Selective decorating Ag and MnOx nanoparticles on halloysite and used as micromotor for bacterial killing

Threats of bacterial infection represent one of the most persistent issues of public health, and efficient bacteria killing materials are to be developed. Taking inspirations from nature, a new class of halloysite (Hal)-based bacteria killing materials (MnOx-Ag/Hal) that were able to self-move in aq...

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Bibliographic Details
Published in:Applied clay science 2022-01, Vol.216, p.106352, Article 106352
Main Authors: Wang, Jian, Wu, Shengyu, Zhang, Wenjing, Wang, Hongchao, Zhang, Peiping, Jin, Bo, Wei, Cundi, Guo, Ruifeng, Miao, Shiding
Format: Article
Language:English
Subjects:
Antibacterial micromotors
Asymmetry structure
Bacterial killing
Halloysite
Selective decorating
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Summary:Threats of bacterial infection represent one of the most persistent issues of public health, and efficient bacteria killing materials are to be developed. Taking inspirations from nature, a new class of halloysite (Hal)-based bacteria killing materials (MnOx-Ag/Hal) that were able to self-move in aqueous solution was prepared. The asymmetric halloysite tubes are used as substrates. Silver (Ag) nanoparticles are loaded both in the lumen and on the external surface, and manganese oxide (MnOx) was distributed on the outside walls. Fuel with low concentration of H2O2, the catalyst Ag and MnOx would decompose H2O2 into gas bubbles (O2), and the back-thrust bubbles provided forward forces for jet movement, which improved the antibacterial efficiency. The fabricated MnOx-Ag/Hal exhibited powerful self-propelled motion with velocity of 18 ± 4 μm/s achieved at 0.2 wt% H2O2. The MnOx-Ag/Hal generated Ag+ ions and highly reactive oxygen species that could efficiently kill E. coli. By coupling the antibacterial capabilities of H2O2, Ag and highly reactive oxygen species with powerful self-propulsion, the prepared micromotors were capable of killing 97% of E. coli within 2.0 min, which was threefold as the counterpart of MnOx-Ag/Hal in the absence of H2O2 that cannot move efficiently. The biocompatible micromotors offered an encouraging strategy for rapid bacteria killing in clinical and environment fields. [Display omitted] •Selective modification of halloysite tubes with MnOx and Ag.•Strong self-propulsion of HNTs-based nanojes in H2O2 solution.•H2O2, Ag NPs, Ag+ and O2• are responsible for killing bacteria.•Self-propulsion enhances the antibacterial performance by promoting mass transfer.
ISSN:0169-1317
1872-9053
DOI:10.1016/j.clay.2021.106352