Department of Mechanical Engineering, Texas A&M University, College Station, Texas 77843, USA.
Part Fibre Toxicol. 2009 Feb 9;6:4. doi: 10.1186/1743-8977-6-4.
There is a need to better understand synergism in the biological effects of particles composed of multiple substances. The objective of this study was to determine if the oxidative stress in cultured cells caused by co-exposure to carbon black and Fe2O3 nanoparticles was significantly greater than the additive effects of exposure to either type of particles alone; and to determine a possible cause for such synergistic effect if one was found. Cultured A549 human lung epithelial cells were exposed to (1) carbon black nanoparticles alone, (2) Fe2O3 nanoparticles alone, and (3) both types of particles simultaneously. Protein oxidation, lipid peroxidation, and cellular uptake of Fe in these cells were measured after 25 hours of exposure. The reduction of solubilized Fe3+ by the carbon black nanoparticles was measured separately in a cell-free assay, by incubating the carbon black and the Fe2O3 nanoparticles in 0.75 M sulfuric acid at 40 degrees C and measuring the amount of reduced Fe3+ at different time points up to 24 hours.
Cells exposed to carbon black particles alone did not show protein oxidation, nor did the cells exposed to Fe2O3 particles alone, relative to the control. However, cells co-exposed to both carbon black and Fe2O3 particles showed up to a two-fold increase in protein oxidation relative to the control. In addition, co-exposure induced significant lipid peroxidation, although exposure to either particle type alone did not. No significant difference in cellular iron uptake was found between single exposure and co-exposure, when the Fe2O3 dosing concentration was the same in each case. In the cell-free assay, significant reduction of Fe3+ ions by carbon black nanoparticle was found within 2 hour, and it progressed up to 24 hours. At 24 hours, the carbon black nanoparticles showed a reductive capacity of 0.009 g/g, defined as the mass ratio of reduced Fe3+ to carbon black.
Co-exposure to carbon black and Fe2O3 particles causes a synergistic oxidative effect that is significantly greater than the additive effects of exposures to either particle type alone. The intracellular redox reaction between carbon black and Fe3+ is likely responsible for the synergistic oxidative effect. Therefore elemental carbon particles and fibres should be considered as potential reducing agents rather than inert materials in toxicology studies. Acidified cell organelles such as the lysosomes probably play a critical role in the solubilization of Fe2O3. Further research is necessary to better understand the mechanisms.
需要更好地了解由多种物质组成的颗粒的生物效应协同作用。本研究的目的是确定同时暴露于炭黑和 Fe2O3 纳米颗粒时培养细胞中的氧化应激是否明显大于单独暴露于任一种颗粒的相加效应;并确定如果发现协同效应,其可能的原因。将培养的 A549 人肺上皮细胞暴露于(1)炭黑纳米颗粒单独,(2)Fe2O3 纳米颗粒单独,和(3)两种类型的颗粒同时暴露。暴露 25 小时后,测量这些细胞中的蛋白质氧化、脂质过氧化和细胞内铁的摄取。在细胞外测定中分别测量炭黑纳米颗粒对溶解的 Fe3+的还原,通过在 40°C 的 0.75 M 硫酸中孵育炭黑和 Fe2O3 纳米颗粒,并在 24 小时内的不同时间点测量还原的 Fe3+的量。
单独暴露于炭黑颗粒的细胞没有显示蛋白质氧化,单独暴露于 Fe2O3 颗粒的细胞也没有,相对于对照组。然而,同时暴露于炭黑和 Fe2O3 颗粒的细胞显示出与对照组相比,蛋白质氧化增加了一倍。此外,尽管单独暴露于任一种颗粒类型都没有引起脂质过氧化,但同时暴露诱导了显著的脂质过氧化。当 Fe2O3 给药浓度在每种情况下相同时,在单一暴露和共同暴露之间,细胞内铁摄取没有发现显著差异。在细胞外测定中,在 2 小时内发现炭黑纳米颗粒对 Fe3+离子的显著还原,并且在 24 小时内进行。在 24 小时时,炭黑纳米颗粒表现出 0.009 g/g 的还原性,定义为还原的 Fe3+与炭黑的质量比。
同时暴露于炭黑和 Fe2O3 颗粒会导致协同的氧化作用,其明显大于单独暴露于任一种颗粒类型的相加效应。炭黑和 Fe3+之间的细胞内氧化还原反应可能是协同氧化作用的原因。因此,在毒理学研究中,元素碳颗粒和纤维应被视为潜在的还原剂,而不是惰性物质。酸化的细胞器,如溶酶体,可能在 Fe2O3 的溶解中起关键作用。需要进一步研究以更好地了解机制。
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