a Environmental Molecular Sciences Laboratory , Pacific Northwest National Laboratory , Richland , ( WA ), USA.
b Department of Chemistry , University of Wisconsin-Madison , 1101 University Ave , Madison , ( WI ), USA.
Nanotoxicology. 2018 Dec;12(10):1166-1181. doi: 10.1080/17435390.2018.1508785. Epub 2018 Nov 19.
Metal oxide and phosphate nanoparticles (NPs) are ubiquitous in emerging applications, ranging from energy storage to catalysis. Cobalt-containing NPs are particularly important, where their widespread use raises questions about the relationship between composition, structure, and potential for environmental impacts. To address this gap, we investigated the effects of lithiated metal oxide and phosphate NPs on rainbow trout gill epithelial cells, a model for environmental exposure. Lithium cobalt oxide (LCO) NPs significantly reduced cell viability at10 µg/mL, while a 10-fold higher concentration of lithiated cobalt hydroxyphosphate (LCP) NPs was required to significantly reduce viability. Exposure to Li and Co alone, at concentrations relevant to ion released from the NPs, did not reduce cell viability and minimally impacted reactive oxygen species (ROS) levels. Both LCO- and LCP-NPs were found within membrane-bound organelles. However, only LCP-NPs underwent rapid and complete dissolution in artificial lysosomal fluid. Unlike LCP-NPs, LCO-NPs significantly increased intracellular ROS, could be found within abnormal multilamellar bodies, and induced formation of intracellular vacuoles. Increased p53 gene expression, measured in individual cells, was observed at sub-toxic concentrations of both LCO- and LCP-NPs, implicating both in inductions of cellular damage and stress at concentrations approaching predicted environmental levels. Our results implicate the intact NP, not the dissolved ions, in the observed adverse effects and show that LCO-NPs significantly impact cell viability accompanied by increase in intracellular ROS and formation of organelles indicative of cell stress, while LCP-NPs have minimal adverse effects, possibly due to their rapid dissolution in acidic organelles.
金属氧化物和磷酸盐纳米颗粒(NPs)广泛存在于新兴应用中,从储能到催化等领域都有涉及。含钴的 NPs 尤为重要,由于其广泛应用,人们开始关注其组成、结构与潜在环境影响之间的关系。为了弥补这一空白,我们研究了锂化金属氧化物和磷酸盐 NPs 对虹鳟鱼鳃上皮细胞的影响,该细胞模型可用于模拟环境暴露。10μg/mL 的锂离子钴氧化物(LCO) NPs 显著降低了细胞活力,而 10 倍更高浓度的锂化钴羟磷灰石(LCP) NPs 才会显著降低细胞活力。在与从 NPs 释放的离子浓度相关的浓度下,单独暴露于 Li 和 Co 并不会降低细胞活力,也不会显著影响活性氧(ROS)水平。LCO-NPs 和 LCP-NPs 都被发现存在于膜结合细胞器内。然而,只有 LCP-NPs 在人工溶酶体液中能迅速且完全溶解。与 LCP-NPs 不同,LCO-NPs 能显著增加细胞内 ROS,并能在异常的多层体中找到,同时还能诱导细胞内空泡的形成。在亚毒性浓度下,两种 LCO-NPs 和 LCP-NPs 都能观察到细胞内 p53 基因表达增加,这表明两种 NPs 都能在接近预测环境浓度的浓度下诱导细胞损伤和应激。我们的研究结果表明,完整的 NP 而非溶解的离子,导致了观察到的不良反应,并且表明 LCO-NPs 会显著影响细胞活力,同时增加细胞内 ROS 和形成细胞应激的细胞器,而 LCP-NPs 的不良反应最小,这可能是由于它们在酸性细胞器中快速溶解。
