时间分辨后化学发光同时测定林可霉素和卡那霉素

根据林可霉素、卡那霉素在过氧化单硫酸盐(PMS)-鲁米诺(Luminol)体系中的化学发光反应动力学性质的明显差异,建立了时间分辨后化学发光同时测定林可霉素和卡那霉素的新方法.在PMS-鲁米诺体系中林可霉素化学发光反应较快,0.8s达到最大值,峰尖锐;卡那霉素化学发光反应较慢,54.8s后达到最大值,峰平缓,且其动力学曲线呈现出随时间分开的两个独立的发光峰,互不干扰.该方法测定林可霉素、卡那霉素的线性范围分别为4.0×10-9～8.0×10-7 g/mL、4.0×10-7～8.0×10-5 g/mL,对8.0×10-8 g/mL的林可霉素溶液和8.0×10-6 g/mL的卡那霉素溶液进行测定,其相对标准偏差(RSD,n=11)分别为4.6％和3.3％,测定林可霉素和卡那霉素的检出限分别为1.0×10-9 g/mL和1.0×10-7 g/mL.     

化学氧化合成聚(苯胺-鲁米诺)复合纳米线的电化学发光特性研究

以过硫酸铵为氧化剂,通过氧化苯胺和鲁米诺混合溶液合成了聚(苯胺-鲁米诺)复合纳米线。相对于鲁米诺425 nm处的最大荧光发射波长,复合纳米线中聚鲁米诺的最大荧光发射波长明显红移到465 nm处。采用简单的滴凃方式将聚(苯胺-鲁米诺)复合纳米线修饰于石墨电极表面,形成一层稳定的聚(苯胺-鲁米诺)复合纳米线膜。此聚(苯胺-鲁米诺)纳米线膜修饰电极呈现出良好的电化学发光特性,H2O2对化学合成的聚(苯胺-鲁米诺)纳米线电化学发光呈现出增敏效应。在优化实验条件下,修饰电极的电化学发光信号与H2O2在5.0×10#9~1.0×10#5mol/L范围内呈线性关系,检出限为2×10#9mol/L。     

中性体系中鲁米诺电化学发光行为

研究了中性体系中鲁米诺的电化学发光行为。通过对Pt电极的预处理 ,以Br-为增强剂 ,在硼酸中性缓冲溶液中 ,0 .75V(vs .Ag)的正矩形脉冲激励下 ,得到鲁米诺良好的电化学发光信号。其强度在 2 .0× 10 -8～ 3.6× 10 -5mol/L之间与浓度存在定量关系 ;检出限可达 8.0× 10 -9mol/L。     

铁氰化钾-鲁米诺体系后化学发光反应及其分析应用研究-分子印迹-后化学发光法测定双嘧达莫

研究了双嘧达莫在铁氰化钾-鲁米诺化学发光反应体系中的后化学发光反应, 并在研究其反应的动力学性质、化学发光光谱、荧光光谱以及一些相关问题的基础上, 探讨了反应机理; 合成了双嘧达莫的分子印迹聚合物, 以此聚合物为分子识别物质, 利用铁氰化钾-鲁米诺-双嘧达莫后化学发光体系, 建立了测定双嘧达莫的高选择性分子印迹-后化学发光分析方法. 所建方法的线性范围为1.0×10-8-1.0×10-6 g/mL(r=0.999 2), 检出限为3×10-9 g/mL, 相对标准偏差为2.7%(1.0×10-7 g/mL双嘧达莫, n=11).     

聚鲁米诺-镍(Ⅱ)复合物自组装膜修饰电极电化学法测定氢氯噻嗪

基于鲁米诺的电聚合效应和该聚合物与镍离子的配位效应,利用层层自组装技术,聚鲁米诺-镍(Ⅱ)复合膜可以层层修饰在石墨电极表面。与电聚合修饰电极相比,氢氯噻嗪在该修饰石墨电极上能够更强烈地增敏鲁米诺弱电化学发光信号。据此,建立了一种高灵敏测定氢氯噻嗪的电化学发光分析新方法,同时也提出了利用自组装膜修饰电极改善电极表面电化学发光微环境从而提高其分析特性的新思路。该方法测定氢氯噻嗪的检出限为3.0×10-6g/L,线性范围为7.0×10-6~3.0×10-3g/L,相对标准偏差为2.3%(n=9)。     

地塞米松磷酸钠的流动注射-化学发光分析法的研究

实验了地塞米松磷酸钠在K3Fe（CN）6-鲁米诺、KMnO4-鲁米诺、KIO4-鲁米诺、H2O2-鲁米诺体系中的化学发光现象。结果表明,地塞米松磷酸钠能够显著增强K3Fe（CN）6-鲁米诺体系和KMnO4-鲁米诺体系的化学发光强度,而在另外两个体系中没有增强作用。结合流动注射技术,分别在K3Fe（CN）6-鲁米诺体系和KMnO4-鲁米诺体系中建立了测定地塞米松的新方法。方法的线性范围分别为1.0×10^-7-1.0×10^-5g/mL和6.0×10^-8-1.0×10^-5g/mL,检出限分别为3.0×10^-8g/mL和2.0×10^-8g/mL,相对标准偏差分别为1.6%和1.9%（1.0×10^-6g/mL地塞米松,n=11）。此法已用于针剂和片剂样品的测定,结果与药典方法没有显著性差异。     

基于聚(吡咯-鲁米诺-金)纳米复合材料的电化学发光传感器检测盐酸去氧肾上腺素

利用电沉积方法在石墨电极表面制备了聚(吡咯-鲁米诺-金)纳米复合材料,通过扫描电子显微镜(SEM)、电化学阻抗谱(EIS)、循环伏安法(CV)及电化学发光法(ECL)进行了表征。结果表明,采用电沉积方法可以将金纳米与聚(吡咯-鲁米诺)共同固定于电极表面;相对于聚(吡咯-鲁米诺)修饰电极,聚(吡咯-鲁米诺-金)修饰电极呈现出更强的ECL信号,且在中性介质中仍然有良好的ECL信号。盐酸去氧肾上腺素(PHE)对聚(吡咯-鲁米诺-金)修饰电极的ECL信号具有抑制作用,由此建立了一种在中性介质中测定PHE的ECL分析法。聚(吡咯-鲁米诺-金)修饰电极的ECL降低值与PHE浓度的对数值在1. 0×10~(-7)～1. 0×10~(-12)mol/L的范围内呈线性关系,检出限为2. 5×10~(-13)mol/L。     

鲁米诺-铁氰化钾化学发光体系测定甲基多巴

本文研究发现,铁氰化钾在碱性条件能氧化鲁米诺产生微弱的化学发光,而甲基多巴能大大增强该体系的发光强度.基于此,结合流动注射技术,建立起一种直接测定甲基多巴的流动注射化学发光新方法.该方法的检出限为5.7×10-10g/mL,甲基多巴浓度在1.0×10-9～1.0×10-7g/mL范围内与发光强度呈良好的线性关系.对1.0×10-9g/mL的甲基多巴平行测定11次,其相对标准偏差为2.3%.利用该方法对甲基多巴片剂含量的测定,结果令人满意.     

碱性溶液中鲁米诺电化学发光的研究

本文在自制的电化学发光仪上对鲁米诺的电化学发光行为进行了研究。发现在KOH-KCl(pH12.5)介质中,当Pt-Pt电极施加+1.2V(vs.SCE)的矩形脉冲时,可观察到鲁米诺的发光现象。发光强度与鲁米诺浓度在2.0×10~(-8)M-1.2×10~(-5)M范围内呈线性关系。鲁米诺的检测限达7×10~(-9)M。本文还研究了电学参数对鲁米诺发光的影响,并提出了其电化学发光的可能机理。     

流动注射阻抑化学发光法测定己烯雌酚

基于在碱性介质中,己烯雌酚对N-溴代丁二酰亚胺-鲁米诺化学发光体系的阻抑作用,建立了测定己烯雌酚的流动注射化学发光分析新方法,探讨并优化了流动注射化学发光的分析条件。该方法测定己烯雌酚的线性范围为1.5×10-8~2.6×10-7g/mL,检出限为5.0×10-9g/mL,对1.0×10-7g/mL的己烯雌酚标准溶液进行11次测定,相对标准偏差为2.6%。并应用于饲料、己烯雌酚片剂中的己烯雌酚的测定。     

在线衍生高效液相色谱法测定酱油中Pb~(2+)和Ni~(2+)的含量

建立了湿法消解处理样品,反相高效液相色谱在线衍生同时测定酱油中Pb~(2+)和Ni~(2+)含量的方法。以二乙基二硫代氨基甲酸钠(Na DDTC)为衍生试剂,Hypersil ODS2 C-18反相色谱柱(5μm,250 mm×4.6mm)为固定相,甲醇-水-衍生剂(体积比63.5∶35∶1.5)为流动相进行检测。结果显示,Pb~(2+)与Ni~(2+)的线性范围为0.5~50μg/m L,相关系数(r~2)分别为0.998 2和0.999 0,检出限分别为0.3μg/m L和0.2μg/m L,样品加标回收率为88.1%~91.8%。该方法操作简单,准确度和精密度较好,可作为酱油样品中重金属离子测定的替代方法。     

基于一次性薄层色谱电极高选择电化学发光分析法测定Ni(II)的研究

基于一种新的电极制作方法, 研制了具有薄层色谱分离功能的一次性薄层色谱电极. 结合该电极的分离、保留分析物于电极表面一定空间区域的色谱分离能力与电极表面电化学发光信号的空间分辨能力, 实现了分析物的高效分离与原位高灵敏度电化学发光(ECL)检测, 建立了电化学发光分析方法与薄层色谱分离方法联用的新技术. 并以Ni^2＋离子为代表探讨了这一方法的可行性和分析特性. 在最佳的实验条件下, 该方法测定Ni^2＋离子的线性范围为5.0× 10^－9～5.0×10^－6 g/mL, 检出限为1.5×10^－9 g/mL, 相对标准偏差为2.8% (c＝1.0×10^－6 g/mL, n＝11).     

一种香豆素类荧光探针的合成及其性能研究

本文设计合成了一种基于香豆素的荧光探针L,通过氢谱、质谱对其结构进行表征。该探针在DMSO/H_2O(体积比9∶1)体系中对Co~(2+)和Ni~(2+)具有较好的选择性和灵敏度。Co~(2+)和Ni~(2+)的加入使得探针L的荧光发射发生猝灭,其他金属离子未对探针的荧光产生明显的影响。探针L与Co~(2+)和Ni~(2+)的配位比均为1∶2,其对Co~(2+)和Ni~(2+)的检出限分别为1.002×10~(-7)和9.78×10~(-6) mol/L,结合常数分别是1.06×10~6和9.84×10~5 L·mol~(-1)。     

A Novel Electrogenerated Chemiluminescence Reaction Scheme Using Core-Shell LuminoI-Based SiO2 Nanoparticles as a Regulator and Its Analytical Application

A novel core-shell luminol-based SiO2 nanoparticle While these nanoparticles were used as electrogenerated was synthesized by two step micro-emulsion method. chemiluminescence （ECL） reagent, the electrochemical （EC） reaction as well as the subsequent chemiluminescence （CL） reaction not only could be separated spatially, but also presented high efficiency for analytical purpose. In this case, the core-shell luminol-based SiO2 nanoparticles offered more potential to avoid the contradiction between the EC and the CL reaction conditions. A new ECL method based on the nanoparticle was developed, and isoniazid was selected as a model analyte to illustrate the characteristics of this new ECL method. Under the selected conditions, the proposed ECL response to isoniazid concentration was linear in the range of 1.0 ×10^-10 to 1.0 × 10^-6 g/mL with 2 × 10^-11g/mL detection limit.     

大孔型腐植酸树脂的合成及其对重金属离子的螯合性

交联的聚苯乙烯(PS)通过偶氮键—N=N—或酯、醚键与腐植酸(HA)相连接枝得珠状大孔型腐植酸树脂(HAR)。当HA/PSNH_2的重量比为0.7—1.0,PSN_2~+Cl~-偶联PH13时制得的偶氮型腐植酸树脂(AHAR)对重金属离子有优良的吸附性。延长PSCH_2Cl与HA的反应时间可提高酯醚型腐植酸树脂(EHAR)对Cu~(2+)的吸附量。红外光谱探讨了HAR的结构。AHAR的吸附容量为1.01mmol~(2+)Cd/g树脂,对Ni~(2+)、Mn~(2+)、Cu~(2+)、Co~(3+)、Zn~(2+)为0.6—0.53mmol离子/g树脂。重金属离子在AHAR上的分配系数为 Cu~(2+)(8.7×10~3)>Cd~(2+)(3.8×10~2)>Zn~(2+)(2.4×10~2)>Ni~(2+)(1.8×10~2)>Mn~(2+)(4.9×10)。 pH6.5时AHAR能定量吸附Cu~(2+)、Cd~(2+)、Ni~(2+)、Mn~(2+),并能用INHNO_3定量洗脱。AHAR可再生,重复使用,分析了四种天然水、自来水中痕量上述金属离子的浓度。     

Highly Sensitive Electrochemiluminescence Detection of Mercury(II) Ions Based on DNA‐Linked Luminol‐Au NPs Superstructure

A novel highly sensitive electrochemiluminescence (ECL) detection protocol for mercury(II) ions was developed. Based on the strong and stable thymine? thymine mismatches complexes coordination chemistry, mercury(II) ions can specifically bind to a designed DNA strand, leading to the release of the complimentary DNA strand. The released DNA strand was then captured by magnetic beads modified with specific DNA, and then through the formation of DNA‐linked luminol‐Au nanoparticles (NPs) superstructure, a specific ECL system for mercury(II) ions was developed. Using 3‐aminopropyl‐triethoxysilane as an effective enhancer, the ECL system can detect Hg²⁺ ion within a linear range from 2.0×10^?10 mol L^?1 to 2.0×10^?8 M, with a detection limit as low as 1.05×10^?10 M (3σ). Moreover, this ECL system is highly specific for Hg²⁺, without interference from other commonly coexisted metal ions, and it can be used for the analysis of real samples.     

十二烷基苯磺酸钠-盐酸苯海索-Ru(bpy)2+3体系的电化学发光行为研究及应用

在十二烷基苯磺酸钠(SDBS)存在下,考察了盐酸苯海索(BH)-Ru(bpy)32+体系的电化学及其发光行为。结果表明,BH对Ru(bpy)32+体系的电化学发光具有增敏效应;在SDBS存在下,BH对Ru(bpy)32+体系电化学发光的增敏效应显著增强,发光强度提高约16倍。据此建立了一种高效、简便的BH电化学发光新方法。在最佳实验条件下,BH的浓度在4.0×10-7～1.0×10-4 mol/L范围内与相对发光强度呈线性关系(r=0.995 5),检出限(S/N=3)为1.11×10-9 mol/L;连续平行测定1.0×10-5 mol/L BH溶液10次,发光强度的RSD为3.2%。样品的回收率为96%～108%,RSD为4.3%。该方法样品前处理简单,具有较高的选择性和灵敏度,用于实际样品中BH的测定,结果满意。     

Electrogenerated Chemiluminescence (ECL) Determination of Ephedrine with a Self-Assembly Multilayer Ni(II)-Polyluminol Modified Electrode

By combining the layer-by-layer (LBL) self-assembly technique with the electrochemical polymerization method, multilayer Ni(II)-polyluminol films were modified on the surface of a vaseline-impregnated graphite electrode. It was found that, compared with an electrode modified by direct electrochemical polymerization, this modified electrode offered a suitable ECL reaction micro-environment created by the special multilayer films, which was beneficial to the ephedrine hydrochloride enhancing effect for luminol ECL intensity. The ECL enhancing effect of ephedrine hydrochloride on the electro-oxidation luminol was improved on this modified electrode. Based on this finding, a new sensitive ECL method was developed for ephedrine hydrochloride determination under the optimal conditions. At the same time, a new idea is proposed for improving the analytical performance of the luminol ECL system by modifying the ECL reaction micro-environment with the layer-by-layer self- assembly method. Under the optimum experimental conditions, the ephedrine hydrochloride concentration in the range of 2.0 × 10⁻⁸–7.0 × 10⁻⁶ mol L⁻¹ was proportional to the enhanced ECL signal, and it offered an 8.0 × 10⁻⁹ mol L⁻¹ detection limit for ephedrine hydrochloride.     

Electrochemiluminescence Characterization of Poly(luminol‐benzidine) Composite Films and Their Analytical Application

A composite film of poly(luminol‐benzidine) was prepared on the graphite electrode surface by electropolymerizing luminol and benzidine in acidic medium. It was found that the poly(luminol‐benzidine) composite film presented better electrochemiluminescence (ECL) analytical performances for H₂O₂ than that of the polyluminol film. Based on these findings, a more sensitive ECL sensor for H₂O₂ was developed. At the same time, our investigating results on this composite film revealed that, as a real ECL luminophor in this composite film, the polymeric 3‐aminophthalate presented higher fluorescence quantum yield than that in the pure polyluminol film, which suggested that the excellent ECL performances of the composite film may originate from the enhancement of the ECL luminophor quantum yield. Based on these results, a new method to improve the ECL analytical performances of the polymeric luminol was also proposed.     

Application of capillary electrophoresis coupling with electrochemiluminescence detection to estimate activity of leucine aminopeptidas

A new method to estimate the leucine aminopeptidase (LAP, EC 3.4.11.1) activity using capillary electrophoresis coupled with electrochemiluminescence (ECL) is described. The liberated proline produced by LAP catalyzing the hydrolysis reaction of leucin–proline was used as an ECL coreagent to enhance Ru(bpy)₃²⁺ ECL signals efficiently. The detection limit for proline was 2.88 × 10^?6 m (signal‐to‐noise ratio 3), which was equal to 9.60 × 10^?8 units of LAP being used to catalyze leucin–proline for 1 min. The Michaelis constant K_m (2.07 × 10^?2 mol/L) and the maximum reaction velocity V_max (1.06 × 10^?5 mol/L/min) of LAP for leucin–proline are reported. The reaction conditions including the concentration of metal ions, incubation temperature and pH were optimized. This method was successfully applied to detect LAP activity in plasma and the results were in good agreement with that obtained by the clinical method. Copyright © 2013 John Wiley & Sons, Ltd.