Water chemistry controlled aggregation and photo-transformation of silver nanoparticles in environmental waters

The inevitable release of engineered silver nanoparticles (AgNPs) into aquatic environments has drawn great concerns about its environmental toxicity and safety. Although aggregation and transformation play crucial roles in the transport and toxicity of AgNPs, how the water chemistry of environmental waters influences the aggregation and transformation of engineered AgNPs is still not well understood. In this study, the aggregation of polyvinylpyrrolidone (PVP) coated AgNPs was investigated in eight typical environmental water samples (with different ionic strengths, hardness, and dissolved organic matter (DOM) concentrations) by using UV–visible spectroscopy and dynamic light scattering. Raman spectroscopy was applied to probe the interaction of DOM with the surface of AgNPs. Further, the photo-transformation and morphology changes of AgNPs in environmental waters were studied by UV–visible spectroscopy, inductively coupled plasma mass spectrometry, and transmission electron microscopy. The results suggested that both electrolytes (especially Ca^2 + and Mg^2 +) and DOM in the surface waters are key parameters for AgNP aggregation, and sunlight could accelerate the morphology change, aggregation, and further sedimentation of AgNPs. This water chemistry controlled aggregation and photo-transformation should have significant environmental impacts on the transport and toxicity of AgNPs in the aquatic environments.     

Molecular toxicity and defense mechanisms induced by silver nanoparticles in Drosophila melanogaster

The widely use of silver nanoparticles (AgNPs) as antimicrobial agents gives rise to potential environmental risks. AgNPs exposure have been reported to cause toxicity in animals. Nevertheless, the known mechanisms of AgNPs toxicity are still limited. In this study, we systematically investigated the toxicity of AgNPs exposure using Drosophila melanogaster. We show here that AgNPs significantly decreased Drosophila fecundity, the third-instar larvae weight and rates of pupation and eclosion in a dose-dependent manner. AgNPs reduced fat body cell viability in MTT (3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide) assays. AgNPs caused DNA damage in hemocytes and S2 cells. Interestingly, the mRNA levels of the entire metallothionein gene family were increased under AgNPs exposure as determined by RNA-seq analysis and validated by qRT-PCR, indicating that Drosophila responded to the metal toxicity of AgNPs by producing metallothioneins for detoxification. These findings provide a better understanding of the mechanisms of AgNPs toxicity and may provide clues to effect on other organisms, including humans.     

Long-term effects of silver nanoparticles on performance of phosphorus removal in a laboratory-scale vertical flow constructed wetland

Silver nanoparticles(AgNPs) have been widely used in many fields,which raised concerns about potential threats to biological sewage treatment systems.In this study,the phosphorus removal performance,enzymatic activity and microbial population dynamics in constructed wetlands(CWs) were evaluated under a long-term exposure to Ag NPs(0,50,and 200 μg/L) for 450 days.Results have shown that Ag NPs inhibited the phosphorus removal efficiency in a short-term exposure,whereas caused no obviously negativ...     

微生物燃料电池恒电流预培养阳极生物膜分析表征

阳极性能是影响微生物燃料电池(Microbial Fuel Cells,MFCs)性能的关键因素之一,同时阳极的接种挂膜过程是影响微生物燃料电池启动效率的关键因素.因此,本课题组提出了预培养阳极作为微生物燃料电池的一种新型阳极的概念,在三电极体系下,通过外加恒定电流预培养阳极,在不同条件下对阳极表面进行电化学选择和生物膜驯化以丰富生物膜结构和厚度.结果表明,阳极的性能与预培养电流大小密切相关,预培养阳极CF-4i(外加4 A·m-2电流密度)通过循环伏安法、塔菲尔曲线、电化学阻抗谱测试,性能好于其他测试组及对照组,装配阳极CF-4i的微生物燃料电池能实现最大功率密度968.20 m W·m-2,是对照组的2.53倍.同时,通过共聚焦显微镜观察发现,生物膜大体分两层,外层的活细胞及内层的死细胞,外层活细胞长在内层死细胞之上.这种结构分布表明,阳极生物膜中的活细胞部分绝大多数都分布于生物膜的外侧,而不是均布于整个阳极生物膜中;同时这也表明不是整个阳极生物膜都具有新陈代谢活性,但死亡的细胞可以继续积累在电极表面附近,活的外层膜负责电流的产生,而内层的死细胞作为一种导电基质.     

Effect of humic acids and sunlight on the cytotoxicity of engineered zinc oxide and titanium dioxide nanoparticles to a river bacterial assemblage

The effect of a terrestrial humic acid (HA) and Suwannee River HA on the cytotoxicity of engineered zinc oxide nanoparticles (ZnONPs) and titanium dioxide nanoparticles (TiO2NPs) to natural aquatic bacterial assemblages was measured with spread plate counting. The effect of HA (10 and 40 ppm) on the cytotoxicity of ZnONPs and TiO2NPs was tested factorially in the presence and absence of natural sunlight (light irradiation (LI)). The experiment was of full factorial, completely randomized design and the results were analyzed using the General Linear Model in SAS analytical software. The method of least squares means was used to separate the means or combinations of means. We determined the mechanism of toxicity via measurements of oxidative stress and metal ions. The toxicity of ZnONPs and TiO2NPs to natural aquatic bacterial assemblages appears to be concentration dependent. Moreover, the cytotoxicity of ZnONPs and TiO2NPs appeared to be affected by HA concentration, the presence of sunlight irradiation, and the dynamic multiple interactions among these factors. With respect to light versus darkness in the control group, the data indicate that bacterial viability was inhibited more in the light exposure than in the darkness exposure. The same was true in the HA treatment groups. With respect to terrestrial versus Suwanee River HA for a given nanoparticle, in light versus darkness, bacterial viability was more inhibited in the light treatment groups containing the terrestrial HA than in those containing Suwanee River HA. Differences in the extent of reactive oxygen species formation, adsorption/binding of ZnONPs/TiO2NPs by HA, and the levels of free metal ions were speculated to account for the observed cytotoxicity. TEM images indicate the attachment and binding of the tested nanoparticles to natural bacterial assemblages. Besides the individual parameter, significant effects on bacterial viability count were also observed in the following combined treatments: HA-ZnONPs, HA-LI, ZnONPs-LI, and HA-ZnONPs-LI. The main effects of all independent variables, plus interaction effects in all cases were significant with TiO2NPs.     

外阻对三室MFC产电性能和Cu迁移特性的影响

构建一种新型的三室微生物燃料电池（microbial fuel cells,MFCs）对重金属Cu污染的土壤进行修复,研究不同外阻条件下MFC的产电性能和土壤中Cu的迁移去除情况.结果表明,当外接电阻从100Ω增大到1000Ω时,三室MFC的输出电压从0.1V提高到0.4V,最大功率密度从1.10W/m³降低到0.71W/m³,且阴极极化现象也随外阻增大而更加显著.装置运行63d后,MFC外接电阻越大,近阳极土壤区的Cu的去除率越高,外阻为1000Ω的MFC近阳极土壤区的Cu去除率达到39.7%.通过改进欧共体标准（BCR）连续提取法分析重金属的形态,发现乙酸可提取态和可还原态为Cu迁移的两种主要形态.此外,土壤的性质也发生变化,pH值呈现由阳极到阴极逐渐升高的趋势,而电导率则相反.阴极电极的扫描电镜（SEM）和X射线衍射（XRD）结果也表明部分迁移到阴极的Cu（Ⅱ）被还原成单质Cu.