C59XH (X＝N, B)自由基加成区域选择性的理论研究

用半经验的AM1方法, 对C₅₉XHCl_2n (X＝N, B; n＝1～2)和C₆₀H₂Cl_2n (n＝1～2)的异构体进行几何构型全优化和振动频率计算, 结合密度泛函B3LYP/6-31G*单点能计算确定各异构体的相对稳定性. 对比C₅₉XH (X＝N, B)和C₆₀H₂的H₂加成方式, 计算结果表明H₂或Cl₂加在碳笼官能化部分的邻近位置在能量上都是有利的; C₅₉NH和C₅₉BH自由基多加成物区域选择性的差别可归因于N原子和B原子电子性质的不同; 立体效应是导致H₂和Cl₂加成方式不同的主要原因.     

反离子对氟表面活性剂的影响1. 表面活性及胶团化作用

通过表面张力和荧光探针法研究了全氟辛酸钠、全氟辛酸铵以及全氟辛酸四烷基铵[C₇F₁₅COON(C_nH_2n+1)₄, n＝1, 2, 3, 4]的表面活性以及胶团化作用, 系统地讨论了各种反离子, 特别是反离子大小的影响. 结果表明, 与普通碳氢表面活性剂不同, 反离子对这类氟表面活性剂的表面活性以及胶团化作用有很大影响. 表面活性剂的临界胶束浓度(cmc)随反离子的增大而下降; 饱和吸附层中平均每个分子所占的面积则大致随反离子的增大而增大. 而表面张力的变化则较为复杂. cmc时的表面张力随反离子的增大先上升(从全氟辛酸铵到全氟辛酸四乙铵)后下降(从全氟辛酸四乙铵到全氟辛酸四丁铵). 通过反离子的空间位阻、疏水性、插入以及电荷屏蔽效应对上述结果做了解释.     

长链烷基季铵盐插层氧化石墨的结构变化

基于改进的Hummers法制备氧化石墨(GO),并以长链烷基季铵盐(C_nTAB)对其进行插层处理;通过改变C_nTAB的链长、浓度,得到系列C_nTAB/GO插层复合物。采用XRD和元素分析对产物的最大底面间距及C_nTAB插入量进行表征。结果表明,随着C_nTAB链长的增长、C_nTAB浓度的增大,C_nTAB/GO插层复合物的最大底面间距逐渐增大。C_nTAB通过离子键作用和疏水键作用插入到GO层间,在GO片层上的吸附规律符合修正型(Modified)Langmuir模型,即C_nTAB以单分子层吸附在GO片层上。根据C_nTAB/GO插层复合物最大底面间距及C_nTAB插入量的变化规律分析,得出C_nTAB在GO层间的排布模式有单层平躺模式、类双层平躺模式、单层倾斜模式和单层直立模式。     

硬脂酸改性纳米羟基磷灰石表面性能的研究

采用硬脂酸(C₁₇H₃₅COOH)对纳米羟基磷灰石(n-HA)表面进行处理,并研究了n-HA与C₁₇H₃₅COOH的界面作用。透射电子显微镜(TEM)、傅立叶红外光谱(FTIR)以及X光电子能谱(XPS)分析表明,C₁₇H₃₅COOH在n-HA表面黏附,其中羧酸根离子(-COO^-)与钙离子(Ca^2＋)之间形成了稳定的离子键,以羧酸钙形式存在。C₁₇H₃₅COOH改性后的n-HA与聚碳酸酯(PC)复合后,复合材料的力学性能与未改性n-HA相比有明显提高。扫描电子显微镜(SEM)结果显示,经处理后的HA微粒在PC中分散均匀,两者间结合紧密,无明显界面,复合材料的断裂呈明显的韧性断裂,随着n-HA无机粒子含量增加,复合材料的断裂也逐渐向韧性与脆性断裂共存转变。     

水在C12-EOx-C12•2Br/正己醇/正庚烷W/O微乳中的状态

以FT-IR方法研究了水/C₁₂-EO_x-C₁₂•2Br/正己醇/正庚烷形成的W/O微乳中水的状态. 结果表明, 其中的水存在4种状态, 分别为阳离子头基结合水、反离子结合水、类似本体的水以及束缚在微乳栅栏层中的水. 由解卷积技术分解FT-IR谱图, 进而获得每个表面活性剂分子对应于这4种状态水分子的数目n_N＋, n_Br-, n_b和n_f. 随着水含量(W₀)增加, n_b急剧增大, n_N＋少许上升, 而n_f和n_Br-维持不变, 这说明微乳水核逐渐长大, 且在所考察W₀范围内, 表面活性剂头基解离度保持不变.     

β-环糊精与十四烷基硫酸钠和全氟辛酸钠等摩尔混合体系的相互作用

通过¹H NMR和¹⁹F NMR相结合的方法研究了十四烷基硫酸钠(C₁₄H₂₉SO₄Na, STS)和全氟辛酸钠(C₇F₁₅COONa, SPFO)等摩尔混合体系与β-环糊精(β-CD)的相互作用. 实验发现, 尽管STS的临界胶束浓度(cmc)明显小于SPFO, 即在水溶液中STS的疏水性要强于SPFO, 但是β-CD仍首先选择性包结SPFO形成1∶1包结物, 然后随β-CD浓度增加主要生成STS的1∶1包结物, 最后STS的2∶1 (β-CD/STS)包结物和SPFO的2∶1 (β-CD/SPFO)包结物同时生成. 结合我们以前的工作, 本文表明, 随着碳氢表面活性剂烷基硫酸钠的链长(8～12)进一步增加到14, β-CD对氟表面活性剂SPFO的选择性进一步减弱. 也就是说, 由于β-CD的空腔和碳氟链更加匹配以及碳氟链的刚性使得β-CD/SPFO包结物的形成始终更为有利, 但这两类表面活性剂疏水性的差别对于这种选择性的程度会产生一定影响.     

色氨酸-镝(Ⅲ)配合物与鲱鱼精DNA的作用方式

采用UV光谱法、荧光光谱法,在pH=7.40的缓冲溶液中确定了镝(Ⅲ)与色氨酸的结合比n_Dy(Ⅲ)∶n_Trp=1∶3,Dy(Ⅲ)(Trp)₃配合物与鲱鱼精DNA的结合比n_{Dy(Ⅲ)(Trp)3}∶n_DNA=2∶1。用双倒数法确定了结合常数K_25℃=5.75×10⁴ L·mol^-1和K_37℃=3.27×10⁴ L·mol^-1。化学热力学研究显示配合物Dy(Ⅲ)(Trp)₃与hsDNA的结合为熵和焓共同驱动。结合Scatchard法和粘度法,确定了配合物Dy(Ⅲ)(Trp)₃与hsDNA之间主要为静电作用和嵌插作用。     

大气中HSO-3异构体的“量子化学后”研究

在量子化学计算的基础上，用统计热力学方法，计算了亚硫酸氢根离子的两种异构体HOSO^-₂(C_S)和HSO^-₃(C₃V)的热力学性质及它们相互转化的平衡常数(相对稳定性随温度的变化)等。通过计算数据的回归分析，给出了摩尔熵、摩尔热容等随温度变化的表达式。     

最大泡压法研究C12-2-Ex-C12•2Br在气/液表面的吸附动力学

用最大泡压法考察季铵盐Gemini表面活性剂C₁₂-2-E_x-C₁₂?2Br (x＝1, 2, 3)在气/液表面吸附动力学行为, 研究表明增加表面活性剂体相浓度和温度将加快分子扩散速度, 因此提高了表面吸附的动力学效果. 增加联接链长度x减小了分子预聚集倾向, 溶液中的单分子浓度增加, 有利于初始扩散, 使γ_t降低. 接近饱和吸附时, 由于x较大的单元分子在表面层占据的截面积也较大, 降低了表面层甲基端基的覆盖度, 相对升高了介平衡表面张力. 与对应的同头基同碳原子数的十二烷基三甲基溴化铵(C₁₂TABr)比较, C₁₂-2-E₁-C₁₂?2Br分子更倾向于吸附在表面层上.     

制备参数对高比表面积介孔催化剂La-Co-Zr-O结构与性能的影响

采用双表面活性剂模板(十六烷基三甲基溴化铵和聚乙二醇辛基苯基醚的混合物)分解法制备了不同原子比(n_La+n_Co)/(n_La+n_Co+n_Zr)和不同温度焙烧的系列介孔混合氧化物催化剂La-Co-Zr-O。运用XRD、N₂吸附/脱附、XPS和H₂-TPR等技术对催化剂进行了表征，并以CO和C₃H₈氧化为模型反应，考察了组分配比和焙烧温度等参数对催化剂催化性能的影响。比表面积和孔径测试结果表明，样品具有很高的比表面积(108～266 m²·g^-1)和分布集中的孔径(3.4～3.9 nm)，Zr含量较高的样品比表面积较大。XRD结果表明，样品中的活性组分钴物种主要以Co₃O₄形式存在；XPS和H₂-TPR结果表明，样品中可还原的晶格氧的数量、活动度以及表面钴原子浓度均与催化剂对CO和C₃H₈的氧化性能密切相关。原子比为0.5的样品中，较多的晶格氧易于在相对低温下还原；而原子比为0.7的样品表面钴原子浓度较高，这使得两样品均表现出较高的催化活性。经650 ℃焙烧的样品仍保持较高的比表面积(108 m²·g^-1)和分布集中的介孔孔径(最可几孔径约3.8 nm)，且催化活性下降幅度也很小，表明该系列介孔催化剂具有优良的抗烧结能力和介孔热稳定性。     

α-环糊精与季铵盐型双子表面活性剂包结作用的研究

在293.15 K下用微量热法结合核磁共振波谱研究了α-环糊精与三种阳离子型双子表面活性剂((CnN)2Cl2, n=12, 14, 16) 在水溶液中的包结作用. 实验结果表明, 包结物都相当稳定, 且随着疏水链CnH2n+1中碳原子数目的增加, 主-客体包结物的化学计量比由2∶1为主变为6∶1为主, 最大化学计量比的主-客体包结物形成过程的标准焓变(ΔHӨ) 和标准熵变(ΔSӨ) 均为负值且绝对值逐渐增大. 包结物的形成均属焓驱动过程. 1H核磁共振数据表明, (C12H25N)2Cl2的存在使α-环糊精上各质子的化学位移向高场移动, 从微观上证明了包结作用的发生.     

Studies on the binding of paeonol and two of its isomers to human serum albumin by using microcalorimetry and circular dichroism

Interactions of paeonol and two of its isomers with human serum albumin (HSA) in buffer solutions (pH 7.0) have been investigated by calorimetry and circular dichroism. Heats of the interactions have been determined with isothermal titration microcalorimetry at 298.15 K. Data process has been based on the supposition that there are several independent classes of binding sites on each HSA molecule for molecules of each one of the drugs. The results obtained by using this supposition combined with Langmuir adsorption model show that there are two classes of such binding sites. The binding constant, changes of enthalpy, entropy, and Gibbs free energy are obtained, which show that the two classes of binding are mainly driven by enthalpy except that the first-class binding of Ace is predominantly driven by entropy. On the same class of binding site, the negative value of binding enthalpy decreases in the order of Pae, Hma, and Ace. The difference of thermodynamic data is caused by the different locations of substituent groups on aromatic benzene ring of guest molecules. Circular dichroism (CD) spectra show that the three isomers change the secondary structure of HSA. These results indicate that the interaction includes contributions of the binding and the partial change of molecular structure of HSA induced by the three isomers.     

Detergent binding as a sensor of hydrophobicity and polar interactions in the binding cavities of proteins

To evaluate the role of hydrophobic and electrostatic or other polar interactions for protein-ligand binding, we studied the interaction of human serum albumin (HSA) and beta-lactoglobulin with various aliphatic (C10-C14) cationic and zwitterionic detergents. We find that cationic detergents, at levels that do not cause unfolding, interact with a single site on beta-lactoglobulin and with two primary and five to six secondary sites on HSA with an affinity that is approximately the same as that with which zwitterionic (dimethylamineoxide) detergents interact, suggesting the absence of significant electrostatic interactions in the high-affinity binding of these compounds. The binding affinity for all of the groups of compounds was dependent upon hydrocarbon chain length, suggesting the predominant role of hydrophobic forces, supported by polar interactions at the protein surface. A distinct correlation between the binding energy and the propensity for micelle formation within the group of cationic or noncharged (nonionic and zwitterionic) detergents indicated that the critical micellar concentration (CMC) for each of these detergent groups, rather than the absolute length of the hydrocarbon chain, can be used to compare their hydrophobicities during their interaction with protein. Intrinsic fluorescence data suggest that the two primary binding sites on serum albumin for the zwitterionic and cationic compounds are located in the C-terminal part of the albumin molecule, possibly in the Sudlow II binding region. Comparisons with previous binding data on anionic amphiphiles emphasize the important contribution of ion bond formation and other polar interactions in the binding of fatty acids and dodecyl sulfate (SDS) by HSA but not by beta-lactoglobulin. Electrostatic interactions by cationic detergents played a significant role in destabilizing the protein structure at high binding levels, with beta-lactoglobulin being more susceptible to unfolding than HSA. Zwitterionic detergents, in contrast to the cationic detergents, had no tendency to unfold the proteins at high concentrations.     

电动势法研究蛋白质与季铵盐Gemini表面活性剂的相互作用

利用自制的季铵盐Gemini表面活性剂二溴化-N,N′-二（二甲基十二烷基）丙二铵（C12-3-C12·2Br）离子选择电极,通过电动势(EMF)法研究了C12-3-C12·2Br与牛血清白蛋白(BSA)之间的相互作用,得到了C12-3-C12·2Br在BSA大分子上结合过程的结合等温线和对应的Scatchard曲线,并通过结合能力的概念得到了结合过程的结合位点数、Hill系数及Hill结合常数。通过研究发现,C12-3-C12·2Br与BSA大分子的结合具有正的协同作用,相互结合的位点可以分为两类,第一类为主要通过静电作用结合的强结合位点,第二类为主要通过疏水作用结合的弱结合位点。     

Binding of naproxen to bovine serum albumin and tryptophan-modified bovine serum albumin

Two classes of binding sites, a single high-affinity site with an association constant of 4·8×10⁶ M⁻¹ and two low-affinity sites with association constant of about 0·05×10⁶ M⁻¹ have been observed in the interaction of Naproxen with bovine serum albumin (BSA). Chemical modification of two tryptophan residues in BSA with 2-hydroxy-5-nitrobenzyl bromide has led to a reduction in the association constant of the high-affinity site by 89% and its number of binding sites by 66% suggesting the involvement of tryptophan residues in the high-affinity site. In contrast, the two low-affinity sites were not affected by the modification. Binding of Naproxen to the low-affinity sites of BSA induces microdisorganisation of the albumin structure leading to conformational changes as evident from fluorescence measurements with 1-anilino-8-naphthalenesulphonic acid as the probe.     

Studies on the Binding of Bis–Quaternary Ammonium Surfactants to Bovine Serum Albumins by Microcalorimetry and Circular Dichroism

The interactions of bovine serum albumin (BSA) with two cationic gemini surfactants, (C _n N)₂Cl₂ (n = 12, 14), in buffer solutions (pH = 7.0) were investigated by isothermal titration calorimetry (ITC) and circular dichroism (CD). CD spectra showed that the two surfactants change the secondary structure of BSA. The thermodynamic results suggest that there exist two binding types (high affinity/low affinity) in the interacting process of (C _n N)₂Cl₂ micelles with BSA. The high affinity binding is an endothermic process driven by entropy, in which the synergistic effect among weak interactions plays an important role. The low affinity binding is an exothermic process accompanied by positive entropy effect, in which hydrophobic interaction is dominant in all driving forces. Furthermore, corresponding binding site number of BSA for (C₁₄N)₂Cl₂ is much smaller than that for (C₁₂N)₂Cl₂, indicating that the hydrophobic chain length of surfactant plays a key role in low affinity binding process.     

Interaction Between Toddalolatone and Human Serum Albumin

A combination of fluorescence, UV–Vis absorption, circular dichroism (CD), Fourier transform infrared (FT-IR) spectroscopic and molecular modeling approaches was employed to investigate the interaction between toddalolactone (TDT) and human serum albumin (HSA) at physiological buffer conditions (pH 7.4). Fluorescence titration suggests that the mechanism of the fluorescence quenching of HSA is static, resulting from the formation of a TDT–HSA complex. Binding parameters calculated from the modified Stern–Volmer equation show that TDT binds to HSA with high affinity. Negative enthalpy change and positive entropy change values suggest that the binding process is primarily driven by hydrophobic interactions and hydrogen bonds. The binding of TDT to HSA results in an increase in the surface hydrophobicity of HSA. The binding distance between the Trp-214 residue (donor) and TDT (acceptor) was determined to be 4.18 nm based on the Förster theory of non-radioactive energy transfer. Displacement studies of site markers reveal that the binding site of TDT to HSA is located in the subdomain IIA (Sudlow’s site I). Furthermore, the molecular docking results corroborate and illustrate the specific binding mode and binding site. Analysis of UV–Vis absorption, CD and FT-IR spectra demonstrated that TDT induced a small alteration of the protein’s conformation.     

Thermodynamics of porphyrin binding to human serum albumin using affinity capillary electrophoresis

Summary The interaction thermodynamics of heptacarboxylporphyrin (HCP) and protoporhyrin (PP) with human serum albumin (HSA) was studied by affinity capillary electrophoresis (ACE) over the temperature range of 25–50°C, where HCP and PP bound to HSAvia 1:1 molecular association. The binding equilibrium constants (pH 7.4, phosphate buffer) for the binding of HCP with HSA were found to decrease with an increase in temperature, whereas the binding constants of the PP/HSA system appeared to be independent of temperature changes over the range studied. The van’t Hoff relationship (25–50°C) was found to be linear for the interaction of either HCP or PP with HSA. However, the interaction thermodynamics for both of these porphyrins with HSA were found to be quite different. In particular, the interaction of HCP (a hydrophilic porphyrin) with HSA appeared to be based on an enthalpy-driven process, whereas the binding between PP (a hydrophobic porphyrin) and HSA driven by a favorable change in entropy. The ability of using ACE to evaluate the interaction thermodynamics of serum proteins (e.g., HSA) with ligands (e.g., porphyrins and related compounds) should aid in the development of new and more effective photosensitizers in the photodynamic therapy of cancer.     

Spectroscopic and Isothermal Titration Calorimetry Studies of Binding Interactions Between Carbon Nanodots and Serum Albumins

Carbon nanodots (C-dots) have attracted great attention as a new class of luminescent nanomaterials. In order to better understand the basic behavior of C-dots in biological systems, the binding characteristics of C-dots with bovine serum albumin (BSA) and human serum albumin (HSA) were investigated using spectroscopic approaches and isothermal titration calorimetry at pH 7.4. We found that the intrinsic fluorescence of BSA and HSA was quenched by the C-dots with a dynamic quenching mode. It was proved that the C-dots had little influence on the conformation of BSA and HSA by their UV–vis and circular dichroism spectra. Some important thermodynamic parameters were calculated, and the positive values of ΔH° and ΔS° indicate that the binding process was endothermic, and that the interaction was driven by favorable entropy and unfavorable enthalpy. It also showed that the hydrophobic force played a major role in the binding process.     

抗肿瘤药物5-氟尿嘧啶与人血清白蛋白相互作用的热力学研究

在298.15 K下,根据本结合过程的假设和Langmuir结合理论, 用等温滴定微量热和圆二色谱分析法研究了抗肿瘤药物5-氟尿嘧啶(5-FU)与人血清白蛋白(HSA)的相互作用. 研究结果表明, 蛋白质(HSA)与药物配体5-氟尿嘧啶的相互作用存在两类结合位点. 第一类结合, 结合位点数N＝71±0.1, 结合常数 K＝(1.46±0.016)×10⁵ L•mol^－1, 结合焓ΔH＝(39.61±0.220) kJ•mol^－1, 结合熵ΔS＝(231.68±0.025) J•mol^－1•K^－1, 结合自由能ΔG＝(－29.48±0.030) kJ•mol^－1. 结合过程为熵驱动过程, 疏水相互作用是过程的主要推动力;第二类结合, 结合位点数N＝140±0.2, 结合常数 K＝(1.49±0.032)×10⁵ L•mol^－1, 结合焓ΔH＝(－19.31±0.103) kJ•mol^－1, 结合熵ΔS＝(34.30±0.055) J•mol^－1•K^－1, 结合自由能ΔG＝(－29.53±0.041) kJ•mol^－1, 结合过程为焓-熵协同驱动过程, 氢键和静电相互作用是过程的主要推动力. 圆二色谱分析结果表明, 在两类结合过程中, 药物5-氟尿嘧啶(5-FU)的作用致使蛋白质(HSA)二级结构单元的相对含量发生了变化.