Gold nanoplates with superb photothermal efficiency and peroxidase-like activity for rapid and synergistic antibacterial therapy

Lü, Yan; Mu, Jie; Ma, Pengxin; Li, Qian; Yin, Pengxue; Li, Xuan; Cai, Yuanyuan; Yu, Haipeng; Liu, Junchong; Wang, Guoqing; Liu, Aihua

doi:10.1039/d0cc06925f

Cited by 56 publications

(35 citation statements)

References 45 publications

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“…In an in vivo study using an implant biofilm infection model irradiation with 0.5 W/cm 2 NIR lasting 5 min caused considerable acceleration of NO release, damaged MRSA biofilms and killed planktonic MRSA missing its biofilm protection [ 295 ]. Outstanding synergistic antibacterial ability and cure of MRSA-infected wounds in vivo was observed with 50 μg/mL Au nanoplates combined with 0.1 mM H 2 O 2 under irradiation with 808 nm laser (1 W/cm 2 ) for 3 min [ 296 ].…”

Section: Applied Nanomaterialsmentioning

confidence: 99%

Advances in Nanostructures for Antimicrobial Therapy

Jampílek

Kráľová

2022

Materials

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Microbial infections caused by a variety of drug-resistant microorganisms are more common, but there are fewer and fewer approved new antimicrobial chemotherapeutics for systemic administration capable of acting against these resistant infectious pathogens. Formulation innovations of existing drugs are gaining prominence, while the application of nanotechnologies is a useful alternative for improving/increasing the effect of existing antimicrobial drugs. Nanomaterials represent one of the possible strategies to address this unfortunate situation. This review aims to summarize the most current results of nanoformulations of antibiotics and antibacterial active nanomaterials. Nanoformulations of antimicrobial peptides, synergistic combinations of antimicrobial-active agents with nitric oxide donors or combinations of small organic molecules or polymers with metals, metal oxides or metalloids are discussed as well. The mechanisms of actions of selected nanoformulations, including systems with magnetic, photothermal or photodynamic effects, are briefly described.

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Section: Applied Nanomaterialsmentioning

confidence: 99%

Advances in Nanostructures for Antimicrobial Therapy

Jampílek

Kráľová

2022

Materials

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“…To date, with the rapid development of nanotechnology, a large number of antibacterial nanozymes have been developed, from noble-metal (e.g. Au [19][20][21][22][23][24][25][26], Pt [27], Cu [28], Ir [29], Ag [30], Au-Pt [31,32], Pd-Cu [33], Pd-Pt [34], Au-Ag [35], etc), transition metal oxide or sulfide (e.g. Fe 3 O 4 [36][37][38], CuO [39], CeO 2 [40], V 2 O 5 [41], Co-V mixed metal oxide (MMO) [42], MoS 2 [43][44][45][46][47], NiS 2 [48], CuS [49][50][51][52], Co 4 S 3 [53], MnO 2 [54] etc), and nanocarbon (e.g.…”

Section: Future Perspectivesmentioning

confidence: 99%

“…The photothermal nanoagents can absorb the NIR and convert the optical energy into heat, which then initiates the cell membrane breakage and protein denaturation in bacteria, finally leading to their thermal ablation [102][103][104]. Based on this, NIR-responsive nanozymes, such as Au nanoplates [26], Au@Pt nanodots [32], Au NRs/CeO 2 hybrid [91], rough carbon/Fe 3 O 4 nanohybrids [102], cationic chitosan@RuO 2 hybrid [105], MoS 2 nanozymes [43,82,106], N-doped carbon nanozyme [55], PEG@Zr-Fc MOF hydrogel [107], and Fe-and Cu-N-C SAzymes [61,63,64], have been developed. Under the NIR laser irradiation, these NIR-active nanozymes can not only produce local photothermal effect, but more importantly the elevated temperature certainly accelerates catalytic reaction rate, thereby realizing the enhanced synergic CDT and PTT for effectively treating drug-resistant bacterial infections.…”

Section: Nir Stimulationmentioning

confidence: 99%

Efficient nanozyme engineering for antibacterial therapy

et al. 2022

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Antimicrobial resistance (AMR) has posed a huge threat to human health. It is urgent to explore efficient ways to suppress the spread of AMR. Antibacterial nanozymes has become one of the powerful weapons to combat AMR due to their enzyme-like catalytic activity with a broad-spectrum antibacterial performance. However, the inherent low catalytic activity of nanozymes limits their expansion into antibacterial applications. In this regard, a variety of advanced chemical design strategies have been developed to improve the antimicrobial activity of nanozymes. In this review, we have summarized the recent progress of advanced strategies to engineering efficient nanozymes for fighting against AMR, which can be mainly classified into catalytic activity improvement, external stimuli, bacterial affinity enhancement, and multifunctional platform construction according to the basic principles of engineering efficient nanocatalysts and the mechanism of nanozyme catalysis. Moreover, the deep insights into the effects of these enhancing strategies on the nanozyme structures and properties are highlighted. Finally, current challenges and future perspectives of antibacterial nanozymes are discussed for their future clinical potential.

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“…Because the chemical and physical properties of gold (Au) nanocrystals depend heavily on their size and shape, the sizeand shape-controlled synthesis of Au nanocrystals is an important topic. 1,2 The literature includes numerous reports of the synthesis of Au nanocrystals with various shapes, including zero-dimensional (0D, such as spheres and platonic shapes), 3,4 one-dimensional (1D, such as rods and nanowires), 5,6 twodimensional (2D, such as plates and sheets), 7,8 and threedimensional (3D, such as multipods and nanocages). 9,10 Among the various reported structures, Au nanocrystals with 3D hierarchical structures such as ower-like architectures have attracted considerable attention because of their unique structural features, which include a high surface roughness, a large surface area-to-volume ratio, and abundant edges and sharp tips.…”

Section: Introductionmentioning

confidence: 99%