Abstract
Due to its biocompatibility and advantageous electrochemical properties, platinum is commonly used in the design of biomedical devices, e.g., surgical instruments, as well as electro-medical or orthopedic implants. This article verifies the hypothesis that a thin layer of sputter-coated platinum may possess antibacterial effects. The purpose of this research was to investigate the adhesion and growth ability of a model strain of Gram-negative bacteria, Escherichia coli, on a surface of a platinum-coated glass slide. Although some previous literature reports suggests that a thin layer of platinum would inhibit the formation of bacterial biofilm, the results of this study suggest otherwise. The decrease in the number of bacterial cells attached to the platinum-coated glass, which was observed within first three hours of culturing, was found to be a short-time effect, vanishing after 24 h. Consequently, it was shown that a thin layer of sputter-coated platinum did not exhibit any antibacterial effect. For this reason, this study indicates an urgent need for the development of new methods of surface modification that could reduce bacterial surface colonization of platinum-based biomedical devices.
Highlights
The antimicrobial properties of metals have been known for centuries [1]
This articleonconcerns the investigations a thin layer of platinum sputter-coated the surface of a glass slideofinantibacterial relation to aproperties noncoatedofslide
Bare glass and Pt-coated glass slides were used to investigate the antibacterial activity of sputter-coated filmsPt-coated against a model strain, Escherichia coli
Summary
The antimicrobial properties of metals have been known for centuries [1]. Noble metal ions have been indicated as potential antibacterial agents. Apart from antibacterial activity, noble metals, especially platinum, offer high strength and stability in different conditions, as well as biocompatibility. High electrical conductivity of platinum is an excellent property qualifying this metal for the design of pacemakers, hearing aids and neurological implants [3,4,5]. Antimicrobial effects may be achieved by the use of metal nanoparticles. Nanoparticles of gold, silver, zinc, silica or platinum have been successfully used in the design of Materials 2020, 13, 2674; doi:10.3390/ma13122674 www.mdpi.com/journal/materials
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