Lehman Sean E, Morris Angie S, Mueller Paul S, Salem Aliasger K, Grassian Vicki H, Larsen Sarah C
Department of Chemistry, University of Iowa, Iowa City, IA 52242.
Department of Chemistry, University of Iowa, Iowa City, IA 52242; Division of Pharmaceutics and Translational Therapeutics, College of Pharmacy, University of Iowa, Iowa City, IA 52242.
Environ Sci Nano. 2016 Feb 1;3(1):56-66. doi: 10.1039/C5EN00179J. Epub 2015 Nov 10.
Evaluating toxicological responses of engineered nanomaterials such as silica nanoparticles is critical in assessing health risks and exposure limits. Biological assays can be used to evaluate cytotoxicity of individual materials, but specific nano-bio interactions-which govern its physiological response-cannot currently be predicted from materials characterization and physicochemical properties. Understanding the role of free radical generation from nanomaterial surfaces facilitates understanding of a potential toxicity mechanism and provides insight into how toxic effects can be assessed. Size-matched mesoporous and nonporous silica nanoparticles in aminopropyl-functionalized and native forms were investigated to analyze the effects of porosity and surface functionalization on the observed cytotoxicity. cell viability data in a murine macrophage cell line (RAW 264.7) provides a model for what might be observed in terms of cellular toxicity upon an environmental or industrial exposure to silica nanoparticles. Electron paramagnetic resonance spectroscopy was implemented to study free radical species generated from the surface of these nanomaterials and the signal intensity was correlated with cellular toxicity. In addition, assay of intracellular reactive oxygen species (ROS) matched well with both the EPR and cell viability data. Overall, spectroscopic and studies correlate well and implicate production of ROS from a surface-catalyzed reaction as a predictor of cellular toxicity. The data demonstrate that mesoporous materials are intrinsically less toxic than nonporous materials, and that surface functionalization can mitigate toxicity in nonporous materials by reducing free radical production. The broader implications are in terms of safety by design of nanomaterials, which can only be extracted by mechanistic studies such as the ones reported here.
评估工程纳米材料(如二氧化硅纳米颗粒)的毒理学反应对于评估健康风险和暴露限值至关重要。生物测定可用于评估单个材料的细胞毒性,但目前无法从材料表征和物理化学性质预测决定其生理反应的特定纳米-生物相互作用。了解纳米材料表面自由基产生的作用有助于理解潜在的毒性机制,并深入了解如何评估毒性效应。研究了尺寸匹配的氨基丙基官能化和天然形式的介孔和无孔二氧化硅纳米颗粒,以分析孔隙率和表面官能化对观察到的细胞毒性的影响。小鼠巨噬细胞系(RAW 264.7)中的细胞活力数据为环境或工业接触二氧化硅纳米颗粒时可能观察到的细胞毒性提供了一个模型。采用电子顺磁共振光谱研究这些纳米材料表面产生的自由基种类,并将信号强度与细胞毒性相关联。此外,细胞内活性氧(ROS)测定与电子顺磁共振和细胞活力数据均吻合良好。总体而言,光谱学和细胞研究相关性良好,并表明表面催化反应产生的ROS可作为细胞毒性的预测指标。数据表明,介孔材料本质上比无孔材料毒性小,并且表面官能化可以通过减少自由基产生来减轻无孔材料的毒性。更广泛的意义在于纳米材料的设计安全性,这只能通过本文报道的此类机理研究来得出。