氯过氧化物酶活性中心结构域中Mn2+与酶催化行为的关系

通过乙二胺四乙酸二钠(EDTA)配位竞争反应结合石墨炉原子吸收及电感耦合等离子体发射检测结果,为氯过氧化物酶(CPO)活性中心血红素丙酸根与金属Mn2+配位结合提供了更直接的证据;基于Mn2+移除前后CPO的紫外特征吸收光谱、圆二色谱以及氯化活性和过氧化活性的变化,阐明了Mn2+的存在对于保持酶活性中心的结构域、稳定CPO的优势构象具有一定作用,是酶分子表现活力所必需的结构元素.本研究还发现移除Mn2+前后CPO血红素活性中心微环境的变化是一个可逆过程,重新引入Mn2+后活性可恢复,并且以外源性Ag+和Cr3+替代Mn2+后,CPO的氯化活性和过氧化活性分别比天然态的酶有所改善,为通过化学修饰提高CPO的催化活性提供了新的途径.     

阳离子型温敏水凝胶的溶胀性能及其对表面活性剂的吸附行为

阳离子单体;温敏凝胶;阳离子型温敏水凝胶的溶胀性能及其对表面活性剂的吸附行为     

一种新二肟的合成及其电化学行为

修饰电极;一种新二肟的合成及其电化学行为     

多肽和蛋白质的反相高效液相色谱研究--色谱行为的多样性

以Ｃ８柱为固定相,研究了微管结合蛋白２中两段重要肽段（肽１,肽２）和猪胰岛素在反相色谱上的保留行为。当以甲醇溶液为流动相时,猪胰岛素保留因子的对数值（ｌｎＫ’）随流动相有机溶剂体积分数（ψ）的变化呈现很好的线性关系。当以乙腈为流动相测定肽１的ｌｎＫ’随ψ变化关系时,所得结果显示ｉｎＫ’与ψ呈现良好的二次曲线关系。以乙腈为流动相测定肽１和肽２和Ｖａｎ’ｔ Ｈｏｆｆ曲线（ｌｎｋ’与１／Ｔ的关系图）时,     

硒代胱氨酸在银电极上的电化学行为及其定量分析

研究了硒代胱氨酸 (SeCys)于0.03mol/L的硼砂 -NaOH( pH9.5)介质中在银电极上的电化学行为 ;实验发现在 -0.62V和 -0.68V(vsSCE)处存在一对氧化还原峰 ,其峰电流与硒代胱氨酸浓度具有良好的线性关系 ,由此建立了SeCys的电分析化学测定方法, (1)循环伏安法 ,其线性范围为8.6×10 -9～1.1×10 -7mol/L,检出限为4.3×10 -10mol/L, (2)二次微分线性扫描伏安法 ,其线性范围为2.2×10 -10～1.0×10 -8mol/L,检出限为8.6×10-11mol/L;该法应用于中药黄芪中SeCys含量的测定 ,结果令人满意 ;该文还探讨了硒代胱氨酸在上述条件下的电极反应机理     

镍纳米线电极的电化学氧化还原行为及其对乙醇的电化学氧化催化作用

镍电极;电池;电催化;镍纳米线电极的电化学氧化还原行为及其对乙醇的电化学氧化催化作用     

多氯代二苯并呋喃在不同色谱柱上的气相色谱保留行为——定量结构-色谱保留关系(QSRR)的研究

 以一种拟原子的方式处理多氯代二苯并呋喃 (PCDFs)异构体中的苯环 ,将PCDFs异构体中的原子或基团分为 3类 ,即 :氯原子 (Cl) (记为“1”) ,氧原子 (O) (记为“2”)及拟原子 (B) (记为“3”)。在烷烃分子距边矢量的基础上 ,提出一种以基团为基准的分子距离边数矢量 (μ矢量 ) ,借助多元线性回归方法分别建立了多氯代二苯并呋喃在不同色谱柱上的色谱保留指数与表征其结构的 μ矢量间的定量结构 色谱保留关系 (QSRR)相关模型。各样本总体所建模型的相关系数均在 0 98以上。     

颜料体积浓度对水在醇酸涂层中传输行为的影响

水、离子和氧气是导致涂层下金属发生腐蚀的三个重要因素,它们在涂层中的传输过程对其下面金属的腐蚀会产生较大的影响,研究它们在涂层中的传输过程对于弄清涂层下金属发生腐蚀的机制至关重要 .研究表明 [1－ 8], 水在涂层中的传输是一个扩散过程,分起始和饱和两个阶段;在起始阶段,随研究体系和实验条件的不同,水在涂层中的扩散过程遵循不同的规律,可能满足菲克第二扩散定律,也可能会发生较大的偏差 .　　颜料与基料界面间的孔隙是水在涂层中传输的主要通道,调整颜料体积浓度（ PVC）可以改变涂层中这种孔隙的数量和分布,从而…     

含羟基基团取代的氮氧自由基构筑的三个双核稀土化合物的结构及磁性表征

以三氟乙酰丙酮(tfac)为共配体的稀土配合物分别与5-溴-2-羟基苯取代的自由基配体和5-硝基-2-羟基苯取代的自由基配体进行反应,合成3个稀土-自由基配合物[Ln2(tfac)4(NIT-5Br-2PhO)2](Ln=Gd (1),Dy(2))和[Dy2(tfac)4(NIT-5NO2-2PhO)2](3)(NIT...     

基于混酸回流制备碳点的中和过程

Carbon dots (C dots) are relatively novel carbon nanomaterials that have attracted significant interest due to their unique photoluminescence, good biocompatibility, and stability. The preparation methods of C dots was usually summarized into "top-down" and "bottom-up", and mixed acid reflux is a top-down strategy that can be used to synthesize C dots, during which neutralization is a necessary step that can significantly influence the properties and potential applications of the final product. Previously, this research area mainly focused on tuning the properties of C dots by changing the starting materials and/or varying the reaction conditions; the influence of the reagents used during neutralization has been largely ignored. As the previously reported C dots prepared by mixed acid reflux were obtained from different starting materials under varied conditions, a meaningful comparison is difficult. Herein, yellow-emitting C dots were prepared by mixed acid-refluxing a carbon-rich material derived from fullerene carbon soot. For the same batch of as-prepared C dots, the influences of four reagents, i.e., NaOH, Na₂CO₃, K₂CO₃, and NH₃·H₂O, during neutralization on the structures and photoluminescence of the resulting C dots were investigated in detail. The results of thermogravimetric analysis, Fourier transform infrared spectroscopy, and X-ray photoelectron spectroscopy clearly showed that the reagent used during neutralization can affect the degree of dissociation of the acidic functional groups on the C dots. This is further supported by examination of the C dot/surfactant mixtures where subtle changes in the phase behavior were observed. Structural changes of the C dots cause variations in their surface states, ultimately altering the optical characteristics, including UV-vis absorption and fluorescence. Among the treated C dots, the sample prepared with Na₂CO₃ showed the strongest emission under the same excitation wavelength, while that prepared with NH₃·H₂O exhibited a distinct red shift (~8 nm) in the emission curve. The results presented herein provide clear evidence that neutralization reagent selection is important for optimizing the properties of the resulting C dots obtained by mixed acid reflux. In addition, the photoluminescence of the C dots can be influenced by their counterions, providing a novel method for tuning the properties of C dots while explaining their behavior in saline solutions. In short, the basicity of the neutralizing reagent and the type of counterions affect the structure of the C dots surface, which brings different performances. This work reminds researchers that it is necessary to use the type of neutralizing reagent as an experimental condition when preparing C dots in the future.