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Self‐driven Electrical Stimulation Promotes Cancer Catalytic Therapy Based on Fully Conjugated Covalent Organic Framework Nanocages

Shuncheng Yao, Minjia Zheng, Shaobo Wang, Tian Huang, Zhuo Wang, Zhuo Wang, Yunchao Zhao, Wei Yuan, Zhou Li, Zhong Lin Wang, Zhong Lin Wang, Linlin Li

2022Advanced Functional Materials61 citationsDOI

Abstract

Abstract Engineered nanozymes have been developed to catalyze the production of reactive oxygen species (ROS) for cancer therapy, but currently, the ROS generation efficiency is still far from optimistic. In this study, a human self‐driven electrical stimulation enhanced catalytic system based on wearable triboelectric nanogenerator (TENG) and fully π‐conjugated covalent organic framework nanocages (hCOF) for improving cancer therapy is created. The fully π‐conjugated hCOF nanocage with high electron mobility under the self‐generated electric field can not only rearrange the local electric field for optimizing energy utilization, but also facilitates the access of electrolytes to optimize the utilization of the electric field. With the self‐powered wearable TENG, the peroxidase‐like activity of hCOF increased by 2.44‐fold and has electricity‐responsive doxorubicin delivery capacity for enhancing the therapeutic outcomes. The high‐efficient self‐driven electrical stimulation enhanced nanocatalytic system provides a new optimized model for the catalytic energy supply of nanozymes.

Topics & Concepts

NanocagesMaterials scienceNanotechnologyConjugated systemTriboelectric effectCovalent bondRational designCatalysisPolymerChemistryOrganic chemistryComposite materialAdvanced Nanomaterials in CatalysisCarbon and Quantum Dots ApplicationsNanoplatforms for cancer theranostics
Self‐driven Electrical Stimulation Promotes Cancer Catalytic Therapy Based on Fully Conjugated Covalent Organic Framework Nanocages | Litcius