场放大进样-扫集胶束电动色谱法测定金银花中的咖啡酸与绿原酸

以场放大进样-扫集胶束电动色谱法( FASI - sweeping-MEKC)测定了金银花中的咖啡酸、绿原酸.考察了SDS浓度、进样电压、进水时间与进样时间比值、进样时间以及缓冲液组成对分离效果的影响.最佳分离条件为:采用未涂层熔融石英毛细管(50 cm × 50 μm,有效柱长33 cm),缓冲体系为100 mmol...     

毛细管电泳分离莽草酸及其对映体

采用毛细管电泳分离莽草酸及其对映体.试验了缓冲溶液的种类、浓度、pH值、分离电压、进样时间、添加剂对分离的影响.结果表明:以30 mmol·L-1三(羟甲基)氨基甲烷-30 mmol·L-1 H3BO3(pH 8.6)为缓冲体系,在波长214 nm,分离电压为15 kV,进样时间为10 s的条件下,实现了对莽草酸及其对映体的分离.     

毛细管电泳免疫分析法研究鼠IgM、兔抗鼠IgG及其免疫复合物

根据鼠IgM能与兔抗鼠IgG发生特异性免疫反应,采用毛细管电泳免疫法分析鼠IgM及其免疫复合物.以Tris为电解质,探讨了缓冲溶液浓度和pH值、进样时间、进样电压等因素对鼠IgM、兔抗鼠IgG及其免疫复合物分离的影响.在缓冲体系浓度为40 mmo1·L-1 TAE、1.0 mmo1.L-1EDTA(pH为8.5),进样时间为12 s,进样电压为18 kV的条件下,鼠IgM、兔抗鼠IgG及其反应形成的免疫复合物获得了很好的分离.     

微流控芯片测定盐酸金刚烷胺片中的盐酸金刚烷胺

建立了微流控芯片非接触电导检测片剂中盐酸金刚烷胺的分析方法.对缓冲液和添加剂的种类及浓度、分离电压、进样时间等进行了优化.实验采用1 mmol/L HAc+2 mmol/L NaAc(pH 4.5)+0.1 mmol/LSDS的缓冲体系,于2.00kV的分离电压下进样10 s,在1 min内实现了盐酸金刚烷胺的快速检测...     

微流体芯片电泳技术对人血清蛋白的快速分离

通过微流体芯片电泳技术分离人血清蛋白,探讨了常见十字形微流体芯片上样品的电动进样与分离过程,分析了在十字芯片上的进样时间和电压设置对后续样品检测和定量的影响。采用的缓冲体系为:100mmol/L H3BO3,50mmol/L NaCl,5%Dextran(以NaOH调至pH 8.3),该缓冲液能够有效分离人血清蛋白中的白蛋白(Albumin)和4种球蛋白(α1-,α2-,β-,和γ-globulin),并且给出了它们在该缓冲体系中的淌度估算范围为5.15×10-5～47.2×10-5 cm2/(V.s)。在芯片上2min之内可以完成进样和分离,相比于常用的毛细管区带电泳,提高了分析速度。     

阴离子选择性耗尽进样-胶束扫集毛细管电泳法对痕量醋酸氢化可的松的测定

联用阴离子选择性耗尽进样和胶束扫集两种在线富集技术,建立了胶束毛细管电泳方法测定化妆品中醋酸氢化可的松的方法。讨论了SDS浓度、样品基体、进样电压、进水时间和进样时间对富集和分离的影响。优化的实验条件:以120 mmol/L SDS-20 mmol/L NaH2PO4(pH2.2)-10%(体积分数)甲醇为缓冲体系,分离电压-20 kV,进样电压-20 kV,进样时间80 s,进水时间200 s,测量波长250 nm。在该实验条件下,醋酸氢化可的松的富集倍数比普通毛细管电泳法提高了约173倍。方法的线性范围为0.05~5.0 mg/L,检出限为12.6μg/L。该方法用于化妆品中醋酸氢化可的松含量的测定,回收率为98%~105%,相对标准偏差均小于4.0%(n=4)。     

阳离子选择性耗尽进样-胶束电动色谱法对可非糖浆中盐酸异丙嗪与磷酸可待因的测定

在胶束电动色谱法的基础上,联用阳离子选择性耗尽进样技术,对盐酸异丙嗪和磷酸可待因同时测定的方法进行了研究。考察了pH值、有机溶剂、SDS浓度、进样时间、进样电压等实验条件对分离效果的影响。最佳实验条件为:缓冲体系16%乙腈+80 mmol/L SDS+20 mmol/L NaH2PO4(pH2.4),分离电压为-18 kV,测量波长214 nm,萃取液pH2.4,进样电压10 kV,进样时间100 s。在优化实验条件下,两种物质在8 min内出峰,峰面积RSD不大于4.6%。盐酸异丙嗪、磷酸可待因的线性范围分别为0.50~81.3、0.78~62.5μg/L,检出限分别为0.16、0.12μg/L,相关系数分别为0.998 9、0.998 8。将方法用于可非糖浆中盐酸异丙嗪与磷酸可待因的测定,回收率为96%~106%。     

场放大进样-胶束扫集法测定升麻中3种有机酸

利用两种在线富集技术,对阿魏酸、异阿魏酸、咖啡酸同时测定的方法进行了研究.在胶束扫集的基础上,联用场放大进样,使富集倍数提高了约100倍;检出限降至4 μg/L,线性范围向下延伸到10 μg/L.胶束扫集电动色谱缓冲体系为90 mmol/L SDS 20 mmol/L Na2PO4(pH=2.20) 10%甲醇,分离电压20 kV.进样电压10 kV,进样时间21 s,进水时间210 s(H=20.0 cm),测量波长214 nm.讨论了SDS浓度、进样长度、进样电压等对分离效果的影响.在优化条件下,3种有机酸在14 min内出峰,峰面积RSD≤3.8%.方法检出限(μg/L)、线性范围(μg/L)、相关系数分别为:阿魏酸4.0、10～400、0.9982;异阿魏酸4.0、10～400、0.9970;咖啡酸5.0、10～400、0.9980.回收率为83.9%～114.3%.     

阳离子选择性耗尽进样-胶束扫集法测定尿液中的麻黄碱和可待因

联用选择性耗尽进样和胶束扫集两种在线富集技术,建立了尿样中麻黄碱和可待因含量测定的灵敏方法,并通过日内、日间、柱间实验考察了方法的稳定性.胶束扫集电动色谱缓冲体系为80 mmol/L 十二烷基磺酸钠(SDS)-20 mmol/L NaH2PO4(pH 2.20)-18%乙腈(V/V),分离电压-20 kV,进样电压10 kV,进样时间150 s,测量波长200 nm.同时讨论了pH值、SDS浓度、选择性耗尽进样萃取液电导、进样电压、进样时间和进水长度等对分离效果的影响.结果显示,方法富集功能很强,对麻黄碱和可待因含的富集倍数分别达5800和2490以上.在优化条件下,方法线性关系良好(r=0.9999),麻黄碱和可待因的线性范围分别为0.500～16.0 μg/L和2.00～48.0 μg/L,检出限分别为0.10和0.80 μg/L.方法稳定性良好,日内、日间和柱间的RSD分别为2.6%,5.9%和6.6%.应用于实际尿样分析,回收率在96.8%～106%之间,RSD≤4.7%,结果比较满意.     

场放大进样-胶束扫集毛细管电脉法测定痕量泼尼松

建立了胶束毛细管电动色谱在线富集技术测定药品中痕量的泼尼松的方法。在胶束扫集的基础上联用场放大进样,使泼尼松的富集倍数提高了136倍;检出限由原来的2.7mg/L降至20μg/L。胶束扫集毛细管电泳缓冲体系为120mmol/LSDS、10mmol/LNaH2PO4(pH2.5)10%乙腈(V/V)。分离电压-20kV,进样电压-20kV,进样时间70s,进水时间180s,检测波长250nm。同时讨论了SDS浓度、样品基质pH、进样电压、进水时间和进样时间对分离效果的影响。实验结果显示:在优化实验条件下,样品的检测仅需8min,泼尼松在0.05～10mg/L的范围内线性关系良好(r=0.998)。回收率在89.4%～106%之间,相对标准偏差在2.1%～2.6%之间,可用于各种中药制剂中泼尼松的含量测定。     

一种快速高选择性检测痕量癌胚抗原的共振散射光谱法

用10 nm的金纳米粒子标记单克隆癌胚抗原抗体制备了检测癌胚抗原（CEA）的共振散射光谱探针（Au-CEAAb）。在pH 6.8 的Na2HPO4- NaH2PO4缓冲溶液中及聚乙二醇-6000存在下, CEA与Au-CEAAb发生免疫反应聚集形成疏水性的、平均粒径为227.0 nm的免疫复合物微粒,并在321 nm、581 nm产生2个共振散射峰。随着癌胚抗原（CEA）浓度的增大,581 nm处的共振散射强度I581nm线性增加,其增加值△I581nm与CEA浓度在1.0～50.0 ng·mL-1范围内呈良好的线性关系,相应的回归方程、相关系数、检出限(3σ)分别为ΔI581nm=1.63 C +5.6、0.9940、0.52 ng·mL-1。该法简便、快速、灵敏且选择性好,用于检测人血清中癌胚抗原（CEA）,结果满意。     

基于杂交链式反应的可视化免疫分析检测癌胚抗原

构建了基于杂交链反应的比色免疫分析方法,实现了对肿瘤标志物癌胚抗原的检测。在抗原-抗体的特异性结合作用下,在磁珠表面构建夹心式免疫复合物,进一步结合杂交链式反应(HCR)作为信号放大策略,将染料曙红Y嵌入至DNA长链中。在可见光的照射下,能使反应底液中的四甲基联苯胺(TMB)氧化,发生明显的颜色变化,由无色变为蓝色,且与癌胚抗原的浓度呈正相关性。在最优实验条件下,癌胚抗原的浓度在1 pg/mL^5 ng/mL范围内呈线性变化,检出限为1 pg/mL。     

Synthesis and Characterization of Silver Nanoparticle Modified 3-Aminophenol Resin Microspheres with Application for Determination of Carcinoembryonic Antigens by Surface-Enhanced Raman Scattering

Uniform phenolic resin microspheres were prepared by the polycondensation of 3-aminophenol and formaldehyde. On the surface of the 3-aminophenol resin microspheres, silver nanoparticles were synthesized in situ and immobilized by simple heating. The composite was employed as a substrate for surface-enhanced Raman scattering (SERS). The SERS enhancement factor was evaluated using 4-mercaptobenzoic acid and Nile blue A as signal molecules. A highly sensitive SERS immunoassay that combined labeled antibody conjugated silver nanoparticle modified 3-aminophenol resin microspheres and coating antibody conjugated magnetic nanoparticles was fabricated to determine carcinoembryonic antigen. A linear relationship was obtained between the Raman intensity and the concentration of carcinoembryonic antigen. The limit of detection was 1.2 picograms per milliliter at a signal-to-noise ratio of three. This is believed to be the first report of a SERS immunoassay using silver nanoparticle modified 3-aminophenol resin microspheres as substrates.     

Use of nitrocellulose films for affinity-directed mass spectrometry for the analysis of antibody/antigen interactions

Combination of affinity extraction procedures with mass spectrometric analyses is termed affinity-directed mass spectrometry, a technique that has gained broad interest in immunology and is extended here with several improvements from methods used in previous studies. A monoclonal antibody was immobilized on a nitrocellulose (NC) membrane, allowing the corresponding antigen to be selectively captured from a complex solution for analysis by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOFMS). This method was also used to rapidly determine the approximate binding region responsible for the antibody/antigen interaction. The tryptic fragments of antigen protein in buffer were applied to the antibody immobilized on NC film and allowed to interact. The NC film was then washed to remove salts and other unbound components, and subjected to analysis by MALDI-TOFMS. Using interferon-alpha(2a) and anti-interferon-alpha(2a) monoclonal antibody IgG as a model system, we successfully extracted the antigen protein and determined the approximate binding region for the antigen/antibody interaction (i.e., the tryptic fragment responsible).     

Determination of Carcinoembryonic Antigen by Surface-Enhanced Raman Spectroscopy Using Gold Nanobowl Arrays

Surface-enhanced Raman scattering (SERS) based on the double-antibody sandwich format is reported for the determination of carcinoembryonic antigen. Ordered gold nanobowl arrays were fabricated and conjugated with anticarcinoembryonic as capturing substrates, and gold nanoshells, adsorbed with 4-mercaptobenzonic acid, were modified with anticarcinoembryonic antigen as labeling tags. After the carcinoembryonic antigen was captured on ordered gold nanobowl arrays, the labeling tags were bonded to the captured carcinoembryonic antigen. The interaction of SERS substrates (ordered gold nanobowl arrays) and SERS labels (gold nanoshells) showed high sensitivity and a low detection limit for carcinoembryonic antigen. The linear dynamic range of SERS for carcinoembryonic antigen was from 5?pg/mL to 100?ng/mL with a linear relationship between carcinoembryonic antigen concentration and SERS intensity. The detection limit was 1.73?pg/mL. SERS detection may be used for other cancer biomarkers and provides potential for the clinical diagnosis of cancer biomarkers.     

Electrochemical immunosensor for carcinoembryonic antigen based on antigen immobilization in gold nanoparticles modified chitosan membrane.

A disposable electrochemical immunosensor for carcinoembryonic antigen (CEA) was proposed based on the antigen immobilized in a colloidal gold nanoparticles modified chitosan membrane on the surface of an indium-tin oxide (ITO) electrode. The different membranes were characterized by scanning electron microscope and electrochemical methods. Based on a competitive immunoassay format, the immobilized antigen of the immunosensor was incubated with a horseradish peroxidase (HRP) labeled antibody and sample CEA antigen, and the formed immunoconjugate in the immunosensor was detected by an o-phenylenediamine-H(2)O(2)-HRP electrochemical system. Under the optimal experimental conditions, the electrocatalytic current decreased linearly with the competitive mechanism. CEA could be determined in the linear range from 2.0 to 20 ng/ml with a detection limit of 1.0 ng/ml. The prepared CEA immunosensor is not only economic due to the low-cost ITO electrode obtained from industrial mass production, but is also capable with good stability and reproducibility for batch fabrication.     

Comparative Analysis of Proline Enantiomer in Chiral Recognition of Biological Macromolecule in Immunoassay

An interesting phenomenon of the stereoselective interaction between biological macromolecule and amino acid enantiomorphous was described. Firstly, proline enantiomer (L‐ and D‐proline) was assembled on the glassy carbon electrode surface. Then carcinoembryonic antibody (anti‐CEA) was loaded to the enantiomer surface, electrochemical impedance spectroscopy (EIS) was used to monitor the growth of amino acid film. The assembly process was characterized by cyclic voltammetry (CV) and atomic force microscopy (AFM) was applied to image the chiral films. Finally, the developed electrodes had interacted with carcinoembryonic antigen (CEA) in varying concentration solutions. The AFM and amperometric results revealed that the proline enantioner had the chiral recognition function to antibody.     

Electrochemical Immunoanalysis for Carcinoembryonic Antigen Based on Multilayer Architectures of Gold Nanoparticles and Polycation Biomimetic Interface on Glassy Carbon Electrode

This paper describes a layer‐by‐layer (LBL) self‐assembly process of chitosan (CTS) and gold nanoparticles (Au) on the pretreated negatively charged glassy carbon (GC) electrode to fabricate electrochemistry immunosensor with a nontoxic biomimetic interface, which provided an environment similar to a native system and allowed more freedom in orientation for immobilization of carcinoembryonic antibody (anti‐CEA) to monitor carcinoembryonic antigen (CEA). UV‐vis spectroscope, atomic force microscopy (AFM), and cyclic voltammetric (CV) measurements were used to follow the multilayer film formation. The performance of the biominetic interface and factors influencing the assay system were investigated in detail. The differential pulse voltammetry (DPV) current response is used for the CEA concentration assay. The dynamic range was from 0.50 to 80.00 ng mL^?1 with a detection limit of 0.27 ng mL^?1 at 3σ. In addition, the experiment results indicate that immobilization described in this proposed method exhibits a good sensitivity, selectivity, and stability.     

磁性纳米金共价固定癌胚抗原单克隆抗体的电流型免疫传感器

合成了Fe3O4/Au磁性复合纳米粒子, 在粒子表面通过自组装硫脲分子使表面氨基化, 再用戊二醛共价交联固定癌胚抗原抗体(anti-CEA). 在外加磁场的作用下, 将anti-CEA复合磁性粒子吸附在固体石蜡碳糊电极表面, 制成了新型电流型免疫传感器. 免疫电极在含有癌胚抗原CEA和辣根过氧化物酶标记的癌胚抗原(HRP-CEA)的混合溶液中温育, CEA和HRP-CEA与固定在电极表面的anti-CEA发生竞争反应, 导致HRP对H2O2的催化降解作用的改变, 从而可间接测定CEA. 由于标记的HRP可催化降解H2O2, 导致媒介体间苯二酚浓度改变, 使测定的灵敏度大大提高. 响应电流与CEA质量浓度的对数在2~160 ng/mL的范围内呈线性关系, 检出限为0.57 ng/mL(3σ法). 该免疫传感器具有制作简单、价廉及表面易于更新等特点.     

CA 19-9 like epitope(s) on carcinoembryonic antigen molecules

CA 19-9 epitope(s) on carcinoembryonic antigen (CEA) was studied by a method designated the hybrid immunoradiometric-assay (hybrid IRMA) using solid phase CEA antibody to capture the CEA molecule and radio-labeled NS 19-9 antibody as a detector. The radioactivities of the hybrid IRMA of respective sera with certain cancers differed from that of normal sera. The specific radioactivities of hybrid IRMA did not disappear on washing with a reaction mixture containing Triton X-100 as a detergent. Treatment of the sample with neuraminidase or periodate diminished the specific bound radioactivities, similar to CA 19-9 antigen. Furthermore, the treatment of CEAs by PI-PLC had no effect on the radioactivities. Taken together, it was suggested that CEA sugar moieties contain CA 19-9 like epitope(s).