Stimuli-Responsive Release-Active Dressing: A Promising Solution for Eradicating Biofilm-Mediated Wound Infections

Dey, Rajib; Mukherjee, Riya; Biswas, Sucheta; Haldar, Jayanta

doi:10.1021/acsami.4c09820

ACS Appl. Mater. Interfaces

2024

DOI: 10.1021/acsami.4c09820

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Stimuli-Responsive Release-Active Dressing: A Promising Solution for Eradicating Biofilm-Mediated Wound Infections

Rajib Dey,

Riya Mukherjee,

Sucheta Biswas

et al.

Abstract: Biofilm-mediated wound infections pose a significant challenge due to the limitations of conventional antibiotics, which often exhibit narrow-spectrum activity, fail to eliminate recurrent bacterial contamination, and are unable to penetrate the biofilm matrix. While the search for alternatives has explored the use of metal nanoparticles and synthetic biocides, these solutions often suffer from unintended toxicity to surrounding tissues and lack controlled administration and release. In this study, we engineer… Show more

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Cited by 3 publications

References 48 publications

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One‐Step Nanoimprinting of Fe₂O₃/AgBr Thin Films for Dark‐Light Active Antibiofilm and Bacterial‐Free Cell Culture Surfaces

Thakur,

Singh,

Ganesan

et al. 2024

Small Methods

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The resuscitation of bacteria through biofilms presents a critical challenge in controlling microbial pathogenesis and addressing antimicrobial resistance. Continuous antibiofilm activity, particularly on frequently contacted surfaces, is therefore critical. In this study, a scalable is introduced, one‐step fabrication of Fe2O3/AgBr nanoimprints using a polymerizable sol–gel (PSG) approach to create functional nanostructured thin films with strong antimicrobial properties. Fe2O3, a visible‐light photocatalyst, is coupled with AgBr, a photosensitizer and dark‐active antimicrobial, forming a heterojunction that demonstrated potent antibacterial activity against Escherichia coli and Pseudomonas putida under both dark and light conditions. The heterojunctions exhibit significant biofilm inhibition in the dark, particularly against the robust biofilm‐forming P. putida, while visible light irradiation ensures complete biofilm clearance. These surfaces also achieve optimal reactive oxygen species (ROS) production, selectively targeting bacteria without compromising the integrity of mammalian cells. The biocompatibility is confirmed through MTT, TBARS, and apoptosis assays, demonstrating the non‐cytotoxic nature of the substrates. Moreover, the surfaces enable cell patterning and recovery of mammalian cells from microbial contamination, highlighting their potential in creating bacterial‐free environments for cell culture. This innovative method offers a promising route to next‐generation, self‐cleaning antimicrobial coatings, combining continuous biofilm inhibition with excellent biocompatibility and scalability.

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One‐Step Nanoimprinting of Fe₂O₃/AgBr Thin Films for Dark‐Light Active Antibiofilm and Bacterial‐Free Cell Culture Surfaces

Thakur,

Singh,

Ganesan

et al. 2024

Small Methods

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Stimuli-responsive and targeted nanomaterials: Revolutionizing the treatment of bacterial infections

Li,

Ding,

et al. 2025

Journal of Controlled Release

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Cu-BTC MOFs Grown In Situ on Poly(ionic liquid)-Based Electrospun Fibrous Membranes for Wound Dressings

Zhou,

Gao,

Zhou

et al. 2024

ACS Appl. Polym. Mater.

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Developing wound dressings with antibacterial, good moisture absorption, air permeability and inflammatory inhibition activities to promote wound healing effectively is highly desirable in clinical practice. Herein, a multifunctional wound dressing with air permeability, hygroscopicity and antibacterial activity was developed by in situ growth of a metal−organic framework (Cu-BTC) benzene-1,3,5-tricarboxylate (BTC) on poly(ionic liquid) (PIL)based fibrous membranes. The Cu-BTC was grown in situ on an imidazolium-based PIL fibrous membrane via coordination bonds, which increased the stability and dispersion of the Cu-BTC. The porous structure of electrospinning and Cu-BTC allows the breathable dressings to absorb wound exudate and regulate the wound microenvironment. The imidazolium-based IL and Cu 2+ released from Cu-BTC endow the dressing with effective bactericidal activities both in vitro and in vivo, especially for Cu-BTC 60 /PIL, in which more than 96% of bacteria are inactivated. Moreover, an in vivo bacterial infection wound study revealed that the dressing with good biocompatibility can effectively sterilize Staphylococcus aureus while suppressing inflammation and promoting wound healing. The developed wound dressing synergistically combines the antibacterial therapeutic effect of PIL and the release of Cu 2+ from Cu-BTC for effective wound healing, which may provide an ideal clinical intervention strategy for infected wounds.

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Stimuli-Responsive Release-Active Dressing: A Promising Solution for Eradicating Biofilm-Mediated Wound Infections

Cited by 3 publications

References 48 publications

One‐Step Nanoimprinting of Fe₂O₃/AgBr Thin Films for Dark‐Light Active Antibiofilm and Bacterial‐Free Cell Culture Surfaces

One‐Step Nanoimprinting of Fe₂O₃/AgBr Thin Films for Dark‐Light Active Antibiofilm and Bacterial‐Free Cell Culture Surfaces

Stimuli-responsive and targeted nanomaterials: Revolutionizing the treatment of bacterial infections

Cu-BTC MOFs Grown In Situ on Poly(ionic liquid)-Based Electrospun Fibrous Membranes for Wound Dressings

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Stimuli-Responsive Release-Active Dressing: A Promising Solution for Eradicating Biofilm-Mediated Wound Infections

Cited by 3 publications

References 48 publications

One‐Step Nanoimprinting of Fe2O3/AgBr Thin Films for Dark‐Light Active Antibiofilm and Bacterial‐Free Cell Culture Surfaces

One‐Step Nanoimprinting of Fe2O3/AgBr Thin Films for Dark‐Light Active Antibiofilm and Bacterial‐Free Cell Culture Surfaces

Stimuli-responsive and targeted nanomaterials: Revolutionizing the treatment of bacterial infections

Cu-BTC MOFs Grown In Situ on Poly(ionic liquid)-Based Electrospun Fibrous Membranes for Wound Dressings

Contact Info

Product

Resources

About

One‐Step Nanoimprinting of Fe₂O₃/AgBr Thin Films for Dark‐Light Active Antibiofilm and Bacterial‐Free Cell Culture Surfaces

One‐Step Nanoimprinting of Fe₂O₃/AgBr Thin Films for Dark‐Light Active Antibiofilm and Bacterial‐Free Cell Culture Surfaces