体内
抗氧化剂
纳米材料
乙二醇
体外
氧化应激
超氧化物歧化酶
材料科学
PEG比率
化学
纳米技术
生物化学
有机化学
经济
财务
生物技术
生物
作者
Emily A. McHugh,Anton V. Liopo,Kimberly Mendoza,Claudia S. Robertson,Gang Wu,Zhe Wang,Weiyin Chen,Jacob L. Beckham,Paul J. Derry,Thomas A. Kent,James M. Tour
标识
DOI:10.1002/adma.202211239
摘要
Carbon-based superoxide dismutase (SOD) mimetic nanozymes have recently been employed as promising antioxidant nanotherapeutics due to their distinct properties. The structural features responsible for the efficacy of these nanomaterials as antioxidants are, however, poorly understood. Here, the process-structure-property-performance properties of coconut-derived oxidized activated charcoal (cOAC) nano-SOD mimetics are studied by analyzing how modifications to the nanomaterial's synthesis impact the size, as well as the elemental and electrochemical properties of the particles. These properties are then correlated to the in vitro antioxidant bioactivity of poly(ethylene glycol)-functionalized cOACs (PEG-cOAC). Chemical oxidative treatment methods that afford smaller, more homogeneous cOAC nanoparticles with higher levels of quinone functionalization show enhanced protection against oxidative damage in bEnd.3 murine endothelioma cells. In an in vivo rat model of mild traumatic brain injury (mTBI) and oxidative vascular injury, PEG-cOACs restore cerebral perfusion rapidly to the same extent as the former nanotube-derived PEG-hydrophilic carbon clusters (PEG-HCCs) with a single intravenous injection. These findings provide a deeper understanding of how carbon nanozyme syntheses can be tailored for improved antioxidant bioactivity, and set the stage for translation of medical applications.
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