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      Tuning antimicrobial properties of biomimetic nanopatterned surfaces

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          Abstract

          New forms of hydrophilic black silicon with superior bactericidal properties that can be tailored to selectively kill specific species.

          Abstract

          Nature has amassed an impressive array of structures that afford protection from microbial colonization/infection when displayed on the exterior surfaces of organisms. Here, controlled variation of the features of mimetics derived from etched silicon allows for tuning of their antimicrobial efficacy. Materials with nanopillars up to 7 μm in length are extremely effective against a wide range of microbial species and exceed the performance of natural surfaces; in contrast, materials with shorter/blunter nanopillars (<2 μm) selectively killed specific species. Using a combination of microscopies, the mechanisms by which bacteria are killed are demonstrated, emphasizing the dependence upon pillar density and tip geometry. Additionally, real-time imaging reveals how cells are immobilized and killed rapidly. Generic or selective protection from microbial colonization could be conferred to surfaces [for, e.g., internal medicine, implants (joint, dental, and cosmetic), food preparation, and the agricultural industry] patterned with these materials as coatings.

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          2009 IEEE Sensors

          Schmidt (2009)
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            Author and article information

            Contributors
            (View ORCID Profile)
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            Journal
            NANOHL
            Nanoscale
            Nanoscale
            Royal Society of Chemistry (RSC)
            2040-3364
            2040-3372
            2018
            2018
            : 10
            : 14
            : 6639-6650
            Affiliations
            [1 ]Biosciences Division
            [2 ]Argonne National Laboratory
            [3 ]Argonne
            [4 ]USA
            [5 ]Center for Nanoscale Materials
            [6 ]Materials Science Division
            [7 ]Department of Biomedical Engineering
            Article
            10.1039/C8NR00439K
            29582025
            ebd9b541-7c13-442c-bf33-93790576b55f
            © 2018

            Free to read

            http://rsc.li/journals-terms-of-use#chorus

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