Abstract
As inflammation frequently occurs after the implantation of a medical device, biocompatible, antibacterial materials must be used. Polymer–metal nanocomposites are promising materials. Here we prepared enhanced polyethylene naphthalate (PEN) using surface modification techniques and investigated its suitability for biomedical applications. The PEN was modified by a KrF laser forming periodic ripple patterns with specific surface characteristics. Next, Au/Ag nanowires were deposited onto the patterned PEN using vacuum evaporation. Atomic force microscopy confirmed that the surface morphology of the modified PEN changed accordingly with the incidence angle of the laser beam. Energy-dispersive X-ray spectroscopy showed that the distribution of the selected metals was dependent on the evaporation technique. Our bimetallic nanowires appear to be promising antibacterial agents due to the presence of antibacterial noble metals. The antibacterial effect of the prepared Au/Ag nanowires against E. coli and S. epidermidis was demonstrated using 24 h incubation with a drop plate test. Moreover, a WST-1 cytotoxicity test that was performed to determine the toxicity of the nanowires showed that the materials could be considered non-toxic. Collectively, these results suggest that prepared Au/Ag nanostructures are effective, biocompatible surface coatings for use in medical devices.
Highlights
Surface morphology was studied on pristine polyethylene naphthalate (PEN) (PEN), PEN modified under different incidence angles of laser light (PEN 0/22.5/45◦ ) and modified PEN coated with bimetallic nanowires (Au/Ag PEN 0/22.5/45◦ )
Laser irradiation with KrF lasers resulted in the development of periodical arrays on the PEN, with structural parameters differing at specific light incidence angles of 0◦, 22.5◦ and 45◦
We have presented a straightforward and effective method for the preparation of bimetallic nanowires on laser-rippled PEN using a physical vapour deposition technique
Summary
Advances in manufacturing and processing technologies have resulted in polymers being used in a wide range of medical and pharmaceutical applications [1,2] These applications include artificial blood vessels, orthopaedic implants, surgical instruments, wound dressing and drug delivery. Properties such as surface morphology, roughness and wettability have a crucial influence on the interaction between an implant and a human body. These properties play a significant role in ensuring that a medical device functions correctly and that its introduction does not lead to inflammation [3] or bacterial infection [4,5]. Bacteriosis can occur due to many reasons ranging from the simple insertion of foreign material to the inadequate sterilisation or poor storage of a medical device
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