溶解性有机物与活性氯物种反应过程中其分子组成对消毒副产物生成的影响

溶解性有机物(DOM)在紫外/氯(胺)高级处理过程中会与活性氯物种(Cl^(·)和Cl_(2)^(·-))反应生成消毒副产物(DBPs),进而影响水质的毒性和安全性。本研究详细研究了单一活性氯物种(Cl^(·)或Cl_(2)^(·-))与不同来源DOM反应生成DBPs的情况,重点探究了DOM分子组成与生成DBPs质量浓度、种类、毒性之间的相关关系。结果表明:Cl^(·)与DOM反应过程中主要生成的DBPs及毒性贡献者分别为三卤甲烷(THMs)和卤乙醛(HALs)。DOM的分子组成与生成DBPs的质量浓度、种类及毒性之间相关性较低,这可能归因于Cl^(·)与不同DOM之间相似的反应活性,而在Cl_(2)^(·-)与DOM反应过程中HAAs和非管制类DBPs分别为主要生成的DBPs和毒性贡献者。此外,生成DBPs的质量浓度、种类及体系的毒性与DOM分子的不饱和度、芳香度、含氧量、极性呈负相关,与DOM中含N、S、P官能团化合物的相对含量呈正相关。本研究推动了DOM在单一活性氯物种介导下生成DBPs的研究,并为高级氧化工艺参数的优化及高毒性副产物的消减提供依据。

阳极材料对电氧化及其耦合UV处理酸性氨氮废水的影响分析

线路板制造等行业生产加工过程中会产生酸性氨氮废水,传统的生物硝化/反硝化、物理分离、折点加氯等方法不适用于酸性条件处理.电氧化体系具有pH适应性广、药剂投加量小、绿色高效等优势,是处理酸性氨氮废水的潜在应用技术.电极材料是电化学处理氨氮废水的关键因素之一,系统探讨酸性水质影响下不同阳极的除氨性能具有实际指导意义.本研究考察Ti/RuO_(2)-IrO_(2)、Ti/PbO_(2)、Ti/SnO_(2)-Sb等3种商业电极在酸性环境下电氧化及其耦合UV体系降解氨氮性能差异,并通过分析造成差异的原因,推测酸性氨氮废水处理中UV协同强化机制.结果表明:(1)阳极析氯性能是酸性氨氮废水降解的关键因素之一,Ti/SnO_(2)-Sb阳极在pH=2时游离氯积累量为145.0 mg·L^(-1),分别是Ti/RuO_(2)-IrO_(2)阳极与Ti/PbO_(2)阳极的2.13倍及1.95倍,相对应其氨氮去除速率为Ti/RuO_(2)-IrO_(2)阳极的2.79倍,Ti/PbO_(2)阳极的1.90倍;(2)UV的引入加速了酸性氨氮废水处理,电氧化耦合UV体系较电氧化体系氨氮降解速率提高了1.98-2.67倍,结合掩蔽实验和电子顺磁共振表征,证明氯自由基物种在电氧化耦合UV体系氨氮氧化过程起到关键作用;(3)3种电极电氧化耦合UV体系实现了金属冲洗废水和氨气吸收塔清洗废水两股实际酸性废水中氨氮的有效处理;(4)尽管Ti/SnO_(2)-Sb阳极单次氧化氨氮性能最佳,但是其稳定性最差,通过比较3种阳极不同体系下去除1kgNH_(4)^(+)-N的阳极耗损费用,发现Ti/PbO_(2)相较其余两种阳极成本减少10.24-271.17倍.

Gadolinium-promoted angiogenesis involves the activation of PKCα/β_2 and MAPKs in human umbilical vein endothelial cells

Gadolinium has been widely used as a contrast agent for magnetic resonance imaging in clinical practice. Recently, it was reported that gadolinium is involved in nephrogenic systemic fibrosis, although the exact mechanism by which gadolinium triggers nephrogenic systemic fibrosis remains unclear. In this study, we show that gadolinium chloride （GdC13） induced human umbilical vein endothelial cells （HUVECs） to migrate in Matrigel and tubulogenesis during wound healing. Chick chorioallantoic membrane assay confirmed that GdC13 stimulates angiogenesis. Under the optimal angiogenic concentration of GdC13 （1 0 ~tM）, intracellular calcium concentration and reactive oxygen species generation were elevated. Moreover, western blotting results indicate that in cells treated with GdC13, Ca2＋-dependent PKCa/132 was phosphorylated, and MAPKs pathways were also activated. Taken together, GdC13 has a potential effect on angiogenesis in HUVECs, and the possible mechanisms may involve oxidative stress and calcium-related signalin~ pathways.