活性氧
催化作用
生物物理学
化学
材料科学
生物
生物化学
作者
Hua He,Xinjian Shi,Junying Wang,Xiaojuan Wang,Qian Wang,Daoyong Yu,Baosheng Ge,Xiaodong Zhang,Fang Huang
标识
DOI:10.1021/acsami.9b17509
摘要
Nanozymes show excellent enzyme activity and robust catalytic properties, but the targeting capability to disease organs is limited because of lack of specificity. Herein, we developed an ultrasmall (∼3 nm) organic nanozyme that can gradually aggregate under a reactive oxygen species (ROS)-rich environment via a spontaneous reaction, namely, ROS-induced aggregation. The size of nanozymes is 75 and 100 times higher than the original size under •OH and H2O2 environments without losing enzyme activity. In vitro experiments confirm that nanozymes prefer to aggregate in mitochondria under ROS-rich conditions. Importantly, the nanozymes show in situ ROS-induced aggregation in the brain, ∼9 times higher uptake than ordinary nanozymes, indicating their potential for treating ROS-related diseases in the central nervous system.
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