废水生物强化中基因工程菌的流失和环境生存状况研究

在废水生物强化处理中,基因工程菌从生物反应器向环境的流失会造成潜在生态风险.在传统活性污泥法反应器(CAS)和膜一生物反应器(MBR)中,考察了1株降解阿特拉津基因工程菌的流失和流失后在模拟自然环境中的生存状况.结果表明,基因工程菌在接种初期从反应器中流失的密度最大.在接种密度为1010CFU/mL时,CAS的最大流失密度接近接种密度,MBR的最大流失密度仅有102CFU/mL.在模拟自然环境中,流失密度是决定基因工程菌生存状况的主要因素.在CAS出水1010CFU/mL流失密度下,高种群密度基因工程菌在水体和土壤中生存时间较长(30 d以上),潜在生态风险较高;在MBR出水102CFU/mL流失密度下.基因工程菌在水体和土壤中很快衰亡,潜在生态风险较小.环境条件对基因工程菌生存状况具有影响,提高土壤的含水率、有机质含量以及环境选择压力的存在有利于基因工程菌生存.     

Study of the performance of a coolant mixed with an Al2O3/SiC nanomaterial in an engine radiator

One of the important components of a car to control the temperature of a car's engine is the radiator. To increase the heat absorption capacity of the coolant/fluid used in the radiator with minimum pumping power, innovative fluids called nanofluids have become the main area of research these days. Therefore, with the development of new technologies in the field of “nano-materials” and “nano-fluids,” the physical and chemical properties of coolant/fluid can be improved which in turn improves the radiator and engine efficiency, and reduces radiator weight and size. In this article, the heat transfer by forced convection in nanofluids based on Al₂O₃ and SiC was studied experimentally and compared to that of base fluid in an automotive radiator. The nanofluid is mixed with ethylene glycol and the fluid is prepared by the sonication method. The nanofluids were prepared by varying the nanomaterials and the amounts of nanomaterials in the base fluid and their heat transfer performance in the radiator was analyzed using ANSYS FLUENT software. Approximately 15% and 12% increase in radiator efficiency by using Al₂O₃ mixed nanofluid and SiC mixed nanofluid, respectively.     

石墨烯纳米材料对哺乳动物的毒性及其作用机制

石墨烯是一种应用广泛的新兴非金属纳米材料，具有独特的电学机械性能、超大的比表面积以及潜在的生物相容性，在材料、电子、能源、光学以及生物医学等领域得到广泛应用。与此同时，石墨烯的环境行为和生物毒性也随之引起日益广泛的关注。本文通过对石墨烯纳米材料的动物毒性、细胞毒性、毒性影响因素和毒性机制等相关研究进展进行总结。石墨烯纳米材料可通过气管滴注、吸入、静脉注射、腹腔注射以及口服等方式进入体内，通过机械屏障、血脑屏障和血液胎盘屏障等积累在肺、肝、脾等部位引起急性或者慢性损伤；目前有关石墨烯毒性机制的研究主要集中于线粒体损伤、DNA损伤、炎性反应、凋亡等终点及氧化应激参与的复杂信号通路，不同石墨烯纳米材料的浓度、尺寸、表面结构和官能团等对石墨烯的生物毒性影响不同。鉴于当前该领域研究的局限性，对石墨烯纳米材料生物毒性研究的发展方向进行了展望，进而为石墨烯材料的安全应用提供理论借鉴和实践参考。     

植物对纳米颗粒的吸收、转运及毒性效应

随着工程纳米颗粒的广泛使用,这些纳米材料不可避免地进入环境,对环境造成未知影响.植物是高等生物暴露于纳米颗粒的一条主要途径,工程纳米颗粒可能通过食物链使其在高营养水平生物中积累.植物与纳米颗粒间的相互作用应该受到关注和重视.已有的文献表明纳米颗粒能被植物选择性地吸收并引起植物毒性,但纳米颗粒进入植物体内的机制仍不明确.多数关于植物吸收纳米颗粒的研究是在理想条件如水培实验下开展,并且集中在植物的种子发芽或是幼苗生长阶段.描述纳米颗粒在植物体内的生物转化和在植物体内分配的报道较少,而且这方面的机制没有阐述清楚.目前有许多研究者关注纳米颗粒的植物毒性效应,但这方面的研究需要进一步深入.     

Mesoporous carbon nanomaterials induced pulmonary surfactant inhibition, cytotoxicity, inflammation and lung fibrosis

Environmental exposure and health risk upon engineered nanomaterials are increasingly concerned. The family of mesoporous carbon nanomaterials(MCNs) is a rising star in nanotechnology for multidisciplinary research with versatile applications in electronics,energy and gas storage, and biomedicine. Meanwhile, there is mounting concern on their environmental health risks due to the growing production and usage of MCNs. The lung is the primary site for particle invasion under environmental exposure to nanomaterials. Here, we studied the comprehensive toxicological profile of MCNs in the lung under the scenario of moderate environmental exposure. It was found that at a low concentration of 10 μg/mL MCNs induced biophysical inhibition of natural pulmonary surfactant. Moreover, MCNs at similar concentrations reduced viability of J774 A.1 macrophages and lung epithelial A549 cells.Incubating with nature pulmonary surfactant effectively reduced the cytotoxicity of MCNs.Regarding the pro-inflammatory responses, MCNs activated macrophages in vitro, and stimulated lung inflammation in mice after inhalation exposure, associated with lung fibrosis.Moreover, we found that the size of MCNs played a significant role in regulating cytotoxicity and pro-inflammatory potential of this nanomaterial. In general, larger MCNs induced more pronounced cytotoxic and pro-inflammatory effects than their smaller counterparts. Our results provided valuable information on the toxicological profile and environmental health risks of MCNs, and suggested that fine-tuning the size of MCNs could be a practical precautionary design strategy to increase safety and biocompatibility of this nanomaterial.     

Modified titanium oxide (TiO2) nanocomposites and its array of applications: a review

Titania (TiO₂) has been the focus of attention of researchers since the first demonstration of its capability to generate the photocatalytic splitting of water into hydrogen and oxygen. However, there seems to be a recent surge in the research activity, involving modified TiO₂ nanoparticles (NP), which are considered to be more effective due to different physicochemical properties in comparison to unmodified fine particle analogs. Several strategies have been employed to modify TiO₂ to reduce recombination rates of photogenerated charge carriers to enhance the optimal functioning of TiO₂. Doping with cations and anions and coupling it with another semiconductor are the most well-known modification methods used. Titania nanocomposites are known to have a plethora of applications. Photoexcitation of these particles are seen to be extraordinarily effective in eliciting microbial death which makes it an attractive candidate for the manufacturing of antimicrobial coatings. On the other hand, TiO₂ induces the oxidation of various organic refractory compounds like tetracycline, sulfamethazine, and bisphenol. The photo-electrocatalytic oxidation technique which amalgamates the principle of photocatalysis and electrolysis serves as a newer, unswerving, and cost effective water treatment process. In the biomedical arena, use is now acknowledged for the photodynamic therapy of cancer, cell imaging, biological sensors, drug delivery system, and as endonucleases. In the commercial front, it is utilized in creams owing to its small particle size, which facilitates absorption through skin. It is also employed as ultraviolet blocking agents in sunscreen and commonly encountered as a brilliant white pigment in paint due to its brightness, high refractive index and resistance to discoloration. Its use in solar cells has also been reported. This review aims to encompass the new progress of modified TiO2 nanocomposites for efficient applications, emphasizing the future trends of TiO2 in arenas like healthcare, environment, biomedical, food, personal care, and pharmacy and also highlights the commercial implications of this promising nanomaterial.     

铁磁性纳米材料的制备及对17β-雌二醇的选择性富集——基于分子印迹技术

将铁磁性分离与分子印迹技术结合,以四氧化三铁纳米颗粒为核,以17β-雌二醇(E2)为模板分子,3-氨基丙基三乙氧基硅烷(APTES)为功能单体,利用表面聚合法制备了E2分子印迹纳米材料(MIPs)和不含E2的非印迹纳米材料(NIPs).通过傅里叶变换红外光谱(FT-IR)、X射线衍射(XRD)、X射线光电子能谱(XPS...     

Toxicological studies of zinc oxide nanomaterials in rats

In this study, we have evaluated the ability of zinc oxide (ZnO) nanoparticles to induce pulmonary and extrapulmonary toxicities was examined in rats following intratracheal (IT) instillation. Lungs of rats were instilled IT with either phosphate-buffered saline (PBS)?+?1% Tween 80, ZnO nanoparticles, carbonyl iron or quartz particles at a dose of 1 or 5?mg?kg^?1 body weight. Following exposure, bronchoalveolar lavage (BAL) fluid, blood samples and organs including lung, liver, kidneys, heart, pancreas, and brain were collected at 24?h, 1 week, or 1 month of post instillation of nanoparticles and different parameters estimated to assess toxicity. BAL fluid was analyzed for lactate dehydrogenase (LDH) and alkaline phosphatase (ALP) to assess pulmonary toxicity. Exposures to ZnO or quartz particles produced transient dose-dependant increase in BAL fluid LDH and ALP activities at all post exposure periods. Blood samples were analyzed for the tissue damage biomarkers to assess extrapulmonary toxicity. Histopathological examination of lung, liver and kidneys revealed dose-dependent degeneration and necrosis which worsened at 1 week post-instillation periods but recovered at 1 month post instillation. Histopathological examination of rat pancreas, heart, and brain exposed to quartz or ZnO particles showed no marked changes. Data suggest the instillation of ZnO nanoparticles produced a greater pulmonary toxicity in rats comparable with quartz; and extrapulmonary toxicities of these ZnO nanoparticles might be due to translocation into liver and kidney.     

Biodegradation of azo dyes by genetically engineered azoreductase

A azoreductase gene with 537 bp was obtained by PCR amplification from Rhodobacter sphaeroides ASI. 1737. The enzyme,with a molecular weight of 18.7 kD, was efficiently expressed in Escherichia coli and its biodegradation characteristics for azo dyes were investigated. Furthermore, the reaction kinetics and mechanism of azo dyes catalyzed by the genetically engineered azoreductase were studied in detail. The presence of a hydrazo-intermediate was identified, which provided a convincing evidence for the assumption that azo dyes were degraded via an incomplete reduction stage.     

纳米材料的环境行为及其毒理学研究进展

随着纳米科技的迅速发展,纳米材料被广泛应用于工业、农业、食品、日用品、医药等领域.在纳米材料广泛应用的同时,其不可避免地会被释放到环境中(包括水体、空气和土壤),对生态系统产生不利影响.与常规物质相比,纳米材料具有独特的物理、化学性质,其对生态系统生物种群和个体的潜在负面影响不容忽视.在总结国内外相关研究基础上,论文对纳米材料在水体、大气和土壤中的环境行为和生态毒性进行了综述.