Transparent and Highly Flexible Hierarchically Structured Polydimethylsiloxane Surfaces Suppress Bacterial Attachment and Thrombosis Under Static and Dynamic Conditions

Khan, Shadman; Jarad, Noor Abu; Ladouceur, Liane; Rachwalski, Kenneth; Bot, Veronica A.; Shakeri, Amid; Maclachlan, Roderick; Sakib, Sadman; Weitz, Jeffrey I.; Brown, Eric D.; Soleymani, Leyla; Didar, Tohid F.

doi:10.1002/smll.202108112

Cited by 6 publications

(3 citation statements)

References 59 publications

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“…To demonstrate the usefulness of superhydrophobic nickel samples in contaminated environments, a series of tests was conducted [42][43][44]. These included a self-cleaning test, as shown in Figure 5a, and antifouling tests, as shown in Figure 5b,c.…”

Section: Resultsmentioning

confidence: 99%

Wire Electrochemical Etching of Superhydrophobic Nickel Surfaces with Enhanced Corrosion Protection

Wu,

Yan,

Lin

et al. 2023

Materials

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Superhydrophobic nickel surfaces have significant advantages in the field of corrosion protection compared with traditional nickel corrosion protection methods which need a toxic chemical corrosion inhibitor. Electrochemical etching, an ideal method for fabricating superhydrophobic nickel surfaces, was also limited by low current density, resulting in low processing efficiency. To overcome this limitation, we proposed a new method to fabricate a superhydrophobic nickel surface using a wire electrochemical etching method. The wire electrochemical etching method accomplished the etching process by sweeping a controlled wire cathode across the surface of the anode nickel plate in an environmentally friendly neutral electrolyte, NaCl. The superhydrophobic nickel sample with a contact angle of 153° and a rolling angle of 10° could be fabricated by wire electrochemical etching and modification. Additionally, the optimal parameters of the wire electrochemical etching and the principle of superhydrophobic surface formation had also been systematically investigated, respectively. Moreover, the superhydrophobic nickel surface had self-cleaning performance, antifouling performance, corrosion protection, and abrasion resistance. Wire electrochemical etching improves the current density of processing, which means that this method improves the processing efficiency for fabricating a superhydrophobic nickel surface. This work is expected to enrich the theory and technology for fabricating superhydrophobic nickel surfaces to improve the corrosion protection of nickel.

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Section: Resultsmentioning

confidence: 99%

Wire Electrochemical Etching of Superhydrophobic Nickel Surfaces with Enhanced Corrosion Protection

Wu,

Yan,

Lin

et al. 2023

Materials

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“…In vitro surface anti-adhesion technology alone does not meet practical clinical needs; it is also vital to address how to apply these techniques in vivo. Didar et al transferred the topography present with hierarchical polystyrene surfaces onto polydimethylsiloxane (PDMS), which prevents biofilm and thrombosis in vivo ( Figure 4 b) [ 96 ]. Sun et al integrated highly antibacterial copper nanoparticles (CuNPs) into hydrophilic polydopamine (PDA) coating and finally fixed it on a reverse osmosis (RO) thin-film composite membrane, which could reduce bacterial adhesion and significantly inhibited the formation of biofilm [ 97 ].…”

Section: Strategies Of Targeting Initial Adhesion Stagementioning

confidence: 99%

Targeted Anti-Biofilm Therapy: Dissecting Targets in the Biofilm Life Cycle

Liu

Xie

et al. 2022

Pharmaceuticals

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Biofilm is a crucial virulence factor for microorganisms that causes chronic infection. After biofilm formation, the bacteria present improve drug tolerance and multifactorial defense mechanisms, which impose significant challenges for the use of antimicrobials. This indicates the urgent need for new targeted technologies and emerging therapeutic strategies. In this review, we focus on the current biofilm-targeting strategies and those under development, including targeting persistent cells, quorum quenching, and phage therapy. We emphasize biofilm-targeting technologies that are supported by blocking the biofilm life cycle, providing a theoretical basis for design of targeting technology that disrupts the biofilm and promotes practical application of antibacterial materials.

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“…A wide range of surface treatment approaches have been developed to improve the blood compatibility and antifouling properties of medical devices. In particular, liquid-infused surfaces (LIS) have been established as an effective strategy to prevent fouling on a wide range of devices, such as grafts, catheters, and implants. − Since their initial invention, many efforts have been dedicated to the preparation and optimization of different types of LIS systems to maximize lubricant–surface interactions, long-term stability, and ease of application. ,− Many such improvements have focused on minimizing the depletion of the lubricant layer over time, which remains a key hindrance in the real-world applicability of LIS systems. − To this end, recent studies have determined that having a good lubricant–surface interaction, and a larger surface contact areaachieved by hierarchical structures at the micro- and nanoscalesuccessfully delays lubricant depletion off the surface and enhances its stability …”

Section: Introductionmentioning

confidence: 99%

Highly Stable Hierarchically Structured All-Polymeric Lubricant-Infused Films Prevent Thrombosis and Repel Multidrug-Resistant Pathogens

Afonso

Bayat

Ladouceur

et al. 2022

ACS Appl. Mater. Interfaces

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Thrombus formation and infections caused by bacterial adhesion are the most common causes of failure in blood-contacting medical devices. Reducing the interaction of pathogens using repellent surfaces has proven to be a successful strategy in preventing device failure. However, designing scale-up methodologies to create large-scale repellent surfaces remains challenging. To address this need, we have created an all-polymeric lubricant-infused system using an industrially viable swellingcoagulation solvent (S-C) method. This induces hierarchically structured micro/nano features onto the surface, enabling improved lubricant infusion. Poly(3,3,3-trifluoropropylmethylsiloxane) (PTFS) was used as the lubricant of choice, a previously unexplored omniphobic nonvolatile silicone oil. This resulted in allpolymeric liquid-infused surfaces that are transparent and flexible with long-term stability. Repellent properties have been demonstrated using human whole blood and methicillin-resistant Staphylococcus aureus (MRSA) bacteria matrices, with lubricated surfaces showing 93% reduction in blood stains and 96.7% reduction in bacterial adherence. The developed material has the potential to prevent blood and pathogenic contamination for a range biomedical devices within healthcare settings.

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Transparent and Highly Flexible Hierarchically Structured Polydimethylsiloxane Surfaces Suppress Bacterial Attachment and Thrombosis Under Static and Dynamic Conditions

Cited by 6 publications

References 59 publications

Wire Electrochemical Etching of Superhydrophobic Nickel Surfaces with Enhanced Corrosion Protection

Wire Electrochemical Etching of Superhydrophobic Nickel Surfaces with Enhanced Corrosion Protection

Targeted Anti-Biofilm Therapy: Dissecting Targets in the Biofilm Life Cycle

Highly Stable Hierarchically Structured All-Polymeric Lubricant-Infused Films Prevent Thrombosis and Repel Multidrug-Resistant Pathogens

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