铁氰化钾-鲁米诺体系后化学发光行为的研究-流动注射后化学发光法测定可待因

发现了可待因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。优化了反应条件,建立了一种利用后化学发光反应测定可待因的流动注射化学发光新方法。方法的检出限为3×10-8g mL,相对标准偏差为1.9%(1.0×10-6g mL可待因,n=11),线性范围为8.0×10-8～1.0×10-5g mL。此法已用于可待因片剂中可待因的测定,结果与药典方法测定值一致。     

高碘酸钾-鲁米诺后化学发光反应的研究——流动注射-后化学发光法测定异烟肼

实验发现了异烟肼在高碘酸钾-鲁米诺化学发光反应体系中的后化学发光反应。在对这一后化学发光反应的动力学性质、化学发光光谱、荧光光谱、紫外可见吸收光谱以及一些相关问题研究的基础上,讨论了其可能的反应机理;建立了利用此后化学发光反应测定异烟肼的流动注射化学发光新方法。方法的线性范围为1.0×10-9~4.0×10-7g/mL,检出限为6×10-10g/mL,对5.0×10-8g/mL的异烟肼进行11次平行测定的相对标准偏差为1.7%。此法已用于异烟肼片剂中异烟肼含量的测定,结果与药典法测定值一致。     

流动注射化学发光法测定没食子酸

基于在碱性介质中,没食子酸(Gallicacid)被过氧化氢氧化能产生化学发光,而甲醛对该体系的化学发光有较强增敏作用,据此建立了流动注射化学发光法测定没食子酸的新方法。该法简单、快速、线性范围较宽。本法测定没食子酸的线性范围为2.0×10-6～2.0×10-4g/mL,检出限达5.8×10-7g/mL,采样频率为120个/小时。对4.0×10-5g/mL没食子酸溶液连续11次测定的相对标准偏差为2.52%。该方法已成功地用于橄榄中没食子酸含量的测定。     

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).     

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.     

反向流动注射化学发光法测定痕量硫离子

在碱性条件下,基于硫离子对鲁米诺和高碘酸钾化学发光反应有很强的增敏作用,建立了反向流动注射化学发光法检测水中痕量硫离子的新方法。在优化实验条件下,硫离子浓度在8.0×10-10~5.0×10-6g/mL范围内与发光强度呈良好的线性关系;检出限(3σ)为2.0×10-10g/mL;相对标准偏差为2.3%(n=11,1.0×10-8g/mLS2-)。该方法用于环境水样中S2-的测定,结果令人满意。     

流动注射化学发光抑制法测定吡罗昔康

基于吖啶橙在氢氧化钠介质中能被高锰酸钾氧化产生较强的化学发光,吡罗昔康能强烈抑制其化学发光,建立了高锰酸钾-吖啶橙-吡罗昔康化学发光抑制测定吡罗昔康的新方法。吡罗昔康在1.0×10-5~7.0×10-4g/mL范围内与化学发光强度呈良好线性关系,方法的检出限为4.5×10-6g/mL,对1.0×10-5g/mL吡罗昔康连续进行6次测定的相对标准偏差为3.6%。     

流动注射化学发光分析法测定三类磺胺类药物

研究发现可溶性锰(Ⅳ)氧化磺胺类药物(磺胺甲基异口恶唑、磺胺嘧啶和磺胺脒)可以产生弱的化学发光,甲醛对这一化学发光反应有较强的增敏作用,据此建立了一种测定磺胺类药物的流动注射化学发光分析法。该方法对3种磺胺类药物磺胺甲基异口恶唑、磺胺嘧啶、磺胺脒的检出限分别为2×10-8、3×10-8、2×10-8g/mL;线性范围分别为6.0×10-8~1.0×10-5、1.0×10-7~8.0×10-6、4.0×10-8~8.0×10-6g/mL。对6.0×10-6g/mL磺胺甲基异口恶唑、4.0×10-6g/mL磺胺嘧啶和4.0×10-6g/mL磺胺脒的相对标准偏差分别为1.1%、1.2%和2.2%(n=11)。此法已用于复方新诺明片剂中磺胺甲基异口恶唑的测定,结果与药典方法测定值一致。并对化学发光反应的机理进行了探讨。     

流动注射化学发光法测定安痛定注射液中的氨基比林

在甲醛存在下 ,高锰酸钾与氨基比林能够发生化学发光反应 ,产生很强的化学发光 ,据此采用流动注射技术建立了一种测定氨基比林的化学发光分析法。方法的检出限为 3 .0× 10 -8g/mL ,相对标准偏差为 1.3 % (4 .0× 10 -6g/mL氨基比林 ,n =11) ,线性范围为 1.0× 10 -7～ 8.0× 10 -5g/mL氨基比林。该法已用于安痛定注射液中氨基比林含量的测定。     

流动注射电化学发光测定利福平的研究

发现利福平对电生BrO-氧化Luminol的强化学发光有很强的抑制作用。将在线恒电流电解产生BrO-与流动注射技术结合,建立了流动注射电化学发光测定利福平的新方法。该方法线性范围为1×10-8～1×10-6g/mL,检出限为3×10-9g/mL,相对标准偏差为1.7%(n=11,c=2.0×10-7g/mL)。     

Luminol-K_3[Fe(CN)_6]流动注射化学发光体系检测头孢吡肟

在碱性介质中,头孢吡肟对Luminol-K3[Fe(CN)6]化学发光体系具有明显的增强作用,基于此建立了流动注射化学发光法测定头孢吡肟的新方法。在优化实验条件下,化学发光增强强度与头孢吡肟的浓度在3.0×10-6~4.0×10-5g/m L范围内呈良好的线性关系,检出限为2.8×10-6g/m L。对2.0×10-5g/m L头孢吡肟平行测定11次,相对标准偏差(RSD)为1.5%。该方法用于头孢吡肟针剂的测定,结果满意。     

Flow‐Injection Chemiluminescence Analysis of Cloperastione Hydrochloride

Abstract

A new chemiluminescence (CL) reaction was observed when cloperastine hydrochloride was injected into the reaction mixture after the CL reaction of Ce(IV) and sodium sulfite finished. A new flow injection CL method for the determination of cloperastine hydrochloride was established based on the CL reaction. The relative standard deviation (RSD) for the determination of cloperastine hydrochloride was 1.3% (n=11, c=1.0×10^?6 g/mL). The CL intensity responded linearly to the concentration of cloperastine hydrochloride in the range 2.0×10^?7～2.0×10^?5 g/mL (r=0.9962). The detection limit was 5×10^?8 g/mL cloperastine hydrochloride. The method had been applied to the determination of cloperastine hydrochloride in tablets with satisfactory results.     

基于纳米TiO2的化学发光法检测核黄素

纳米TiO2与NaOH溶液作用能产生化学发光辐射,在表面活性剂十六烷基三甲基溴化铵(CTAB)的存在下,核黄素的加入能增强纳米TiO2-NaOH溶液的化学发光强度。基于此,构建了纳米TiO2-NaOH溶液化学发光新体系,建立了纳米TiO2-NaOH-核黄素体系检测核黄素的化学发光新方法。在优化实验条件下,核黄素质量浓度在5.0×10-6～3.5×10-4g/mL范围内与化学发光强度呈良好的线性关系,检出限为3.0×10-6g/mL,对2.5×10-5g/mL的核黄素进行11次平行测定,相对标准偏差为2.9%。该方法用于维生素B2片剂的测定,其结果与药典方法测得一致。该文同时对化学发光反应的机理进行了初步探讨。     

Flow Injection Chemiluminescence Determination of Phenol in Neutral Medium

A new flow injection chemiluminescence method for the determination of phenol was proposed, based upon the chemiluminescence reaction of phenol, N-bromosuccinimide, and hydrogen peroxide in neutral aqueous medium in the presence of cetyltrimethylammonium bromide surfactant micelles. The chemiluminescence signal was proportional to the concentration of phenol in the range of 1.0 × 10^?7?8.0 × 10^?6 g/mL with a detection limit of 3 × 10^?8 g/mL. The relative standard deviation for 1.0 × 10^?6 g/mL phenol solution was 2.0% (n = 11). The proposed method was successfully applied to the determination of phenol in phenol ear drops. A possible CL reaction mechanism was also discussed briefly.     

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.     

流动注射-化学发光法测定富马酸依美斯汀

在酸性条件下,KMnO4与甲醛能够产生微弱的化学发光,而富马酸依美斯汀的存在能够大大增强该化学发光强度;结合流动注射技术,建立了测定富马酸依美斯汀的流动注射-化学发光新方法。该方法的线性范围分别为3.0×10-8～2.0×10-7g/mL,2.0×10-7～1.0×10-6g/mL和1.0×10-6～8.0×10-6g/mL。检出限为1.0×10-8g/mL,对2.0×10-6g/mL富马酸依美斯汀滴眼液平行测定11次,其相对标准偏差为1.3%。该方法已成功应用于滴眼液中富马酸依美斯汀的含量测定。     

Flow-injection chemiluminescence sensor for determination of isoniazid in urine sample based on molecularly imprinted polymer

In this paper, molecularly imprinted polymer (MIP) of isoniazid is synthesized through thermal radical copolymerization of metharylic acid (MAA) and ethylene glycol dimethacrylate (EGDMA) in the presence of isoniazid template molecules. A novel flow injection chemiluminescence sensor for isoniazid determination is developed by packing the isoniazid-MIP into the flow cell as recognition elements. Isoniazid could be selectively adsorbed by the MIPs and the adsorbed isoniazid was sensed by its great enhancing effect on the weak CL reaction between luminol and periodate which were mixed in the flow cell. The enhanced CL intensity is linear in the range 2x10(-9) to 2x10(-7) g/mL and the detection limit is 7x10(-10) g/mL (3sigma) isoniazid with a relative standard deviation 2.8% (n=9) for 8x10(-8) g/mL. The sensor is reversible and reusable. It has a great improvement in sensitivity and selectivity for CL analysis. As a result, the sensor has been successfully applied to determination of isoniazid in human urine. At the same time, the binding characteristic of the polymer to isoniazid was evaluated by batch method and the dynamic method, respectively.     

流动注射化学发光法快速测定尿液中左亚叶酸钙

在碱性介质中, 左亚叶酸钙对鲁米诺-K3Fe(CN)6体系有显著的增敏作用, 据此, 建立了一种简单、快速测定左亚叶酸钙的流动注射化学发光新方法. 在优化的实验条件下, 该法测定左亚叶酸钙的线性范围为5.0×10-8～1.0×10-5 g/mL; 检出限(3σ)为2.0×10-8 g/mL; 对浓度为1.0×10-6 g/mL的样品进行11次平行测定, 相对标准偏差为1.3%. 将此法用于尿液中左亚叶酸钙的测定, 同时进行回收率实验.     

Flow injection chemiluminescence determination of isoniazid with electrogenerated hypochlorite

A flow-injection chemiluminescence method for the determination of isoniazid based on the sensitizing effect of isoniazid on the chemiluminescence generating luminol-hypochlorite reaction is described. The hypochlorite was electrogenerated on-line by constant current electrolysis, thus, eliminating instability of hypochlorite solution prepared from commercially available sodium hypochlorite. The calibration graph is linear in the range 1 × 10^–8 to 1 × 10^–6 g mL^–1, and the detection limit is 6 × 10^–9 g mL^–1. The relative standard deviation for determination of 5 × 10^–8 g mL^–1 is 2.8%. The proposed method has been successfully applied to the determination of isoniazid in pharmaceutical preparations.