水溶性有机物电子转移能力与荧光峰强度的关系研究

以不同来源的水溶性有机物（DOM）为供试材料,采用电化学方法和荧光光谱法研究了DOM电子转移能力及其与荧光峰强度的关系.采用库仑安培法测定DOM电子转移能力,其中测得的电子接受能力为635.6～1 049.3μmol.（g.C）-1,电子供给能力为27.3～42.3μmol.（g.C）-1.利用循环伏安法研究DOM电化学活性,发现其氧化还原电位在-731～-996 mV（vs.Ag/AgCl）之间.经过电位跃阶法三次氧化还原循环后电子转移能力仍可维持在232.1～897.2μmol.（g.C）-1之间,电子循环率为36.7%～78.2%,说明DOM具有重复利用、反复转移电子的特性.采用荧光激发发射光谱法（EEMS）测定DOM的类富里酸荧光峰强度并比较其与DOM电子转移能力的关系,发现DOM的类富里酸荧光峰强度与DOM的电子循环率具有显著相关（r2=0.92）.实验结果为理解DOM在元素循环、污染物降解以及生物地球化学循环中的作用提供科学依据.     

雌激素受体作为壬基酚的主要作用靶点导致机体免疫毒性

雌激素作为一类重要的性腺类固醇化学信使,已经被证实能够直接调节机体免疫反应,因此,一些具有拟雌激素特性的环境内分泌干扰物(endocrine disruptors,EDs),会通过影响雌激素相关信号通路对免疫系统产生干扰作用。壬基酚(nonylphenol,NP)作为典型的环境内分泌干扰物,已有大量的文献报道其通过拟雌激素特性或干扰雌激素的合成、分泌、转运以及与靶点的结合,破坏机体生殖功能以及神经-免疫-内分泌系统,影响整体生理平衡与稳定。近年来,NP对免疫系统的干扰作用逐渐引起重视,研究发现,NP暴露会引起小鼠免疫器官及免疫细胞的发育异常,并且会导致新生小鼠肝毒性,肝脏细胞内炎性因子TNF-α、IL-1β分泌增加。除NP作为配体干扰雌激素信号通路外,尚未发现其他明确的分子机制解释NP造成的免疫毒性。本综述主要结合近年来相关的实验结果,总结了NP对免疫系统的潜在影响及其可能的分子机制。     

诺氟沙星对芽期玉米的毒性和氧化损伤研究

畜禽养殖废弃物的农田处置,使大量抗生素进入环境,从而对环境生物产生潜在危害.为了研究诺氟沙星(norfloxacin,Nor)对玉米发芽和幼苗生长的影响,采用水培发芽实验,测定了不同浓度下,诺氟沙星对玉米种子的发芽率和玉米幼苗对诺氟沙星的吸收与传输的影响;另外还研究了诺氟沙星对玉米幼苗生物量、自由基水平、丙二醛(MDA)含量、抗氧化酶活性的影响.结果显示,诺氟沙星能被玉米根吸收并传输到地上部分.0.5mg·L-1～50mg·L-1的诺氟沙星暴露均不影响玉米的发芽率.当诺氟沙星浓度大于1mg·L-1时,幼苗的生长受到抑制,其敏感指标依次为根重>根长>芽长>芽重.诺氟沙星暴露使玉米根、芽中MDA含量明显增加,玉米根中谷胱甘肽硫转移酶(GST),过氧化物酶(POD),超氧化物歧化酶(SOD)和过氧化氢酶(CAT)等抗氧化酶的活度有显著改变,这表明诺氟沙星暴露能够引起玉米体内的氧化损伤.用电子自旋共振结合二级自由基自旋捕获技术测定了玉米根中自由基水平,发现诺氟沙星能够引起玉米根中大量羟基自由基的产生,为诺氟沙星引起玉米幼苗的氧化损伤提供了直接的证据.     

好氧反硝化菌的脱氮特性研究与探讨

本论文对好氧反硝化菌株FR2,FX5,FW4在好氧条件下的反硝化特性进行了研究。结果表明：反硝化主要发生在菌体的对数生长期,且反硝化过程中NO2^--N有少量的积累。 对不同温度、pH、碳源对好氧反硝化作用的影响进行了研究,结果表明：该三株菌在好氧条件下均具有良好的反硝化效果;温度为25℃～30℃的中性和微碱性条件反硝化效果较好;以乙酸钠为碳源的反硝化效果最好,NO3^-N的去除率最高。以葡萄糖为碳源的反硝化效果最差,NO3^-N的去除率最低。     

厌氧氨氧化电子受体的研究

在无机条件下,以该课题组已经培养出来的厌氧氨氧化污泥作为接种污泥,分别以硫酸盐、硝酸盐和亚硝酸盐为电子受体来研究氨的氧化反应。从去除速率的角度来看,以NO2--N、NO3--N和SO42--S为电子受体的反应器,分别在运行的第24.5天、40天和31天时达到0.030 0 kg/(m.3d)NH4+-N去除速率,则氧化氨的能力由大到小依次是:亚硝酸盐>硫酸盐>硝酸盐;从标准吉布斯自由能变化来看,3种反应都是可以发生的;以亚硝酸盐为电子受体的反应过程是一个消耗酸度的生物过程,而以硫酸盐为电子受体的反应过程是一个消耗碱度的生物过程。     

介质阻挡放电降解环境污染物CF2ClBr的等离子体系电子密度

在利用介质阻挡放电对污染物质ＣＦ２ＣｌＢｒ进行等离子体降解产物分析的基础上,进一步研究等离子体系中的电子密度。采用动态反应装置,以平行板电极法直接测量。在ＣＦ２ＣｌＢｒ的压力为２ｋＰａ时,得出该实验条件下的电子密度约为５．０×１０＾１３／ｍ＾３。     

Hydroxytyrosol, the phenolic compound of olive oil protects human PBMC against oxidative stress and DNA damage mediated by 2,3,7,8-TCDD

The protective effect of hydroxytyrosol (HT), a strong antioxidant compound from extra virgin olive oil, against TCDD induced toxicity was investigated in human peripheral blood mononuclear cells (PBMC). PBMC (1 × 10⁶ cells mL⁻¹) were divided into four groups and were incubated in a CO₂ incubator (5% CO₂) for 12 h with vehicle, TCDD (10 nM), TCDD + HT (10 nM + 100 μM) and HT alone (100 μM) respectively. To clarify the role of HT against TCDD induced cytotoxicity, oxidative stress and the levels of antioxidant enzymes were assessed. Incubation of PBMC with TCDD significantly decreased cell viability, catalase (CAT) and glutathione peroxidase (GPx) and increased the levels of superoxide dismutase (SOD), glutathione reductase (GR) and oxidative stress markers such as lipid peroxidation products (LPO), protein carbonyl content (PCC) and reactive oxygen species (ROS). Whereas, HT had an effective antioxidant property as observed by the increased cell viability, normalization of antioxidant enzymes and decreased levels of LPO, PCC and ROS in PBMC co-treated with HT and TCDD. Apoptosis detection and comet assay results shows that HT, by acting as an antioxidant, prevents the damage to DNA induced by TCDD. In addition light microscopic and histopathological observations revealed that the cells are apoptotic and degenerated during TCDD treatment, whereas cells showed intact morphology during co-treatment with HT. On the whole, the results reveal that HT exerts a promising antioxidant potential in protecting the PBMC against TCDD induced oxidative stress, which might be due to the presence of catechol moiety in its structure.     

The Characterisation of Settled Dust by Scanning Electron Microscopy and Energy Dispersive X-ray Analysis

Settled dust has been collected inside the main foyers ofthree University buildings in Wolverhampton City Centre,U.K. Two of the three buildings are located in a streetcanyon used almost exclusively by heavy duty dieselvehicles. The dust was collected on adhesive carbonspectro-tabs to be in a form suitable for analysis byscanning electron microscope and energy dispersive X-rayanalysis. Using these analytical techniques, individualparticle analysis was undertaken for morphology andchemistry. Seasonal variations and variations due tolocation were observed in both the morphologicalmeasurements and chemical analysis. Many of the differencesappear attributable to the influence of road traffic, inparticular, the heavy duty diesel vehicles, travellingalong the street canyon.     

电子束辐照降解水中氯霉素的研究

本研究对氯霉素(CAP)在不同条件下的电子束辐照降解进行了研究.结果表明,电子束辐照可有效去除水中CAP,低浓度CAP在酸性条件下的辐照降解更为显著,且降解过程符合准一级动力学模型.通过添加不同的自由基清除剂,发现HO·在CAP降解中起关键作用,此外,CAP分子也会吸收辐照而发生分解.水中共存的阴离子和腐殖酸(HA)对CAP辐照降解均有抑制作用,这跟其与HO·的反应速率常数大小有关,并且反应速率越大,其抑制能力越强.CAP在去离子水中的去除率高于其他实际水体,但辐照剂量为4 k Gy时,污水厂污水过滤水和胶体浓缩液中的CAP也可分别去除89.1%和81.7%.利用GC-MS检测到辐照后溶液中有6种中间产物,主要是通过脱水、不对称中心断键和脱酰胺作用形成.此外,IC检测有Cl-、NO-3和NO-2的产生,并且TOC在一定程度上降低,说明部分CAP被矿化.     

Integrated energy view of wastewater treatment: A potential of electrochemical biodegradation

• Energy is needed to accelerate the biological wastewater treatment. • Electrical energy input in traditional technology is indirect and inefficient. • Direct injection of electricity can be a game changer to maximize energy efficiency. • Microbial electrochemical unit for decentralized wastewater treatment is proposed. It has been more than one century since the activated sludge process was invented. Despite its proven stability and reliability, the energy (especially the electrical energy) use in wastewater treatment should evolve to meet the increasingly urgent demand of energy efficiency. This paper discusses how the energy utilized in conventional biological wastewater treatment can be altered by switching the indirect energy input to a direct electricity injection, which is achieved by the electrode integration providing extra thermodynamic driving force to biodegradation. By using electrodes instead of oxygen as terminal electron acceptors, the electrical energy can be utilized more efficiently, and the key of direct use of electrical energy in biodegradation is the development of highly active electroactive biofilm and the increase of electron transfer between microbes and the electrode. Furthermore, the synergy of different microbial electrochemical units has additional benefit in energy and resource recovery, making wastewater treatment more sustainable.