zinc oxide. In this method, zinc sulfate and manganese sulfate were used to prepare manganese-zinc oxide  and iron sulfate and zinc sulfate are used for Zn- Fe doped nanoparticles. After preparing the sulfate solutions, the sulfate solutions were mixed and placed in an ultrasonic apparatus at a frequency of 57 kHz for 2 hours at 50ºC. Then, it was stirred at 80°C. A solution of NaOH was added until the pH of the solution reached 12. In these conditions, the mixing was done for 30 minutes. The solution was placed at ambient temperature for 18 hours. Then the centrifuge was performed to separate the sediment. Purification was done through washing with distilled water and ethanol. The precipitates were dried in the vacuum oven. In this way, the doped nanoparticles of manganese-zinc oxide and iron-zinc oxide were obtained. The Fourier transform infrared spectrum (FTIR) was carried out by the Perkin-Elmer apparatus of the Spectroma2 model, using a dry potassium bromide tablet at a frequency range of 4500-4000 cm-1. The X-ray diffraction was tested using the Phillips PW1820 from 2º to 80º. Structure of produced nanoparticles was assessed by the HITACHI electron microscope, the H-7500 model, by placing a drop of nanoparticles dissolved in methanol on a special lining with carbon coating and air drying, and performing microscopic images using an electron microscope in 100kv. The bacteria used in this study included Bacillus cereus (PTCC 1665) was purchased from the Iranian Scientific and Industrial Research Center and was transferred to the BHI medium in sterile condition and incubated for 32 hours at a temperature of 32°C. Microbial cells were isolated by centrifugation at 4000 rpm. McFarland's method was used for determining the bacterial population. Dilution was carried out to reach a population of about 106 CFU/ml. Agar disc diffusion method was used for assessing the antimicrobial effect of the doped nanoparticles alone or in combination with tested biocides (hydrogen peroxide, sodium hypochlorite). At first, 106 CFU/ml of Bacillus cereus were inoculated on the surface of Blood Agar. Then, 5, 10, 20, 30, 50, 100 and 200 mg/L of each of the nanoparticles were placed on the surface of the culture medium and then the plates was incubated at 37°C for 24 hours. Inhibition zone was considered as antibacterial activity. In order to investigate synergistic effects, inhibitory fraction index test was calculated. All experiments were performed in three replications. Statistical analyzes were performed using STATISTICA software.
 Results and discussion: Results obtained from X-ray and FTIR analysis of doped nanoparticles confirmed that co- precipitation is a suitable method for producing doped nanoparticles of zinc oxide. TEM analysis of produced nanoparticles also affirm formation of doped nanoparticles of zinc oxide with manganese and iron. The results of antimicrobial tests showed that Mn-Zn oxide nanoparticles have more antimicrobial effects on Bacillus cereus than zinc oxide (32mm inhibition zone) whereas Fe- Zn oxide nanoparticles cause inhibition zone about 12 mm. In addition, both doped nanoparticles have more antimicrobial effects than zinc oxide nanoparticles alone, resulted in doping process improves antimicrobial properties of zinc oxide. The synergistic effects of synthetic nanoparticles in the combination of two common antimicrobial agents, including hydrogen peroxide and sodium hypochlorite, have been identified. Both nanoparticles show synergistic effects in combination with two tested biocides (especially in high concentrations). A mixture of two biocides with nanoparticles increases their antimicrobial properties. Manganese-zinc oxide nanoparticles with hydrogen peroxide and sodium hypochlorite showed a partial synergistic effect at low concentrations (5 + 20) and a complete synergistic effect at higher concentrations. In the case of iron-zinc oxide, combination of this nanoparticle with hydrogen peroxide and sodium hypochlorite, has complete synergistic effects at high concentration (100 + 200) and at other conditions, shows partial synergistic effects.

Keywords

References
Altaf, M.S., Iqbal, A., Ahmad, M., Hussain, S.A., Ahmad, R. and Willayat, M.M. (2012). Study of enterotoxigenicity of B.cereus emetic strain by skin vasopermeability reaction in rabbits and poultry. International Journal of Pharma and Bio Sciences 3(2):166-172.
Amoupour, E., Ghodsi, F.E., Andarva, H., Abdolahzadeh ziabari, A. 2013. Preparation and investigation of optical, structural, and morphological properties of nanostructured ZnO:Mn thin films. Pramana Journal of physics. 81(2): 33-341.
Ansari MA, Khan HM, Khan AA, Cameotra SS, Saquib Q, Musarrat J. Interaction of Al2O3 nanoparticles with Escherichia coli and their cell envelope biomolecules. J Appl Microbiol 2014; 116:772–83.
Baek YW, An YJ. Microbial toxicity of metal oxide nanoparticles (CuO, NiO, ZnO, and Sb2O3) to Escherichia coli, Bacillus subtilis, and Streptococcus aureus. Sci Total Environ 2011; 409:1603–8.
Bayanduri Moghaddam A, et al. Comparative study of antimicrobial activities of TiO2 and CdO nanoparticles against the pathogenic strain of Escherichia coli. Iran J Pathol 2010; 5:83–9.
Chauhan R, Reddy A, Abraham J. Biosynthesis of silver and zinc oxide nanoparticles using Pichia fermentans JA2 and their antimicrobial property. 2015. J Appl Nanosci .5:63–71.
Corr SA. Metal oxide nanoparticles. Nanoscience 2013;1:180–234.
Dong, X., Koo, Y., Tang, Y., Yun, Y., Yang, Y. 2015. Superior Antibacterial Activity of Photochemical Synthesized Ag-CNT Composites and their Synergistic Effects in Combination with other Antimicrobial Agents. J Nanomed Nanotechnol 2015, 6(3): 1-7.
Fernandez-Garcia M, Martinez-Arias A, Hanson JC, Rodriguez JA. Nanostructured oxides in chemistry: characterization and properties. Chem Rev 2004;104:4063–104.
Ghahfarokhi, S.A., Naji, T., Mazdapour, M., Kazemi, A.,T ajehmiri,A. 2014. Antibacterial effect of silver nanoparticles on Bacillus cereus. International Journal of Basic Biosciences. 2(2): 6-11.
Gupta K, Singh RP, Pandey A, Pandey A. 2013. Photocatalytic antibacterial performance of TiO2 and Ag-doped TiO2 against S. aureus, P. aeruginosa and E. coli. Beilstein J Nanotechnol .4:346–51.
Hameed ASH, Karthikeyan C, Sasikumar S, Kumar VS, Kumaresan S, Ravi G. Impact of alkaline metal ions Mg2+, Ca2+, Sr2+ and Ba2+ on the structural, optical, thermal and antibacterial properties of ZnO nanoparticles prepared by the co-precipitation method. J Mater Chem B 2013;1:5950.
Jassim AM, Farhan SA, Salman JA, Khalaf KJ, Al Marjani MF, Mohammed MT. Study the antibacterial effect of bismuth oxide and tellurium nanoparticles. Int J Chem Biol Sci 2015;1:81–4.
Kumar KA, Mazumdar K, Dutta NK, Karak P, Dastidar SG, et al., 2004 Evaluation of synergism between the aminoglycoside antibiotic streptomycin and the cardiovascular agent amlodipine. Biological & Pharmaceutical Bulletin 27: 1116-1120.
Malka E, Peralshtein I, Lipovsky A, Shalom Y, Naparstek L, Perkas N, et al. 2013.Eradication of multi-drug resistant bacteria by a novel Zn-doped CuO nanocomposite. Small. 9:4069–76.
Mirhosseini, M., Barzegari Firouzabadi, F. 2015. Reduction of Listeria monocytogenes and Bacillus cereus in Milk by Zinc Oxide Nanoparticles. Iranian Journal of Pathology. 10(2): 97-104.
Mukhtar, M., Munisa, L., Saleh, R. 2012. Co-Precipitation Synthesis and Characterization of Nanocrystalline Zinc Oxide Particles Doped with Cu2+ Ions. Materials Sciences and Applications. 3, 543-551
Muneer M. Ba-Abbad, Abdul Amir H. Kadhum, Abu Bakar Mohamad, Mohd S. Takriffand Kamaruzzaman Sopian. 2013. The effect of process parameters on the size of ZnO nanopartic synthesized via the sol-gel technique. Journal of Alloys and Compounds. 8: 63-70.
Muthukumaran, S., Gopalakrishnan, R. 2012. Structural, FTIR and photoluminescence studies of Cu doped ZnO nanopowders by co-precipitation method. Optical Materials 34:1946–1953.
Poloju, M., Jayababu, N., Ramana Reddy, M.V.2018. Improved gas sensing performance of Al doped ZnO/CuO nanocomposite based ammonia gas sensor. Materials Science & Engineering B 227 (2018) 61–67.
Raghunath, A., Perumal, E. 2017. Metal oxide nanoparticles as antimicrobial agents: a promise for the future. International Journal of Antimicrobial Agents 49: 137–152.
Raja, K., P.S. Ramesh, D. Geetha, Structural, FTIR and photoluminescence studies of Fe doped ZnO nanopowder by co-precipitation method. 2014. Spectrochem. Acta A – Mol. Biomol. Spectrosc. 131: 183–188.
Roks G, Deckers CL, Meinardi H, Dirksen R, van Egmond J, et al. 1999 Effects of polytherapy compared with monotherapy in antiepileptic drugs: an animal study. J Pharmacol Exp Ther 288: 472-477.
Sawai J, Kojima H, Igarashi H, Hashimoto A, ShojiS, Sawaki T, et al. Antibacterial characteristics of magnesiumoxide powder. World J Microbiol Biotechnol; 2000. 16(2):187-94.
Sharma, N., Jandaik, S., Kumar, S., Chitkara, M., Singh Sandhu, I. 2015. Synthesis, characterization and antimicrobial activity of manganese- and iron-doped zinc oxide nanoparticles. Journal of Experimental Nanoscience. 11:1, 54-71
Sood, B., Pal Sahota, P., Hunjan, M. 2017. Multidrug Resistant Bacillus cereus in Fresh Vegetables: A Serious Burden to Public Health. Int.J.Curr.Microbiol.App.Sci. 6(4): 649-661.
Srinivasulu, T., Saritha, K., Ramakrishna Reddy, K.T. 2017. Synthesis and characterization of Fe-doped ZnO thin films deposited by chemical spray pyrolysis. Modern Electronic Materials 3: 76–85
Tran N, Mir A, Mallik D, Sinha A, Nayar S, Webster TJ. Bactericidal effect of iron oxide nanoparticles on Staphylococcus aureus. Int J Nanomedicine 2010; 5:277–83.
Whitesides GM. Nanoscience, nanotechnology, and chemistry. Small 2005; 1:172–9.
Yolmeh M, Habibi-Najafi M B, Najafzadeh M. 2015. Study the effects of ultraviolet radiation on the growth of Escherichia coli and Bacillus cereus isolated from raw milk and raw rice Iranian Food Science and Technology Research Journal; 4: 319-324.
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Iranian Food Science and Technology Research Journal
Volume 15, Issue 2 - Serial Number 56
May and June 2019
Pages 257-266
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History
  • Receive Date: 27 May 2018
  • Revise Date: 19 July 2018
  • Accept Date: 01 November 2018
  • First Publish Date: 22 May 2019
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