2019
DOI: 10.1021/acsabm.8b00765
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Ultrascalable Multifunctional Nanoengineered Copper and Aluminum for Antiadhesion and Bactericidal Applications

Abstract: Biofouling disrupts the surface functionality and integrity of engineered substrates. A variety of natural materials such as plant leaves and insect wings have evolved sophisticated physical mechanisms capable of preventing biofouling. Over the past decade, several reports have pinpointed nanoscale surface topography as an important regulator of surface adhesion and growth of bacteria. Although artificial nanoengineered features have been used to create bactericidal materials that kill adhered bacteria, functi… Show more

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Cited by 27 publications
(31 citation statements)
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“…Also, it may affect the longterm efficiency of these surfaces (Nino-Martinez et al, 2019). To overcome this issue, alternative approaches have been proceeded; developing a surface that (i) can hinder bacterial adhesion at its early stages that eventually alter biofilm formation (Zhang et al, 2018;Chi et al, 2019), (ii) physically disrupt membrane of adhered bacteria (Reed et al, 2019;Wandiyanto et al, 2019), or (iii) exhibits multifunctional antiadhesion/antibacterial properties (Balaure et al, 2016;Borcherding et al, 2019). Laser-based techniques used to modify surface topography can be a powerful technique for controlling bacterial colonization.…”
Section: Implication For Developing New Anti-fouling Strategiesmentioning
confidence: 99%
“…Also, it may affect the longterm efficiency of these surfaces (Nino-Martinez et al, 2019). To overcome this issue, alternative approaches have been proceeded; developing a surface that (i) can hinder bacterial adhesion at its early stages that eventually alter biofilm formation (Zhang et al, 2018;Chi et al, 2019), (ii) physically disrupt membrane of adhered bacteria (Reed et al, 2019;Wandiyanto et al, 2019), or (iii) exhibits multifunctional antiadhesion/antibacterial properties (Balaure et al, 2016;Borcherding et al, 2019). Laser-based techniques used to modify surface topography can be a powerful technique for controlling bacterial colonization.…”
Section: Implication For Developing New Anti-fouling Strategiesmentioning
confidence: 99%
“…Bacterial adhesion tests were performed on all investigated substrates with a rod-shaped gramnegative bacteria. The Escherichia coli BL21 (DE3) strain (Thermofisher Scientific, USA) was selected as an example bacteria in this research because of its wide use in investigations on antimicrobial efficacy of textured surfaces [40][41]. In particular, this motile strain was prepared by first cloning the hplA gene with Green Fluorescent Protein (GFP) in pBSK cloning vector.…”
Section: Bacterial Retention Characterisationmentioning
confidence: 99%
“…Identifying the modes in which insects enact these remarkable properties would act as a guide to the consideration of both chemistry and topography during the fabrication of engineered materials with combined superhydrophobic and antimicrobial purposes. [ 28 ]…”
Section: Introductionmentioning
confidence: 99%