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Nitrogen Vacancy Modulation of Tungsten Nitride Peroxidase-Mimetic Activity for Bacterial Infection Therapy.
- Source :
-
ACS nano [ACS Nano] 2024 Sep 03; Vol. 18 (35), pp. 24469-24483. Date of Electronic Publication: 2024 Aug 22. - Publication Year :
- 2024
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Abstract
- Bacterial infections claim millions of lives every year, with the escalating menace of microbial antibiotic resistance compounding this global crisis. Nanozymes, poised as prospective substitutes for antibiotics, present a significant frontier in antibacterial therapy, yet their precise enzymatic origins remain elusive. With the continuous development of nanozymes, the applications of elemental N-modulated nanozymes have spanned multiple fields, including sensing and detection, infection therapy, cancer treatment, and pollutant degradation. The introduction of nitrogen into nanozymes not only broadens their application range but also holds significant importance for the design of catalysts in biomedical research. The synergistic interplay between W and N induces pivotal alterations in electronic configurations, endowing tungsten nitride (WN) with a peroxidase-like functionality. Furthermore, the introduction of N vacancies augments the nanozyme activity, thus amplifying the catalytic potential of WN nanostructures. Rigorous theoretical modeling and empirical validation corroborate the genesis of the enzyme activity. The meticulously engineered WN nanoflower architecture exhibits an exceptional ability in traversing bacterial surfaces, exerting potent bactericidal effects through direct physical interactions. Additionally, the topological intricacies of these nanostructures facilitate precise targeting of generated radicals on bacterial surfaces, culminating in exceptional bactericidal efficacy against both Gram-negative and Gram-positive bacterial strains along with notable inhibition of bacterial biofilm formation. Importantly, assessments using a skin infection model underscore the proficiency of WN nanoflowers in effectively clearing bacterial infections and fostering wound healing. This pioneering research illuminates the realm of pseudoenzyme activity and bacterial capture-killing strategies, promising a fertile ground for the development of innovative, high-performance artificial peroxidases.
- Subjects :
- Microbial Sensitivity Tests
Tungsten Compounds chemistry
Tungsten Compounds pharmacology
Peroxidase metabolism
Peroxidase chemistry
Animals
Tungsten chemistry
Tungsten pharmacology
Biomimetic Materials chemistry
Biomimetic Materials pharmacology
Bacterial Infections drug therapy
Mice
Catalysis
Nanostructures chemistry
Escherichia coli drug effects
Humans
Anti-Bacterial Agents pharmacology
Anti-Bacterial Agents chemistry
Nitrogen chemistry
Subjects
Details
- Language :
- English
- ISSN :
- 1936-086X
- Volume :
- 18
- Issue :
- 35
- Database :
- MEDLINE
- Journal :
- ACS nano
- Publication Type :
- Academic Journal
- Accession number :
- 39172806
- Full Text :
- https://doi.org/10.1021/acsnano.4c07856