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Oxygen Vacancy Piezoelectric Nanosheets Constructed by a Photoetching Strategy for Ultrasound “Unlocked” Tumor Synergistic Therapy

Piezoelectric dynamic therapy (PzDT) is an effective method of tumor treatment by using piezoelectric polarization to generate reactive oxygen species. In this paper, two-dimensional Cu-doped BiOCl nanosheets with surface vacancies are produced by the photoetching strategy. Under ultrasound, a built...

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Published in:	Nano letters 2024-07, Vol.24 (26), p.8008-8016
Main Authors:	Yu, Chenghao, Dong, Yushan, Zhu, Xingyu, Feng, Lili, Zang, Pengyu, Liu, Bin, Dong, Shuming, Zhao, Ruoxi, Xu, Rongchen, Yang, Piaoping
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creator	Yu, Chenghao Dong, Yushan Zhu, Xingyu Feng, Lili Zang, Pengyu Liu, Bin Dong, Shuming Zhao, Ruoxi Xu, Rongchen Yang, Piaoping
description	Piezoelectric dynamic therapy (PzDT) is an effective method of tumor treatment by using piezoelectric polarization to generate reactive oxygen species. In this paper, two-dimensional Cu-doped BiOCl nanosheets with surface vacancies are produced by the photoetching strategy. Under ultrasound, a built-in electric field is generated to promote the electron and hole separation. The separated carriers achieve O2 reduction and GSH oxidation, inducing oxidative stress. The bandgap of BiOCl is narrowed by introducing surface oxygen vacancies, which act as charge traps and facilitate the electron and hole separation. Meanwhile, Cu doping induces chemodynamic therapy and depletes GSH via the transformation from Cu(II) to Cu(I). Both in vivo and in vitro results confirmed that oxidative stress can be enhanced by exogenous ultrasound stimulation, which can cause severe damage to tumor cells. This work emphasizes the efficient strategy of doping engineering and defect engineering for US-activated PzDT under exogenous stimulation.
doi_str_mv	10.1021/acs.nanolett.4c01656
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title	Oxygen Vacancy Piezoelectric Nanosheets Constructed by a Photoetching Strategy for Ultrasound “Unlocked” Tumor Synergistic Therapy
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