Author:
Gao Hongbo,Sun Li,Ni Dalong,Zhang Libo,Wang Han,Bu Wenbo,Li Jinjin,Shen Qianwen,Wang Ya,Liu Yanyan,Zheng Xiangpeng
Abstract
AbstractIn the process of radiation therapy (RT), the cytotoxic effects of excited electrons generated from water radiolysis tend to be underestimated due to multiple biochemical factors, particularly the recombination between electrons and hydroxyl radicals (·OH). To take better advantage of radiolytic electrons, we constructed WO3 nanocapacitors that reversibly charge and discharge electrons to regulate electron transportation and utilization. During radiolysis, WO3 nanocapacitors could contain the generated electrons that block electron-·OH recombination and contribute to the yield of ·OH at a high level. These contained electrons could be discharged from WO3 nanocapacitors after radiolysis, resulting in the consumption of cytosolic NAD+ and impairment of NAD+-dependent DNA repair. Overall, this strategy of nanocapacitor-based radiosensitization improves the radiotherapeutic effects by increasing the utilization of radiolytic electrons and ·OH, warranting further validation in multiple tumour models and preclinical experiments.
Funder
Shanghai Sailing program
Shanghai Anticancer Association Eyas Project
China National Funds for Distinguished Young Scientists
Key Project of Shanghai Science and Technology Commission
National Science Foundation for the Young Scientists of China
National Natural Science Foundation of China
Shanghai Municipal Commission of Science and Technology
Shanghai Municipal Health Commission
Publisher
Springer Science and Business Media LLC
Subject
Pharmaceutical Science,Applied Microbiology and Biotechnology,Biomedical Engineering,Molecular Medicine,Medicine (miscellaneous),Bioengineering