Nanomaterials for the inhibition of microbial growth on ancient egyptian funeral masks

Part of : Mediterranean archaeology & archaeometry : international journal ; Vol.15, No.3, 2015, pages 87-95

Issue:
Pages:
87-95
Author:
Abstract:
Funeral masks were manufactured in ancient Egypt since several periods ago. They consist of one or more material such as wood, textile, gypsum, faience, silver and gold. They were exposed to microbiological infections from the surrounding environmental conditions such as fungi and bacteria, which caused various deterioration aspects : stains, disintegration, discoloration, cracking, and may promote the decay of funeral masks. In the last few years, nanoparticles have widely been used in treatment and conservation of artifacts. In this paper, the antimicrobial activities of nanomaterials silver, titanium dioxide and copper II oxide, were evaluated against the fungal strain of Aspergillus niger, Aspergillus flavus, Aspergillus fumigatus and the bacterial strain of Bacillus alvei, Gthe short Bacilli, and Gthe Bacilli spore former. Transmission electron microscope TEM, and scanning electron microscope SEM attached with energy dispersive X-ray spectrometer EDX unit were utilized for characterization of nanoparticles. The data showed that silver nanoparticles are the best effective one for inhibition the growth of both isolated fungi and bacteria. It was applied for treatment and conservation of three ancient Egyptian funeral masks in saqqara, Egypt.
Subject:
Subject (LC):
Keywords:
Nanomaterials, Funeral masks, Biodeterioration, microbial inhibition, Fungi, Bacteria
Notes:
Corresponding author: [email protected]
References (1):
  1. Allaker, R.P., Vargas-Reus, M.A., and Ren, G.G., (2012) Nanometals as Antimicrobials, in Antimicrobial Polymers,Wiley & Sons, Inc., first Edition, 328-338Altavilla, C., and ciliberto, E., (2011) Inorganic Nanoparticles: Synthesis, Applications, and Perspectives, Taylorrand franicis group, LIC, 380,381Brantner, A., Peiffer, K.P., and Grein, E., (1993), Antibacterial assays of the pharmacopoeias: diffusion tests ofnutural substances and evaluation. J. Planta Med. 597: 675.Chauhan,R., Abhishek, K., and Abraham, J., (2013) A Biological approach to the synthesis of silver nanoparticleswith Streptomyces sp. JAR1 and its antimicrobial activity, Scientia Pharmaceutica 81: 607-621Cowan, S. T., and Steels, (1974), Manual for the Identification of medical bacteria, 2nd Ed. Cambridge Univ.Press, 51-180.Damm, c., Munstedt, H., Rosch, a., (2008) Antimicrobial efficacy of Polyamide Silver nano and nanocomposites,Mater. Chem. Phys. J., No.108, 61-66.Difco, (1984) Manual of dehydrated culture media and reagents for microbiological and clinical laboratoryprocedures, Difco Laboratory Incorporated (10th Edition), Detroit, Michigan, USA, 689-691Domsch, K.H., Gams, W., and Anderson, T.H. (1980), Compendium of soil fungi. Vol.2, Academic press publisher,London, New York, Toronto, Sydney, San Francisco, 541-747.Egorova, E.M., (2010) Biological Effects of silver nanoparticles, in Silver Nanoparticles : Properties, characterizationand Applications, Nova Science Publishers, Inc., 221-225Gilman., J. C. (1974). A manual of Soil Fungi. Indian Edition published by arrangement with the originalAmerican publishers Iowa State University press, U.S.A, 217-251.Ikram, S. and Dodson, D. (1998) The Mummy in ancient Egypt, Equipping The Dead for Eternity, The AmericanUniversity in Cairo Press, 166Ing, L.Y., Zin, N.M., Sarwar, A., and Katas, H., (2012), Antifungal activity of chitosan nanoparticles and correlationwith their physical properties, International Journal of Biomaterials, Volume 2012, ArticleID 632698, 9 pagesJohnson, C., Gill, A.; Miller, E., and Hignett, K., (1997) Aspects of consolidation from Portraits and masks, BritishMuseum Press, 100Kubacka, A., et al., (2014), Understanding the antimicrobial mechanism of TiO2-based nanocomposites filmsin a Pathogenic bacterium, Nature, Scientific Reports Journal, Vol.4., Article No. 4134,doi:10.1038/srep04134, ISSN (online): 2045-2322Kumar chatterjee, A., Chakraborly R., and Busu T., (2014), Mechanism of antibacterial activity of copper nanoparticles,Nanotechnology Journal, vol. 25 no. 13, , IOP Publishing Ltd,doi:10.1088/25/13/135101, ISSN (online): 0957-4484Kumar, H., Raj Kumar S., and Purewal S., (2014), Antibacterial activity of copper oxide nanoparticles againstgram negative bacterial strain synthesized by reverse Micelle technique Intern. J. of Pharmaceuticalresearch and Development, vol. 6(01), 72-78.Li, WR., Xie, XB., Shi, QS., Zeng, HY., OU-Yang, Y.S., and Chen, YB., (2010) Antibacterial activity and mechanismof silver nanoparticles on Escherichia coli, Appl Microbiol Biotechnol 85: 1115-1122Maliszewska, I., (2011), Microbial synthesis of metal nanoparticles, chapter 7 in Metal nanoparticles in microbiology,Rai, M., and Duran, N., (editors), Springer-Verlag Berlin Heidelberg, DOI 10.1007/978-3-642-18312-6_7, 153-175Martinez – gutierrez, F., Olive, P.L., Banuelos, A., et al., (2010), Synthesis, Characterization and evaluation ofantimicrobial and cytotoxic effect of silver and titanium nanoparticles, Nanomedicine: Nanotechnology,Biology and medicive, vol. 6, no. 5, 681-688.Narollahi, A., Poursham sian Kh., Masourkiaee, P., (2011), Antifungal activity of silver nanoparticles onsome of fungi, Inten. J. Nano. Dim I (3), 233-239.Pullit J., Banech, M., Szczyglowska, R., and Bryk, M., (2013), Nanosilver against fungi. Silver nanoparticles asan effective biocidal factor, Acta Biochemica Pelonica ABP, vol. 60 No. 4, 795-798.Redford, D.B.(2001) The Oxford Encyclopedia of Ancient Egypt, The American University in Cairo press,Vol. 2 , 345-347Saraniya Devi, J., and Valentin Bhimba, B., (2014), Antibacterial and antifungal activity of silver nanoparticlessynthesized using Hypnea unciformis. Biosciences Biotechnology Research Asia, vol. 11 (1),235-238.Sharma, V.K., Yngard, R.A., and Lin, Y., (2009) Silver nanoparticles: Green synthesis and their antimicrobialactivities, Advances in colloid and Interface Science 145, 83-96Sintubin, L., Verstraete, W., and Boon, N., (2012) Biologically produced nanosilver: current state and futureperspectives, Biotechnology and Bioengineering, Vol. 109, No.10, Wiley Periodicals, Inc., 2422-2436Sterflinger, K., (2010), Fungi, their role in deterioration of cultural heritage, fungal bio. Review 24, 47-55Walker, S.; Bierbrier, M.; Roberts, P., and Taylor, J., (1997), Ancient Faces, Mummy Portraits From RomanEgypt, British Museum press, Third Imprission, 10-13Wang, Z., Chen, J., Li, X., Shao, J., Peijnenburg, W., (2012), Aquatic toxicity of nanosilver colloids to differentTrophic organisms: Contributions of particles and free silver ion, Environmental Toxicology andChemistry, Vol.31,No.10, 2408-2413Zhang, X, Υan, S., Tyagim R.D., Surampalli, R.y., (2011), Synthesis of nanoparticles by microorganisms andtheir application in enhancing microbiological reaction rates, Chemosphere 82, 489-494