微孔板蛋白芯片可视化检测方法的研究

将微孔板生物芯片制备技术与银增强显色方法相结合,建立了一种高通量蛋白免疫分析新方法。研究采用夹心法反应原理,将人IgG捕获抗体以微阵列形式点样于96孔板底部制备成蛋白微阵列,并依次与人IgG、生物素标记二抗及链亲和素胶体金反应,最后用银增强法显色。采用平板式扫描仪对微孔板显色结果进行快速扫描成像,图像采用luxscan 3.0软件处理。结果表明:微孔板蛋白芯片的最低检测量可达0.6 ng/mL,线性范围10 ng/mL~100μg/mL,相关系数为0.98,重复性较好(CV10%)。     

量子点银增强可视化检测方法的研究与应用

通过制备链霉亲和素修饰的CdTe量子点探针,建立了基于量子点探针的银增强显色可视化检测方法,并结合蛋白质芯片分析技术,将此方法应用于反相蛋白芯片的分析检测.以人IgG测定为模式,在醛基片上固定人IgG,加入10 ng Bio-羊抗人IgG及CdTe-SA探针,银增强显色15 min.结果显示,人IgG样品量在100 pg～1.6 ng范围内,其对数值与信号灰度值呈良好的线性关系(r=0.997),检出限为50 pg.本方法可实现微量蛋白的灵敏检测,具有操作简单,对仪器要求低,结果可视化等特点.     

基于纳米银的比色阵列传感器的构建及在蛋白质检测中的应用

蛋白质的快速高效检测和鉴定在医学诊断、不同疾病的治疗和蛋白质组学中具有巨大的前景。目前的检测手段大多存在一些问题,如操作繁琐、效率低等,因此开发一个理想的蛋白质检测方法尤为重要。以纳米银(AgNPs)为传感元件的阵列传感器在蛋白质检测方面具有操作便捷、准确率高、可视化等优点。本文合成两种不同颜色和形状的AgNPs:黄色球形和蓝色三角形,以此构建一个简单的比色阵列传感器,用于蛋白质的区分检测。该传感器可以准确地识别和区分不同种类的蛋白质,准确率为100%。在成功识别出不同类型的蛋白质的基础上,进一步评估了该阵列传感器应用于区分正常和变性蛋白质的能力,准确率为96.0%。此外,该阵列传感器对于未知样本的识别也具有高的准确率。     

硅纳米线阵列电极作为细胞色素c传感器的研究

利用化学刻蚀法由p型硅片制备了硅纳米线阵列,经过表面去氧化层处理后,制备了检测蛋白质细胞色素c的电化学传感器.实验表明,硅纳米线阵列电极对细胞色素c有良好的电化学响应,并且在低浓度条件下具备线性响应的特点.根据与未经表面处理的硅纳米线阵列电极的实验结果相对比,提出了细胞色素c所具备的羧基末端与硅纳米线阵列电极表面的Si-H相互作用从而改善传感性能的检测机理.     

可视交叉传感阵列对蛋白质及其热变性过程的快速识别

以卟啉及其衍生物和特异性染料为敏感化学元件, 基于交叉响应原理构建了识别蛋白质的可视6×6阵列. 该阵列以颜色差谱图显示其与蛋白质作用呈现的特异性光谱反应, 采用聚类分析、 主成分分析和欧氏距离对图谱进行了分析. 结果表明, 该阵列可以鉴别模式蛋白牛血清白蛋白(BSA)、 牛血红蛋白(BHb)和卵清白蛋白(Ova)及其混合物, 且有望实现定量分析. 此外, 阵列的高敏感性使其不仅能识别天然蛋白质和不同变性程度的蛋白质, 还能对其热变性过程进行可视化实时监控. 该阵列产生的特殊颜色变化与蛋白质的空间构型、 微环境pH值的差异及溶解度有关. 因此, 该方法不仅能实现对蛋白质的快速识别, 为蛋白质热变性机理的研究提供新途径, 而且在临床医学和食品安全等的实时快速检测方面有潜在的应用价值.     

利用反相乳液-水滴模板法制备功能性生物基图案化结构

通过将传统水滴模板法中的单相成膜液改造为反相乳液体系,引进乳液水滴来加载蛋白质组分,实现了对亲水组分直接实施水滴模板法从而获得其阵列组装结构.利用壳聚糖纳米粒子作为皮克林反相乳液的乳化剂制备了稳定的反相乳液体系,并进一步得到聚乳酸/壳聚糖/牛血清白蛋白的杂化蜂窝状多孔薄膜,考察了壳聚糖粒子对于乳液稳定和所制备多孔阵列结构形貌的影响,研究了加入蛋白质浓度和乳液中的水相/油相比例对于所成膜孔形貌的影响,利用荧光标记蛋白质跟踪确认基于蜂窝状多孔阵列结构上的图案化蛋白质阵列组装形貌.     

碳量子点荧光成像法应用于聚丙烯酰胺凝胶电泳检测人血清蛋白质的研究

建立了碳量子点荧光成像法检测聚丙烯酰胺凝胶电泳分离蛋白质如人血清蛋白质的新方法. 通过一步绿色微波法合成的碳量子点并将其应用在聚丙烯酰胺凝胶电泳分离蛋白质的检测中, 通过醋酸-醋酸钠调节孵育溶液, 优化pH值、碳量子点的用量及孵育溶液的浓度等条件, 使碳量子点和蛋白质相结合并在365 nm的紫外灯照射下得到了清晰的人血清蛋白电泳图, 该新方法具有原料便宜易得、无污染、简单、快速、高灵敏度、低背景及高分辨率的优点, 在生物技术方面和纳米技术方面具有巨大的应用前景.     

基于靶向多肽探针的蛋白质分析检测新方法

高选择性、高灵敏度的蛋白质分析检测方法是复杂生命体系研究的有力工具,能为疾病的发现、治疗以及分子机制研究提供新的、有价值的思路和手段.该文围绕蛋白质与多肽的分子识别,针对疾病相关多肽、蛋白质的分离、分析与检测新方法,综述了近几年取得的研究进展,可为复杂生命体系中生理活性分子的结构与功能研究提供借鉴.     

可视化蛋白芯片检测牛奶中庆大霉素的方法研究

本文采用间接竞争免疫法,研究了可视化蛋白芯片快速检测牛奶中庆大霉素的方法。在固定有庆大霉素人工抗原的醛基修饰芯片的反应区内,加入庆大霉素单克隆抗体和游离的庆大霉素或牛奶样品混合物,待抗原抗体反应完全后依次加入纳米银标记的二抗(羊抗鼠)及银增强显色剂进行可视化检测,结果采用可视化生物芯片检测系统进行定量分析。通过设计制备内标点及建立的内标曲线,可在同一孔内定量检测游离的庆大霉素。该法庆大霉素的线性检测范围为0.1~200ng/mL,检测限为0.1ng/mL,样品的加标回收率为95%~112%。     

对《普通高中化学课程标准》中氨基与亚硝酸法检测蛋白质含量的商榷

《普通高中化学课程标准》中检测蛋白质含量的方法是利用氨基与亚硝酸的反应,其原理是α-氨基与亚硝酸可定量生成氮气,但蛋白质侧链和辅基中的含氮基团难以进行上述反应或者无氮气生成,因此该法不能用于检测蛋白质的含量,但可用于测定蛋白质的水解度。通过比较各种检测蛋白质含量的方法——凯氏定氮法、紫外吸收法、双缩脲法、BCA法、folin-酚试剂法、考马斯亮蓝结合法,建议高中化学教学中采用双缩脲法。     

生物素修饰纳米银探针的制备及在蛋白芯片可视化检测中的应用

采用寡核苷酸为连接分子成功制备了生物素修饰的纳米银探针, 并建立了纳米银催化同种金属离子的特异性还原显色反应. 实验采用蛋白质芯片为分析工具, 以微量人IgG为蛋白分析模式研究了纳米银探针/氢醌/硝酸银体系的显色分析性能. 实验结果表明, 上述检测体系可对160 fg~100 pg含量范围内的微量蛋白显示可视化结果, 蛋白点的灰度值与其浓度具有良好的相关性, 最小蛋白检测量可达160 fg. 同时还开展了与商品化链亲和素纳米金/银增强试剂显色方法的对比实验, 结果表明, 本法制备的探针对蛋白的检出限降低了约40倍, 且具有存储稳定、反应快速等优点.     

Evaluation of a surface-sampling probe electrospray mass spectrometry system for the analysis of surface-deposited and affinity-captured proteins

A combined self-aspirating electrospray emitter/surfacing-sampling probe coupled with an ion trap mass spectrometer was used to sample and mass analyze proteins from surfaces. The sampling probe mass spectrometer system was used to sample and detect lysozyme that had been deposited onto a glass slide using a piezoelectric spotter or murine gamma-interferon affinity captured on a glass slide using surface-immobilized anti-gamma-interferon antibody. The detection level for surface-deposited lysozyme (spot size < or =200 microm) was approximately 1.0 fmol (approximately 100 fmol/mm2) as determined from the ability to measure accurately the protein molecular mass from the mass spectrum acquired by sampling the deposit. These detection limits may be sufficient for certain applications in which protein fractions from a separation method are collected onto a surface. Radiolabeled proteins were used to quantify the surface density of immobilized antibody and the efficiency of capture of the gamma-interferon on glass and higher surface area ceramic supports. The capture density of gamma-interferon at surface saturation ranged from about 23 to 50 fmol/mm2 depending on the capture surface. Nonetheless, mass spectrometric detection of affinity capture protein was successful in some cases, but the results were not reproducible. Thus, improvement of the sampling system, ionization efficiency and/or capture density will be necessary for practical sampling of affinity-captured proteins. The means to accomplish improved sampling system detection limits and to increase the absolute amounts of protein captured per unit area are discussed.     

Covalent strategy for immobilization of DNA-microspots suitable for microarrays with label-free and time-resolved optical detection of hybridization

Sequence-specific detection and quantification of nucleic acids are central steps in many molecular biology procedures which have also been transferred to chip-based procedures. Hybridization-based assays can be used to quantify and discriminate between DNA target sequences down to the level of single base mismatches. Arrays of DNA probes immobilized on a support enable simultaneous testing of multiple sequences of a single sample. DNA arrays can be produced either by in-situ synthesis of oligonucleotides or by immobilization of pre-assembled DNA probes. Covalent and directed immobilization improves the reproducibility and stability of DNA arrays. This is especially interesting with repeated use of transducers or chips. Procedures are described for effective covalent immobilization of pre-assembled amino-linked oligonucleotides, by use of ink-jet techniques, on a modified and heated glass surface, with addressable surface areas ranging from 0.01 mm2 to a few mm2. Almost immediate evaporation of the spotted droplets on the heated surfaces leads to very high surface hybridization capacities. The surfaces are suitable for use with a label-free detection method - reflectometric interference spectroscopy (RIfS). It is shown that hybridization capacity and non-specific interaction at these DNA-surfaces can be characterized by use of RIfS. With a consumption of less than 80 ng mm(-2) oligonucleotide and a specific hybridization capacity of more than 300 fmol mm(-2), the activated aminodextran procedure was usually suitable for setting up a DNA array with label-free detection. Non-specific interactions with random oligomers or protein (ovalbumin) were low. Up to 150 repeated regenerations (stripping) of the surfaces by acid treatment and denaturing agents, and 50 days of storage, have been possible without significant loss of hybridization capacity.     

Determination of nitrocatecholamines in rat brain using high-performance liquid chromatography-peroxyoxalate chemiluminescence reaction detection

We have developed a method to determine nitrocatecholamines (nitroCAs: nitronorepinephrine (nitroNE), nitroepinephrine (nitroE), and nitrodopamine (nitroDA)) in rat brain using high-performance liquid chromatography-peroxyoxalate chemiluminescence (POCL) reaction detection. This method consists of in-line extraction of amines, including nitroCAs, followed by separation on an ODS column, reduction of nitroCAs with a reducer column, derivatization with ethylenediamine, and finally the POCL reaction detection. Use of the reducer column increased the sensitivity of detection of nitroCAs by 45-172%. The limits of detection (signal-to-noise ratio of 3) were 75fmol for nitroNE, 125fmol for nitroE, and 150fmol for nitroDA. By using this method, not only nitroNE, but nitroE and nitroDA were determined in rat brain. The concentrations of nitroNE and nitroE in rat brain were 9.2+/-2.0 and 13.5+/-2.5 pmol/g tissue, respectively (n=5).     

A biosensor for monitoring formaldehyde using a new lipophilic tetrathiafulvalene-tetracyanoquinodimethane salt and a polyurethane membrane

The fabrication and application of an end-column amperometric detection (AD) system with a carbon electrode for capillary-column liquid chromatography (CLC) were described. This new amperometric detector showed good sensitivity and stability in detecting the thiocompounds and other analytes with CLC. In order to obtain the better separation and detection performance for analytes, several operational parameters had been investigated: the working potentials, pH and flow rate. Under the optimum conditions, the method could effectively separate and determine cysteine (Cys), glutathione (GSH), dopamine (DA) and 6-thiopurine (6-TP). Good repeatability for retention time was obtained with a relative standard deviation (R.S.D.) value of 0.5%. The linear range covered over three orders of magnitude and the limits of detection were 8 fmol for cysteine, 20 fmol for glutathione, 8 fmol for dopamine and 20 fmol for 6-thiopurine. This method was successfully applied in determination of urinary sample with characteristics of simplicity, high sensitivity and good repeatability.     

Aptamer-based silver nanosensor for multiple protein detection

In the present work we design a novel aptamer-based silver nanosensor for one-spot simultaneously detection of multiple proteins. SS-DNA modified AgNPs were immobilized on the aldehyde coated glass slide to form an AgNP array. Then dye-labeled aptamer sequences were allowed to hybridize with their complementary strands assembled on the surface of AgNPs. The target proteins were introduced to associate with the corresponding aptamers to form the aptamer-target complexes. The removal of the aptamer-target complexes resulted in a remarkable decrease in fluorescent signals. This nanosensor is found to be highly sensitive for the detection of proteins. When thrombin was employed as a sample model, the limit of detection of the optimized nanosenor was 0.4 fmol with a linear response of 0.8 fmol to 0.5 pmol. We further demonstrated the multiple protein detection of IgE and thrombin using multicolor silver nanoprobes, which shows effective recognition of the relative protein individually or simultaneously. This silver nanosensor offers a unique heterogeneous approach for protein detection with several advantages, such as high sensitivity, rapidity, high throughput, and miniaturization.     

HPLC determination of polyamines in the femtomole range

A new method for the chromatographic determination of polyamines is presented. The procedure consists of the reaction of 9-fluorenylmethyl chloroformate (FMOC-Cl) with polyamines at 50 +/- 1 degrees C for 10 min, followed by stepwise elution chromatography. The reaction is simple and the derivatives are stable. All the polyamine-FMOC derivatives can be separated within 13 min. The linearity of this method is satisfactory in the range of 0.5-100 pmol. The detection limits for putrescine, cadaverine, spermidine and spermine are 83.3 fmol, 109 fmol, 25.5 fmol and 22.7 fmol respectively.     

基于石墨烯化学修饰电极的适体传感器

采用石墨烯(RGO)作载体,凝血酶适体(TBA)作探针,凝血酶为目标蛋白,电化学阻抗谱(EIS)为检测技术,建立了检测蛋白质的新方法。由于RGO可增大电极有效表面积并提高电极表面电子传输速率以及TBA的特异性识别能力,此方法具有较高的灵敏度和良好的选择性。采用本方法检测凝血酶的线性范围为0.3～10 fmol/L,检出限为0.26 fmol/L。本研究将RGO应用于电化学适体传感器,证实了RGO修饰电极在电化学适体传感器领域中潜在的应用价值。     

Solid-phase immunoassay detection of peptides from complex matrices without a separation

A simple and sensitive solid-phase fluorescence immunoassay method was developed to detect peptides without separating them from a biological matrix. A near infrared fluorescence detection system was constructed for scanning analyte spots blotted onto protein binding membranes. Hydrophobic membranes were used with a modified vacuum spot blotting system to concentrate the peptide solution into a small area and the overall assay time was thus reduced by eliminating blocking steps. Both direct and indirect immunoassay methods are demonstrated; the indirect is more sensitive and features a 1 pmol detection limit of neat dynorphin A solutions. To further increase the immunoassay sensitivity, a novel capillary blotting system with hydrophilic membranes was designed where optimized sample volumes of 167 nL were deposited for each spot. The area-reduced blotting method shows a 1000-fold improved, 1.3 fmol spot(-1) detection limit of a dynorphin A diluted in a buffered solution of 150 mg L(-1) of casein. Low-flow push-pull perfusates with volumes of 1 microL sampled from the striatum of the rat were assayed for dynorphin A by the method of standard addition. The detection limit was estimated to be 1.9 fmol in the low-flow push-pull perfusates. These data demonstrate a solid-phase near infrared immunofluorescence strategy for the study of peptides directly blotted from chemically complex biological fluid matrices.     

Analysis of amino acids in human vascular endothelial (ECV-304) cells by microchip electrophoresis with fluorescence detection

A rapid and sensitive method was developed for the analysis of amino acids by microchip electrophoresis with Hg-lamp excitation fluorescence detection. Fluorescein-isothiocyanate (FITC) was chosen to estimate the sensitivity of this system, and the detection limit (S/N = 3) with FITC was 1.7 nM, which showed that the system was sensitive as well as simple. Two derivatizing agents, FITC and ortho-phthalaldehyde (OPA) were employed to label amino acids and were compared in the same fluorescence detection system with an Hg lamp as the excitation source. The separation parameters were optimized in detail. Optimum separation of OPA-labeled amino acids was obtained in less than 200 s with 20 mM borate buffer (pH 9.0) containing 20% acetonitrile and 10 mM beta-cyclodextrin. Detection limits for amino acids (alanine (Ala), taurine (Tau), glycine (Gly), glutamic acid (Glu), and aspartic acid (Asp)) of 0.38-1.0 muM were achieved. The method was successfully applied to analysis of amino acids in human vascular endothelial cells (ECV-304). The average amount of amino acids in single ECV-304 cells is estimated to be 5.84 fmol for Ala, 2.78 fmol for Tau, 1.15 fmol for Gly, 3.10 fmol for Glu, and 1.30 fmol for Asp.