A Nanowire-Based Flexible Antibacterial Surface Reduces the Viability of Drug-Resistant Nosocomial Pathogens

Tripathy, Abinash; Kumar, Arvind; Chowdhury, Atish Roy; Karmakar, Kapudeep; Purighalla, Swathi; Sambandamurthy, Vasan K.; Chakravortty, Dipshikha; Sen, Prosenjit

doi:10.1021/acsanm.8b00397

Cited by 14 publications

(8 citation statements)

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“…13 The nanotopography of the surface is of major importance for the first steps of the bacterial adhesion, as described by Prosenjit Sen's research group. [14][15][16] The major advantage of this coating is that there are only two reactants: HAuCl 4 salt and gentamicin; a commercially available, broad-spectrum antibiotic.…”

Section: Discussionmentioning

confidence: 99%

Nanostructured Gold Coating for Prevention of Biofilm Development in Medical Devices

Rocca

Aiassa

Zoppi

et al. 2020

Journal of Endourology

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Bacterial biofilms on medical devices (MDs) can cause deadly infections due to their resistance to antibiotics. Technology to prevent this kind of complication is urgently needed because they impact not only patients' lives but also hospital budgets. In this article, the creation and testing of an easy-to-produce antibiofilm (more precisely antibiofouling) coating are described for the first time. This coating can be applied to catheters, prostheses, and other plastic pieces, even after they have been manufactured. Rapid and ecofriendly synthesis of nanostructured gold coating was done in situ in just 15 minutes. Complete characterization and microbiological analysis of its antibiofouling capacity are presented. The coating prevents biofilm formation of pathogenic clinical isolates and ATCC strains on MDs, possibly due to its complex nanostructured gold surface. If the next generation of MDs is coated with this kind of antibiofouling technology, biofilm-related infections could be dramatically reduced.

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Section: Discussionmentioning

confidence: 99%

Nanostructured Gold Coating for Prevention of Biofilm Development in Medical Devices

Rocca

Aiassa

Zoppi

et al. 2020

Journal of Endourology

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“…Several other reports with the aim of engineering wing-inspired biomaterials have been published (Figure ). ,− However, wing-inspired strategies are not limited to implant surfaces but also have many other potential applications such as reducing nosocomial infections. , Recently, Wang et al incorporated dragonfly-inspired bSi into a reusable cell, resulting in a bactericidal microfluidic device . The device was shown to effectively rupture Escherichia coli cells from contaminated water.…”

Section: Bioinspirationmentioning

confidence: 99%

Mimicking Insect Wings: The Roadmap to Bioinspiration

Hasan

Roy

Chatterjee

et al. 2019

ACS Biomater. Sci. Eng.

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Insect wings possess unique, multifaceted properties that have drawn increasing attention in recent times. They serve as an inspiration for engineering of materials with exquisite properties. The structure–function relationships of insect wings are yet to be documented in detail. In this review, we present a detailed understanding of the multifunctional properties of insect wings, including micro- and nanoscale architecture, material properties, aerodynamics, sensory perception, wettability, optics, and antibacterial activity, as investigated by biologists, physicists, and engineers. Several established modeling strategies and fabrication methods are reviewed to engender novel ideas for biomimetics in diverse areas.

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“…Superhydrophobic surfaces are widely used in drag reduction, anti-icing, anti-fouling, water manipulation, antibacterial coatings, oil water separation, underwater sensing, and self-cleaning applications. − Such nanostructures are established by creating hierarchical dual-scale roughness on the substrate surface using various techniques such as dip-coating, sol–gel synthesis, chemical etching, plasma etching, electrochemical methods, spin-coating, spray-coating, layer-by-layer methods, and chemical vapor deposition. ,− For practical applications, the fabrication method should be scalable, cost-effective, and straightforward. Spray-coating and dip-coating, two popular methods used for fabricating large-area superhydrophobic surfaces, are suitable for substrates with complex features and geometries. − The first technique involves preparing a precursor solution that is sprayed onto the substrate, while the second involves dipping the substrate into the solution. − In these processes, a binder is either spin-coated over the substrate or dissolved in the solution to ensure better adhesion between the coating and the hydrophobic particle .…”

Section: Introductionmentioning

confidence: 99%

Acrylonitrile Butadiene Polystyrene–SiO₂ Composite Nanostructures for Self-Regulated Superhydrophobic Liquid Dosage Systems

Arun

Kim

Sreekala

et al. 2022

ACS Appl. Nano Mater.

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Superhydrophobic coatings are widely studied for fluid regulation due to their water-repellent surface characteristics. However, there are not many reports on fluid behavior when it flows from a region of higher wettability to that of lower wettability. A fundamental understanding of such behavior would be very useful for regulating the fluid flow through a superhydrophobic channel. Therefore, this work focused on the fabrication of superhydrophobic nanostructured coatings inside fine cylindrical channels and the investigation of the fluid flow behavior through them. The superhydrophobic SiO 2 coatings were obtained through an ultrasound-assisted one-step immersion technique. A self-stratified mechanically durable conformal superhydrophobic coating was obtained inside millimeter-sized fine 3D structures. A binder-free precursor solution has low viscosity and thereby enhances the penetration of the solvent into the polymer surface through ultrasonication. The self-stratification-based surface formation mechanism was explained using scanning electron microscopy images. The fluid behavior inside the superhydrophobic channels was experimentally investigated by analyzing the flow through the hollow cylindrical superhydrophobic channels. Experiments were conducted for different channel lengths (l) and radii (r), and mathematical formulations were developed to determine the maximum pressure (P max ) that the superhydrophobic cylinders could hold when the fluid inside the channel was under static equilibrium. Finally, a self-regulated fluid delivery system was postulated based on the experimental and theoretical findings.

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A Nanowire-Based Flexible Antibacterial Surface Reduces the Viability of Drug-Resistant Nosocomial Pathogens

Cited by 14 publications

References 50 publications

Nanostructured Gold Coating for Prevention of Biofilm Development in Medical Devices

Nanostructured Gold Coating for Prevention of Biofilm Development in Medical Devices

Mimicking Insect Wings: The Roadmap to Bioinspiration

Acrylonitrile Butadiene Polystyrene–SiO₂ Composite Nanostructures for Self-Regulated Superhydrophobic Liquid Dosage Systems

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A Nanowire-Based Flexible Antibacterial Surface Reduces the Viability of Drug-Resistant Nosocomial Pathogens

Cited by 14 publications

References 50 publications

Nanostructured Gold Coating for Prevention of Biofilm Development in Medical Devices

Nanostructured Gold Coating for Prevention of Biofilm Development in Medical Devices

Mimicking Insect Wings: The Roadmap to Bioinspiration

Acrylonitrile Butadiene Polystyrene–SiO2 Composite Nanostructures for Self-Regulated Superhydrophobic Liquid Dosage Systems

Contact Info

Product

Resources

About

Acrylonitrile Butadiene Polystyrene–SiO₂ Composite Nanostructures for Self-Regulated Superhydrophobic Liquid Dosage Systems