Underlying mechanisms of reactive oxygen species and oxidative stress photoinduced by graphene and its surface-functionalized derivatives

Graphene can be modified by different functional groups through various transformation processes in the environment. The toxicological activity of graphene is closely related to its ability to produce reactive oxygen species (ROS), which can be altered by surface modification. Herein, unfunctionaliz...

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Published in:Environmental science. Nano 2020-03, Vol.7 (3), p.782-792
Main Authors: Yao, Hongye, Huang, Yang, Li, Xuan, Li, Xuehua, Xie, Hongbin, Luo, Tianlie, Chen, Jingwen, Chen, Zhongfang
Format: Article
Language:English
Subjects:
Anions
Biological stress
Biomarkers
Coupling (molecular)
Daphnia magna
Density functional theory
Derivatives
Electron transfer
Energy transfer
Free radicals
Freshwater crustaceans
Functional groups
Graphene
Hydroxyl radicals
Identification
Molecular orbitals
Oxidative stress
Oxidoreductions
Oxygen
Photochemicals
Photochemistry
Radiation
Radiation effects
Reactive oxygen species
Redox potential
Singlet oxygen
Stress concentration
Superoxide anions
Superoxide dismutase
Toxicity
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Summary:Graphene can be modified by different functional groups through various transformation processes in the environment. The toxicological activity of graphene is closely related to its ability to produce reactive oxygen species (ROS), which can be altered by surface modification. Herein, unfunctionalized graphene (u-G), carboxylated graphene (G-COOH) and aminated graphene (G-NH 2 ) were selected to determine their ability to photogenerate ROS in the aqueous phase. Oxidative stress (ROS concentration and superoxide dismutase activity) in Daphnia magna under simulated sunlight radiation induced by the materials was also investigated. Based on density functional theory (DFT) calculations, the photochemical pathways of ROS production were identified. G-COOH and G-NH 2 produced singlet oxygen in the aqueous phase by mediating energy transfer. G-COOH, G-NH 2 and u-G generated superoxide anions and further produced hydroxyl radicals by inducing electron transfer. By comparing the biological redox potential and the lowest occupied molecular orbital values ( E LUMO ) of the substances, u-G and G-COOH were identified to have the potential to induce oxidative stress. The predictive results were validated by the significant increase of oxidative stress biomarkers in Daphnia magna . By coupling experimental observations with the theoretical predictions, the results provide mechanistic insight into understanding the photochemical activity and toxicity of graphene and its surface-functionalized derivatives. Graphene can be modified by different functional groups through various transformation processes in the environment.
ISSN:2051-8153
2051-8161
DOI:10.1039/c9en01295h