Biomimetic surface modifications of stainless steel targeting dairy fouling mitigation and bacterial adhesion

Zouaghi, Sawsen; Bellayer, Séverine; Thomy, V.; Dargent, Thomas; Coffinier, Yannick; André, Christophe; Delaplace, Guillaume; Jimenez, Maude

doi:10.1016/j.fbp.2018.10.012

Cited by 31 publications

(22 citation statements)

References 30 publications

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“…Initial bacterial adsorption onto the surface due to intermolecular forces, such as vdW forces or electrostatic attraction, and subsequent fixing of the bacteria onto the surface by biofilm formation is effectively reduced. Any bacterial cells that do come into relatively close proximity of the liquid–solid interface are likely carried away by external forces or random Brownian motion before they can start to form a biofilm and proliferate (Ayazi et al., 2019; Crick et al., 2011; Fadeeva et al., 2011; Manoj et al., 2020; Oh, Lu, et al., 2015; Oh, Kohli et al., 2016; Zouaghi et al, 2019). It has been noted by several authors that the extent of hydrophilic bacteria adhesion onto surfaces generally decreases with increasing surface hydrophobicity or decreasing surface energy (Absolom et al, 1983; Cunliffe et al, 1999; Parreira et al, 2011).…”

Section: Superhydrophobic Antifouling (Anticontact) Surfacesmentioning

confidence: 99%

“…The three key requirements for successful SLIPS fabrication are that the solid used for immobilization has a higher affinity for the immobilized fluid than it does for water, that the solid is textured to increase its effective contact area with the immobilized fluid, and that the immobilized lubricating fluid is immiscible with water (Epstein et al., 2020). Slips have been successfully created by anodizing aluminum (Wang, Zhang, et al., 2015), laser‐etching stainless steel (Zouaghi et al., 2019), or depositing multiwalled carbon nanotubes (MWCNTs) onto stainless steel (Rungraeng et al., 2015) to create roughened substrate surfaces. Porous polytetrafluoroethylene film has also been utilized (Epstein et al., 2020).…”

Section: Other Antifouling Surface Modificationsmentioning

confidence: 99%

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Recent developments in antimicrobial and antifouling coatings to reduce or prevent contamination and cross‐contamination of food contact surfaces by bacteria

DeFlorio

Liu

White

et al. 2021

Comp Rev Food Sci Food Safe

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Illness as the result of ingesting bacterially contaminated foodstuffs represents a significant annual loss of human quality of life and economic impact globally. Significant research investment has recently been made in developing new materials that can be used to construct food contacting tools and surfaces that might minimize the risk of cross‐contamination of bacteria from one food item to another. This is done to mitigate the spread of bacterial contamination and resultant foodborne illness. Internet‐based literature search tools such as Web of Science, Google Scholar, and Scopus were utilized to investigate publishing trends within the last 10 years related to the development of antimicrobial and antifouling surfaces with potential use in food processing applications. Technologies investigated were categorized into four major groups: antimicrobial agent–releasing coatings, contact‐based antimicrobial coatings, superhydrophobic antifouling coatings, and repulsion‐based antifouling coatings. The advantages for each group and technical challenges remaining before wide‐scale implementation were compared. A diverse array of emerging antimicrobial and antifouling technologies were identified, designed to suit a wide range of food contact applications. Although each poses distinct and promising advantages, significant further research investment will likely be required to reliably produce effective materials economically and safely enough to equip large‐scale operations such as farms, food processing facilities, and kitchens.

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Section: Superhydrophobic Antifouling (Anticontact) Surfacesmentioning

confidence: 99%

Section: Other Antifouling Surface Modificationsmentioning

confidence: 99%

Recent developments in antimicrobial and antifouling coatings to reduce or prevent contamination and cross‐contamination of food contact surfaces by bacteria

DeFlorio

Liu

White

et al. 2021

Comp Rev Food Sci Food Safe

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“…Ivanova et al reported that the nano-sized structures on the wings of cicadas and dragonflies exhibit antibacterial activity (Ivanova et al 2012 , 2013 ; Pogodin et al 2013 ). Following this report, various artificial nanostructures with antibacterial and sterilization properties have been actively researched (Zouaghi et al 2019 ; Hasan et al 2020 ; Mann et al 2014 ). Micro-sized patterns also show antibacterial properties.…”

Section: Introductionmentioning

confidence: 99%

Antibacterial effect on microscale rough surface formed by fine particle bombarding

Nishitani¹,

Masuda

Mimura

et al. 2022

AMB Expr

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Fine particle bombarding (FPB) is typically utilized to modify metal surfaces by bombarding them with fine particles at high-speed. The diameters of the particles range from several to tens of micrometers. FPB forms fine microscale concavities and convexities on a surface. As FPB-treated surfaces are widely used in the food industry, the influence of bacteria on their surface must be considered. In this study, we examined the antibacterial activity of microscale rough surfaces formed by FPB. We applied FPB to a stainless-steel surface and evaluated the antibacterial effect of FPB-treated surfaces based on JIS Z 2801 (a modified test method from ISO 22196:2007). Our results indicated that the FPB-treated surfaces (FPB-1 (avg. pitch: 0.72 µm) and FPB-2 (avg. pitch: 3.56 µm)) exhibited antibacterial activity both against Escherichia coli and Staphylococcus aureus. Graphical Abstract

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“…These include the well-studied hydrophobic self-cleaning properties of certain plant species, such as the “lotus effect” as observed in Nelumbo nucifera (whose mechanisms are elucidated and effects artificially reproduced in [ 25 , 26 , 27 ]). Some of these approaches have made it out of the laboratory and into broader technical applications, including some interesting recent patents [ 28 ] and applications [ 29 ]. Of course, these strategies have drawbacks, and there are undoubtedly technical challenges to be overcome in many applications—for example, Flemming points out that the lotus effect, despite its aquatic origins, has not found widespread commercial application on surfaces submerged in water, as the methods to date are based on hydrophobicity requiring the presence of both water and gas phases (a liquid–gas interface), which is difficult to maintain [ 8 ].…”

Section: Introductionmentioning

confidence: 99%

Recent Developments in Biomimetic Antifouling Materials: A Review

Sullivan

O’Callaghan

2020

Biomimetics

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The term ‘biomimetic’ might be applied to any material or process that in some way reproduces, mimics, or is otherwise inspired by nature. Also variously termed bionic, bioinspired, biological design, or even green design, the idea of adapting or taking inspiration from a natural solution to solve a modern engineering problem has been of scientific interest since it was first proposed in the 1960s. Since then, the concept that natural materials and nature can provide inspiration for incredible breakthroughs and developments in terms of new technologies and entirely new approaches to solving technological problems has become widely accepted. This is very much evident in the fields of materials science, surface science, and coatings. In this review, we survey recent developments (primarily those within the last decade) in biomimetic approaches to antifouling, self-cleaning, or anti-biofilm technologies. We find that this field continues to mature, and emerging novel, biomimetic technologies are present at multiple stages in the development pipeline, with some becoming commercially available. However, we also note that the rate of commercialization of these technologies appears slow compared to the significant research output within the field.

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Biomimetic surface modifications of stainless steel targeting dairy fouling mitigation and bacterial adhesion

Cited by 31 publications

References 30 publications

Recent developments in antimicrobial and antifouling coatings to reduce or prevent contamination and cross‐contamination of food contact surfaces by bacteria

Recent developments in antimicrobial and antifouling coatings to reduce or prevent contamination and cross‐contamination of food contact surfaces by bacteria

Antibacterial effect on microscale rough surface formed by fine particle bombarding

Recent Developments in Biomimetic Antifouling Materials: A Review

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