L-(8-羟基-5-甲基喹啉)半胱氨酸修饰电极的制备及其对汞离子选择性检测

利用Shifft碱反应将L-半胱氨酸和5-甲酰基-8-羟基喹啉一步合成L-(8-羟基-5-甲基喹啉)半胱氨酸,通过金-硫键将L-(8-羟基-5-甲基喹啉)半胱氨酸自组装到金电极表面制备L-(8-羟基-5-甲基喹啉)修饰金电极。L-(8-羟基-5-甲基喹啉)半胱氨酸分子中的羟基氧和氮可与Hg2+形成稳定的五元环配合物,因此该修饰电极能选择性吸附Hg2+,结合方波伏安法用于Hg2+电化学检测。在0.01mol/L HCl中,富集时间为160s,Hg2+浓度在1.0×10-9~1.0×10-8 mol/L、1.0×10-8~1.0×10-7 mol/L浓度范围内与方波伏安峰电流分段呈现良好的线性关系,检出限为0.92×10-9 mol/L。     

纳米金修饰的碳纤维超微电极在高浓度抗坏血酸体系中选择性测定多巴胺

将柠檬酸三钠与硼氢化钠还原氯金酸制备纳米金颗粒,采用一步恒电位沉积的方法在碳纤维超微电极上沉积纳米金颗粒,并对电极进行电化学表征。分别对100μmol/L DA、1mmol/L AA在该电极上修饰前后的电化学行为进行了研究,结果表明在浓度为1 mmol/L抗坏血酸共存下,DA的浓度(0. 1～10μmol/L)与氧化峰电流成正比,线性回归方程为Ip(μA)=200 c(μmol/L)+2×10~(-4),相关系数R~2=0. 9979,线性范围0. 1～10μmol/L,检出限为1. 28×10~(-2)μmol/L (S/N=3)。方法可用于较高浓度抗坏血酸共存下对多巴胺的选择性测定。     

荧光金纳米团簇的制备及其在铜离子检测中的应用

在水溶液中以谷胱甘肽(Glutathione,GSH)为稳定剂和还原剂,制备了具有较好荧光性能的金纳米团簇(GSH-AuNCs),对其结构和荧光性能等进行了表征。基于Cu2+对该GSH-AuNCs的荧光具有选择性猝灭作用建立了一种快速且简便的检测痕量Cu2+的方法。考察了检测体系中GSH-AuNCs的浓度、反应时间、pH值等因素对测定的影响。结果表明,在最优实验条件下,GSH-AuNCs的荧光强度与Cu2+的浓度分别在5.0×10-9～4.0×10-6 mol/L(R=0.9940),4.0×10-6～2.0×10-5 mol/L(R=0.9950)范围呈良好线性关系,检出限(S/N=3)为2.0×10-9 mol/L。该方法成功地应用于实际水样中Cu2+的检测。     

基于碳点荧光恢复法测定生物巯基化合物

碳点(CDots)是一种新型荧光纳米材料,Cu2+可以有效猝灭其荧光;而当有生物巯基化合物存在时,碳点-Cu2+体系的荧光可以恢复.基于此原理,我们成功地构建了检测生物体内总巯基化合物的新方法.该方法具有很好的选择性,常见氨基酸和金属离子对谷胱甘肽(GSH)、半胱氨酸(Cys)和高半胱氨酸(Hcy)的检测无影响.最佳实验条件下,谷胱甘肽、半胱氨酸、高半胱氨酸的浓度在6.0×10-6mol/L～1.0×10-4mol/L与相对荧光强度呈线性,R>0.996,检出限为2.0×10-6mol/L.该体系成功用于血清样品中总巯基化合物的检测.     

基于纳米金对荧光素的内滤光效应检测半胱氨酸

基于纳米金对荧光素的内滤光效应,建立了一种新型高灵敏、高选择性测定半胱氨酸的分析方法。将具有较大摩尔吸光系数的纳米金选为吸收体,荧光素的荧光光谱与纳米金的吸收光谱能很好地重叠,作为荧光发光体。在选定的实验条件下,荧光素荧光强度的增加值与半胱氨酸的浓度在5.0×10-8～1.0×10-6mol/L范围内呈良好的线性关系,检测限为1×10-8mol/L。     

半胱氨酸在Ag2S/Cu2S纳米晶修饰玻碳电极上的电化学行为

制备了Ag2S/Cu2S纳米混晶修饰玻碳电极,研究了半胱氨酸在Ag2S/Cu2S纳米混晶修饰电极上的电化学行为.结果表明:Ag2S/Cu2S混晶修饰电极对半胱氨酸的电化学氧化过程具有非常明显的电催化作用,其氧化电位减小为0.23V,氧化峰电流为25.98 μA,与空白电极相比增加了8倍.在1.0×10-5～1.0×10-3 mol/L浓度范围内,稳态电流信号与半胱氨酸浓度呈现良好的线性变化关系.该修饰电极具有良好的稳定性和重现性.     

基于胆碱修饰层为基底的纳米金固定过氧化物酶修饰电极的研究

玻碳电极上共价修饰上单分子层胆碱(Ch)可以显著提高电极的活性。本研究利用该电极上胆碱层带有的正电荷,牢固吸附带负电荷的纳米金溶胶,继而利用纳米金颗粒良好固载辣根过氧化物酶(HRP),制备出了基于HRP酶直接电化学的H2O2传感器。以阻抗谱、循环伏安等方法表征了修饰电极的性质。结果显示,该电化学传感器具有良好的催化活性,电活性HRP的表面浓度(Γ*)为1.2×10-9mol/cm2,米氏常数KMapp=1.55±0.11 mmol/L。该修饰电极在H2O2浓度1.2×10-6~3.2×10-3mol/L范围内有线性响应,检出限(S/N=3)为4.0×10-7mol/L。本修饰电极制备简单,选择性高,稳定性好,可以作为进一步构筑生物传感器的基础。     

纳米金复合薄膜的制备及铅离子肉眼检测方法的构建

基于2-巯基乙醇-硫代硫酸钠-纳米金/Pb2+(2-ME-Na2S2O3-AuNPs/Pb2+)体系的纳米金浸出反应,开发了一种低成本、可通过肉眼灵敏检测Pb2+的纳米复合薄膜。优选出聚酰胺-6(PA-6)层析薄膜,通过吸附牛血清白蛋白(BSA)修饰的纳米金(AuNPs),制备得到一种色泽均匀的BSA-AuNPs/PA-6纳米复合薄膜。考察了PA-6薄膜吸附BSA-AuNPs的时间,2-ME-Na2S2O3-AuNPs/Pb2+反应体系中2-ME和Na2S2O3的浓度,以及反应温度和反应时间对Pb2+检测的影响。结果表明,在优化条件下,吸附30 min后,0.05 mol/L的Na2S2O3及0.25 mol/L的2-ME在80℃下反应20 min,即可通过肉眼实现对Pb2+的检测,灵敏度可达2.0×10-8mol/L;同时,该方法具有高选择性。将BSA-AuNPs/PA-6纳米复合薄膜应用于自来水中Pb2+的检测,通过肉眼判断,检出限可达到5.0×10-8mol/L。     

巯基功能化有机硅纳米颗粒修饰金电极的制备及对痕量铅的测定

以3-巯丙基三甲氧基硅烷(MPTS)为单一硅源,十六烷基三甲基溴化铵(CTMAB)存在下,采用一步简单混合,较方便地制得均匀、小粒径的有机硅纳米颗粒。采用原子力显微镜(AFM)、透射电子显微镜(TEM)对有机硅纳米进行表征,测得粒径约为2.5 nm。通过自组装法将其固定在金电极表面,得到均匀、高巯基含量的有机硅纳米修饰电极。采用方波溶出伏安法(SWV),考察了CTMAB浓度、Bi3+浓度、支持电解质、pH值富集电位及富集时间等参数对铅溶出信号的影响。结果表明:在0.2 mol/L HAc-NaAc(pH 5.0)缓冲溶液中,-1.0V电位下富集10 min,Pb2+溶出峰电流与浓度分别在5.0～500×10-12mol/L;2.5～250×10-9 mol/L和250～1250×10-9 mol/L范围内呈线性关系,最低检出浓度为5.0×10-12mol/L。利用本方法测定了实际水样中铅的含量,并与原子荧光光谱法进行对比,结果一致。     

纳米金/三聚氰胺修饰电极检测亚硝酸盐

采用电聚合方法制备三聚氰胺(MA)膜修饰玻碳电极(GCE),然后采用原位恒电位沉积法制备金纳米颗粒(Au),并将其修饰于膜电极表面,制得纳米金/三聚氰胺修饰玻碳电极(Au/MA/GCE)。用扫描电子显微镜(SEM)对修饰电极进行表面形貌和元素成分分析。用循环伏安法研究亚硝酸根(NO2-)在该修饰电极上的电化学行为发现,NO2-在0.85 V出现一灵敏的氧化峰。在优化的实验条件下,NO2-在1.0×10-5～1.0×10-3mol/L浓度范围内与其氧化峰电流成线性关系,检测下限为8.9×10-7mol/L。将修饰电极用于实际样品中NO2-的检测,效果良好。     

Furyl- and thienyl-silatranes and germatranes

We review our research on the synthesis and study of the physical and biological properties of furyl- and thienylgermatranes and -silatranes.Translated from Khimiya Geterotsiklicheskikh Soedinenii, No. 6, pp. 725–732, June, 1992.     

Review and patents and literature

The use of the insect cell/baculovirus expression system for producing recombinant proteins of bacterial, plant, insect, and mammalian origin has become widespread. The popularity of this eukaryotic expression system is due to many factors, including (1) potentially high protein expression levels, (2) ease and speed of genetic engineering, (3) ability to accommodate large DNA inserts, (4) protein processing similar to higher eukaryotic cells (e.g., mammalian cells), and (5) ease of insect cell growth (e.g., suspension growth). The following review of the literature discusses two engineering aspects of recombinant protein synthesis by insect cell cultures: bioreactor scale-up and insect cell line selection. Following this review patent abstracts and additional literature pertaining to expression of recombinant proteins in insect cell culture are listed.     

Hard and soft acids and bases: structure and process

Under investigation is the structure and process that gives rise to hard-soft behavior in simple anionic atomic bases. That for simple atomic bases the chemical hardness is expected to be the only extrinsic component of acid-base strength, has been substantiated in the current study. A thermochemically based operational scale of chemical hardness was used to identify the structure within anionic atomic bases that is responsible for chemical hardness. The base's responding electrons have been identified as the structure, and the relaxation that occurs during charge transfer has been identified as the process giving rise to hard-soft behavior. This is in contrast the commonly accepted explanations that attribute hard-soft behavior to varying degrees of electrostatic and covalent contributions to the acid-base interaction. The ability of the atomic ion's responding electrons to cause hard-soft behavior has been assessed by examining the correlation of the estimated relaxation energies of the responding electrons with the operational chemical hardness. It has been demonstrated that the responding electrons are able to give rise to hard-soft behavior in simple anionic bases.     

Ground- and excited-state aromaticity and antiaromaticity in benzene and cyclobutadiene

The aromaticity and antiaromaticity of the ground state (S 0), lowest triplet state (T 1), and first singlet excited state (S 1) of benzene, and the ground states (S 0), lowest triplet states (T 1), and the first and second singlet excited states (S 1 and S 2) of square and rectangular cyclobutadiene are assessed using various magnetic criteria including nucleus-independent chemical shifts (NICS), proton shieldings, and magnetic susceptibilities calculated using complete-active-space self-consistent field (CASSCF) wave functions constructed from gauge-including atomic orbitals (GIAOs). These magnetic criteria strongly suggest that, in contrast to the well-known aromaticity of the S 0 state of benzene, the T 1 and S 1 states of this molecule are antiaromatic. In square cyclobutadiene, which is shown to be considerably more antiaromatic than rectangular cyclobutadiene, the magnetic properties of the T 1 and S 1 states allow these to be classified as aromatic. According to the computed magnetic criteria, the T 1 state of rectangular cyclobutadiene is still aromatic, but the S 1 state is antiaromatic, just as the S 2 state of square cyclobutadiene; the S 2 state of rectangular cyclobutadiene is nonaromatic. The results demonstrate that the well-known "triplet aromaticity" of cyclic conjugated hydrocarbons represents a particular case of a broader concept of excited-state aromaticity and antiaromaticity. It is shown that while electronic excitation may lead to increased nuclear shieldings in certain low-lying electronic states, in general its main effect can be expected to be nuclear deshielding, which can be substantial for heavier nuclei.     

Determination and study on residue and dissipation of benazolin-ethyl and quizalofop-p-ethyl in rape and soil

A QuEChERS (quick, easy, cheap, effective, rugged, and safe) method for the determination of benazolin-ethyl and quizalofop-p-ethyl in rape and soil by high-performance liquid chromatography-tandem mass spectrometry has been developed in this study. The residue and dissipation of benazolin-ethyl and quizalofop-p-ethyl in rape and soil were determined with the developed method. The half-lives of benazolin-ethyl in rape straw and soil were 3.7–5.1 days and 14.3–26.3 days, respectively. The half-lives of quizalofop-p-ethyl in rape straw and soil were 5.0-6.1 days and 0.3–9.7 days, respectively. The residue of benazolin-ethyl and quizalofop-p-ethyl in rapeseed and soil were below the detection limit (i.e., 0.5?mg?kg^?1, the maximum residue level of European Union for quizalofop-p-ethyl).