Investigation on surface and biological properties of silver containing diamond like carbon films on polyethylene terephthalate film surface by hybrid reactive sputtering method: Unterschied zwischen den Versionen

Aus Kompetenzportal
Wechseln zu: Navigation, Suche
(Die Seite wurde neu angelegt: „{{Artikel Infobox |Autor=K. N. Pandiyaraj, J. Heeg, Ch. Mewes, Marion Wienecke, T. Barfels, V. Uthayakumar, Pi-Guey Su |In=Key Engineering Materials |Ausgabe=…“)
 
(kein Unterschied)

Aktuelle Version vom 29. September 2014, 13:07 Uhr

Investigation on surface and biological properties of silver containing diamond like carbon films on polyethylene terephthalate film surface by hybrid reactive sputtering method
Autor K. N. Pandiyaraj, J. Heeg, Ch. Mewes, Marion Wienecke, T. Barfels, V. Uthayakumar, Pi-Guey Su
In: Key Engineering Materials
Ausgabe 521
ISBN/ISSN:
Erscheinungsjahr 2012
Jahrgang
Seitenzahl 191-205
Hyperlink http://www.scientific.net/KEM.521.191
Review anderes

Silver containing diamond like carbon films were coated on the surface of polyethylene film (PET) using novel hybrid sputtering method. Polymeric substrates can create soft, flexible, highly absorbent and cost-effective materials by selecting or controlling their molecular structures. The material silver is known to be a potential antibacterial material. The silver containing coating has been potentially recommended for synthesis biomedical materials. In the present work, we discussed the antibacterial activity of the silver containing DLC film coated PET film surfaces which was coated as a function of deposition power level. The surface morphology of the Ag-DLC was analysed by atomic force microscopy (AFM) and scanning electron microscopy (SEM). The atomic concentration and structure of the Ag-DLC was measured by energy dispersive X-ray (EDX) and Raman spectroscopy. The hydrophilicity of the films was measured by contact angle analysis. The antibacterial activity of Ag–DLC films were evaluated by bacterial eradication tests with Escherichia coli at incubation time of one day. In addition, blood compatibility of the Ag-DLC films were studied by In Vitro blood compatibility tests. It was found that the surface of the obtained Ag-DLC decreases with increasing the deposition power level. The antibacterial and hemocompatibility of the silver containing DLC film increase gradually with increase of deposition power level. Our results revealed that the Ag-incorporated DLC films are potentially useful as biomedical devices having good antibacterial and hemocompatibility.