Application of nanotechnology to control bacterial adhesion and patterning on material surfaces

Cait  Costello; Chun-Ling Yeung; Frankie Rawson; Paula Mendes

doi:10.1080/17458080.2012.740640

Application of nanotechnology to control bacterial adhesion and patterning on material surfaces

Cait Costello, Chun-Ling Yeung, Frankie Rawson, Paula Mendes

Chemical Engineering

Research output: Contribution to journal › Article › peer-review

6 Citations (Scopus)

179 Downloads (Pure)

Abstract

Bacterial adhesion and biofilm formation on surfaces raises health hazard issues in the medical environment. Previous studies of bacteria adhesion have focused on observations in their natural/native environments. Recently, surface science has contributed in advancing the understanding of bacterial adhesion by providing ideal platforms that attempt to mimic the bacteria's natural environments, whilst also enabling concurrent control, selectivity and spatial control of bacterial adhesion. In this review, we will look at techniques of how nanotechnology is used to control cell adhesion on a planar scale, in addition to describing the use of nanotools for cell micropatterning. Additionally, it will provide a general background of common methods for nanoscale modification enabling biologist unfamiliar with nanotechnology to enter the field.

Original language	English
Pages (from-to)	634-651
Journal	Journal of Experimental Nanoscience
Volume	7
Issue number	6
DOIs	https://doi.org/10.1080/17458080.2012.740640
Publication status	Published - 21 Nov 2012

Keywords

Nanotechnology
Surface science
bacterial adhesion
bacterial patterning
self-assembled monolayers

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10.1080/17458080.2012.740640

Costello_et_al_2015_Application_nanotechnology_Journal_Experimental_Nanoscience
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Switchable Nanostructured Surfaces as a Sophisticated Tool for Cell Biologists
Mendes, P., Kirkman-Brown, J. & Publicover, S.
THE WELLCOME TRUST
10/01/11 → 9/05/14
Project: Research

Cite this

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title = "Application of nanotechnology to control bacterial adhesion and patterning on material surfaces",

abstract = "Bacterial adhesion and biofilm formation on surfaces raises health hazard issues in the medical environment. Previous studies of bacteria adhesion have focused on observations in their natural/native environments. Recently, surface science has contributed in advancing the understanding of bacterial adhesion by providing ideal platforms that attempt to mimic the bacteria's natural environments, whilst also enabling concurrent control, selectivity and spatial control of bacterial adhesion. In this review, we will look at techniques of how nanotechnology is used to control cell adhesion on a planar scale, in addition to describing the use of nanotools for cell micropatterning. Additionally, it will provide a general background of common methods for nanoscale modification enabling biologist unfamiliar with nanotechnology to enter the field.",

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AU - Costello, Cait

AU - Yeung, Chun-Ling

AU - Rawson, Frankie

AU - Mendes, Paula

PY - 2012/11/21

Y1 - 2012/11/21

N2 - Bacterial adhesion and biofilm formation on surfaces raises health hazard issues in the medical environment. Previous studies of bacteria adhesion have focused on observations in their natural/native environments. Recently, surface science has contributed in advancing the understanding of bacterial adhesion by providing ideal platforms that attempt to mimic the bacteria's natural environments, whilst also enabling concurrent control, selectivity and spatial control of bacterial adhesion. In this review, we will look at techniques of how nanotechnology is used to control cell adhesion on a planar scale, in addition to describing the use of nanotools for cell micropatterning. Additionally, it will provide a general background of common methods for nanoscale modification enabling biologist unfamiliar with nanotechnology to enter the field.

AB - Bacterial adhesion and biofilm formation on surfaces raises health hazard issues in the medical environment. Previous studies of bacteria adhesion have focused on observations in their natural/native environments. Recently, surface science has contributed in advancing the understanding of bacterial adhesion by providing ideal platforms that attempt to mimic the bacteria's natural environments, whilst also enabling concurrent control, selectivity and spatial control of bacterial adhesion. In this review, we will look at techniques of how nanotechnology is used to control cell adhesion on a planar scale, in addition to describing the use of nanotools for cell micropatterning. Additionally, it will provide a general background of common methods for nanoscale modification enabling biologist unfamiliar with nanotechnology to enter the field.

KW - Nanotechnology

KW - Surface science

KW - bacterial adhesion

KW - bacterial patterning

KW - self-assembled monolayers

U2 - 10.1080/17458080.2012.740640

DO - 10.1080/17458080.2012.740640

M3 - Article

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VL - 7

SP - 634

EP - 651

JO - Journal of Experimental Nanoscience

JF - Journal of Experimental Nanoscience

IS - 6

ER -

Application of nanotechnology to control bacterial adhesion and patterning on material surfaces

Abstract

Keywords

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Switchable Nanostructured Surfaces as a Sophisticated Tool for Cell Biologists

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