活性氧
过氧化氢
超氧化物歧化酶
化学
过氧化氢酶
清除
激进的
氧化铈
铈
超氧化物
一氧化氮
气溶胶化
香烟烟雾
核化学
羟基自由基
烟雾
化学发光
氧化应激
氧气
抗氧化剂
氧化磷酸化
生物化学
食腐动物
电子烟
过氧化物
作者
Chen Yufeng,Jia Hong-li,Junqin Li,Ninghong Yin,Ming Song,Zhizhong Hu,Lingyong Song,Yumei Qian,Weize Li,Dinggeng He,Zhong Fan,Luo Hai,Jianbo Liu,Chen Yufeng,Jia Hong-li,Junqin Li,Ninghong Yin,Ming Song,Zhizhong Hu,Lingyong Song
标识
DOI:10.1021/acsami.5c19874
摘要
Tobacco smoke-induced lung disease remains a major global health threat. Reactive oxygen species (ROS) present in cigarette smoke including superoxide (•O2-), hydroxyl radicals (•OH), and hydrogen peroxide (H2O2) contribute substantially to oxidative injury, yet conventional acetate filters are ineffective at removing these gaseous free radicals. Here, we report manganese-doped hollow cerium oxide (Mn-CeO2) nanospheres as robust antioxidative nanozymes for scavenging gas-phase ROS. Mn-CeO2 exhibits enhanced superoxide dismutase (SOD)-like, catalase (CAT)-like activities and superior •OH scavenging compared with undoped CeO2. After being filled into a commercial cigarette filter, Mn-CeO2 removed over 56.2% of targeted ROS from smoke under our test conditions. In a mouse passive-smoking model, cigarette filters filled with Mn-CeO2 markedly reduced pulmonary inflammation and histological lung injury relative to the controls. Serum biochemical markers showed no significant systemic toxicity. Our research demonstrates that manganese doping significantly improves the ROS scavenging performance of CeO2 nanozymes and suggests a feasible route to reduce cigarette smoke-derived oxidative damage.
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