基于纳米金探针和基因芯片的DNA检测新方法

运用荧光纳米金探针和基因芯片杂交建立一种新的DNA检测方法. 荧光纳米金探针表面标记有两种DNA探针: 一种为带有Cy5荧光分子的信号探针BP1, 起信号放大作用; 另一种为与靶DNA一部分互补的检测探针P532, 两种探针比例为5∶1. 当靶DNA存在时, 芯片上捕捉探针(与靶DNA的另一部分互补)通过碱基互补配对结合靶DNA, 将靶DNA固定于芯片上; 荧光纳米金探针通过检测探针与靶DNA及芯片结合, 在芯片上形成“三明治”复合结构, 最后通过检测信号探针上荧光分子的信号强度来确定靶DNA的量. 新方法检测灵敏度高, 可以检测浓度为1 pmol/L的靶DNA, 操作简单, 检测时间短. 通过改进纳米金探针的标记和优化杂交条件, 可进一步提高核酸检测的灵敏度, 这将在核酸检测方面具有重要的应用价值.     

基于双纳米金探针杂交法检测HBV DNA

利用双纳米金探针结合基因芯片平台建立了一种检测乙肝病毒基因(HBV DNA)的新方法. 根据HBV DNA的保守序列设计捕获探针和信号报告探针, 通过一对互补的纳米金检测探针的双杂交法对HBV DNA进行信号放大, 最后进行银染, 达到对HBV DNA的可视化检测. 该方法的灵敏度高, 可检测10 fmol/L的HBV DNA, 且能在1.5 h内完成检测. 其具有的快速、 高灵敏度及低成本等优势使其有望发展成为一种检测HBV DNA的新方法.     

SERS标记的金纳米棒探针用于免疫检测

报道了基于金纳米棒表面增强拉曼散射(SERS)的免疫检测. 将拉曼活性分子对巯基苯甲酸吸附于金纳米棒表面, 制备出SERS标记的金纳米棒探针. 该探针和蛋白抗体结合形成SERS标记抗体. 通过SERS标记抗体、待测抗原和俘获抗体(固体基底上修饰的抗体, 即俘获抗体)之间的免疫应答反应, 将金纳米棒探针组装到固体基底上, 形成SERS标记抗体-抗原-俘获抗体 “三明治”夹心复合体. 待测抗原浓度越大, 固体基底上俘获的金纳米棒探针的数目越多, 从而可通过SERS信号的强弱来检测待测抗原的浓度. 由于金纳米棒的表面等离子体共振(SPR)峰位置可以在较宽的范围内调控, 可通过激发光和SPR的耦合来提高SERS信号, 从而提高免疫检测的灵敏度. 单组分抗原可检出的浓度范围高于1×10－8 mg/mL.     

基于分子识别作用鉴别人参基因的电化学传感器

本文以人参ITS及518 s基因上的SNP位点为检测对象,利用分子识别作用构建了一种电化学传感器,成功地对人参、西洋参进行了品种鉴别。本文设计合成了一种双标记DNA探针(DLP),该探针的一端标记了4-4-二甲氨基苯基偶氮苯甲酸(dabcyl)作为客体分子,另一端标记了金纳米颗粒作为电化学杂交指示剂。同时使用α-CD/MCNTs/GCE电极作为工作电极。由于DLP的茎环结构,只有在DLP与目标DNA杂交后,DLP上的dabcyl分子进入修饰电极表面的α-CD空腔中,进而DLP被α-CD修饰电极捕获。并且,通过金纳米颗粒的AuCl4-的电化学还原电流信号。可灵敏检测4.6×10-10mol.L-1的目标DNA。     

组蛋白乙酰化的耦合增强拉曼散射生物传感方法

提出了一种组蛋白乙酰化修饰检测的耦合增强拉曼散射生物传感新方法. 该方法以金纳米粒子为表面增强拉曼散射(SERS)基底, 表面修饰乙酰化组蛋白H3多肽为识别探针, 对甲氧基苯硫酚(4-MTP)为拉曼标记物, 制备了组蛋白乙酰化修饰检测的SERS纳米探针. 通过紫外可见吸收光谱与动态光散射分析, 证实了组蛋白乙酰化抗体可介导SERS纳米粒子发生可控组装与聚集, 使SERS纳米探针间发生局域电场共振耦合, 产生显著增强的SERS信号. 基于此, 通过待测抗原与SERS纳米探针对抗体的竞争性相互作用, 我们设计了组蛋白乙酰化修饰检测的竞争免疫SERS生物传感方法. 该法操作简便、快速、重现性好, 且裸眼即能进行可视化鉴定. 通过设计不同染料标记的SERS纳米探针, 该法有望实现多种组蛋白修饰的复合检测.     

量子点双标记的Fe3O4@Au磁性纳米DNA电致发光型传感器

合成了Fe3O4@Au磁性纳米粒子,并根据单链寡聚核苷酸(ss-DNA)杂交原理,利用量子点电化学发光,构建了DNA电化学传感器.在磁控玻碳电极(MCGCE)表面,将5′-SH-ssDNA捕获探针自组装在Fe3O4@Au磁性纳米粒子上,然后与目标DNA互补的一端杂交形成dsDNA,再与双标记了量子点的5′-NH2-ssDNA-NH2-3′信号探针杂交形成三明治杂交的DNA.应用循环伏安法对DNA的固定与杂交进行了表征.目标DNA浓度在1.0×10-13～1.0×10-11 mol/L范围与其响应的ECL信号呈线性关系,检出限为1.8×10-14mol/L.由于采用量子点双标记法,检测的灵敏度显著提高.     

抗体和寡核苷酸双标记纳米金生物探针的制备及生物学特性

纳米金通过静电吸附抗体, 与寡核苷酸共价结合制备双标记纳米金生物探针, 比较了双标记纳米金生物探针和单标记抗体IgG或ss-DNA的稳定性和反应性. 结果表明, 在水溶液中纳米金由于ss-DNA的结合使IgG抗体的吸附能力明显改善, IgG的吸附也影响二硫苏糖醇(DDT)对ss-DNA的解离作用. 双标记纳米粒上覆盖(50±15)条ss-DNA和(10±2)条IgG, 较单标记ss-DNA纳米金上的(70±15)条要少. 斑点免疫和杂交实验证明, 纳米金表面标记的IgG和ss-DNA具有良好生物学活性. 双标记纳米金生物探针在超微量蛋白质的检测中具有应用价值.     

基于纳米金复合探针-蛋白芯片检测心肌损伤标志物

运用纳米金复合探针结合蛋白芯片,建立了一种检测心肌损伤标志物的新方法.构建了2种纳米金探针:标记有检测抗体和DNA探针1的检测探针和标记有DNA探针2(与DNA探针1的碱基互补配对)的信号探针.当目的抗原存在时,检测探针经检测抗体和抗原,与芯片上捕获抗体结合固定在芯片上,信号探针通过碱基互补配对与检测探针结合使信号放大,最后利用纳米金成核原理染色,通过显微镜观察结果并定量分析.该体系在40 min内可检测多种标志物,其中肌钙蛋白Ⅰ(c TnⅠ)的检出限为10 pg/m L,与临床电化学发光法(ECLIA)灵敏度相当;肌红蛋白(MYO)与新型脂肪酸结合蛋白(HFABP)的检出限分别为640和10 pg/m L,与ECLIA及酶联免疫吸附法(ELISA)相比,灵敏度显著提高.     

基于表面增强拉曼光谱的重金属离子检测

以对巯基苯甲酸为拉曼标记和自组装修饰分子, 在光亮金基底上修饰后作为检测基底, 在金纳米粒子表面修饰后获得具有表面增强拉曼光谱信号的标记金溶胶. 修饰的基底及纳米离子通过重金属离子与羧基端的配位而发生相互作用, 最终形成“金属基底-对巯基苯甲酸/重金属离子/对巯基苯甲酸-金属纳米颗粒”的三明治结构. 采用扫描电镜表征纳米粒子的组装及以表面增强拉曼光谱检测表面标记分子的信号, 以此实现重金属离子的检测. 以强螯合剂EDTA溶液淋洗三明治结构, 使重金属离子与金属基底以及纳米颗粒上的羧基的配位作用断裂, 获得可再次利用的修饰金基底.     

纳米金信号探针/石墨烯修饰免疫传感器检测微囊藻毒素

利用石墨烯纳米片层(GS)偶联牛血清白蛋白(BSA)标记的微囊藻毒素(MCLR)(BSA-MCLR)构建了纳米金(Au NPs)为信号探针的电流型免疫传感器。分别用扫描电子显微镜(SEM)、透射电子显微镜(TEM)和紫外-可见吸收光谱对合成纳米材料进行表征;用循环伏安法研究修饰电极表面的电化学特性。通过待测MCLR与固定的BSA-MCLR竞争结合抗体(anti-MCLR),之后恒电位将Au NPs氧化为Au Cl-4,再利用差分脉冲伏安法(DPV)进行阴极电位扫描,还原Au Cl-4为Au,以产生的峰电流值为检测信号,测定MCLR浓度。最佳实验条件下,用免疫传感器测定MCLR的线性范围为0.1~50μg/L,检出限为0.05μg/L。对传感器的重现性、稳定性和选择性进行了考察。相较于酶标探针,以Au NPs为信号探针标记抗体,可使检测过程更经济便捷,稳定性更强,检测效果良好。     

Gold Nanoparticle-based Layer-by-Layer Enhancement of DNA Hybridization Electrochemical Signal at Carbon Nanotube Modified Carbon Paste Electrode

Nanoporous materials have been widely applied to biosensor investigation. Recently, Guo et al. have investigated the mesoporous materials modified carbon paste electrode for rapid cTnI (cardiac troponin I) detection with enhanced sensitivity1-3. However, …     

Electrochemical Monitoring of DNA Hybridization by Multiwalled Carbon Nanotube Based Screen Printed Electrodes

The application of multiwalled carbon nanotube (MWCNT) based screen printed graphite electrodes (SPEs) was explored in this study for the electrochemical monitoring of DNA hybridization related to specific sequences on Hepatitis B virus (HBV) DNA. After the microscopic characterization of bare MWCNT‐SPEs and DNA immobilized ones was performed, the optimization of assay has been studied. The development of screen printing process combined with nanomaterial based disposable sensor technology leads herein a great opportunity for DNA detection using differential pulse voltammetry (DPV) by measuring the guanine oxidation signal observed at +1.00 V in the presence of DNA hybridization between HBV probe and its complementary, target. The detection limit estimated for signal to noise ratios =3 corresponds to 96.33 nM target concentration in the 40 μL samples. The advantages of carbon nanotube based screen printed electrode used for electrochemical monitoring of DNA hybridization are discussed with sensitivity, selectivity and reproducibility in comparison with previous nanomaterial based electrochemical transducers developed for DNA or other biomolecular recognitions.     

基于银纳米粒子构建荧光传感平台用于核酸检测

报道了基于银纳米粒子构建的荧光传感平台,并用于核酸检测.此荧光传感平台对核酸检测基于以下策略:首先,荧光团标记的单链DNA探针被吸附到银纳米粒子的表面,荧光团与银纳米粒子近距离接触,发生荧光猝灭;加入与探针DNA序列互补的目标DNA,两者杂交形成双链DNA,并从银纳米粒子的表面脱离,荧光得到恢复.这种银纳米粒子构建的荧...     

商品化血糖仪用于乙型肝炎病毒的便携式体外分子诊断

为解决当前乙型肝炎病毒(HBV)基因检测技术在一定程度上存在成本高、操作繁琐、误诊率高等问题,在此提出了一种便携式生物传感平台用于HBV基因的超灵敏检测,可检出低至2 copies/μL的HBV基因.首次通过设计针对HBV检测序列的环介导等温扩增(LAMP)反应,实现了在40 min之内对HBV基因型单拷贝基因的检测....     

A Novel DNA Probe Based on Molecularly Imprinted Polymer Modified Electrode for the Electrochemical Monitoring of DNA

A DNA probe that was based on methylene blue (MB) imprinted polyvinyl pyridine polymer (MIP) modified carbon paste electrodes were developed for the first time for electrochemical monitoring of DNA. Probes were built up by adsorbing MB onto modified electrodes prior to DNA immobilization. It was shown that DNA strongly immobilizes on MIP modified electrodes when MB was adsorbed in advance of DNA immobilization. The performance of the MB imprinted polymer modified carbon paste electrodes (MIP‐CPE) to rebind the template molecule (MB) were compared to those of control polymer modified (non‐imprinted polymer NIP‐CPE) and bare (CPE) electrodes. Electrochemical signal resulting from the oxidation of guanine moiety of the immobilized probe DNA was high enough on the constructed platform, implicating that probes of this kind could be favorably used for DNA analysis. These probes exhibited high selectivity for its complementary DNA sequences (target). HBV‐DNA hybridization was studied to evaluate the selectivity of the probes for complementary, non‐complementary and mismatch sequences. The detection limit of the probe for the target DNA was 8.72 µg/mL (1.38 µM), which was better than those attained by some earlier DNA sensor studies.     

Electrochemical Detection of DNA Hybridization Based on the Probe Labeled with Carbon‐Nanotubes Loaded with Silver Nanoparticles

A sensitive electrochemical method for the detection of DNA hybridization based on the probe labeled with multiwall carbon‐nanotubes (MWNTs) loaded with silver nanoparticles (Ag‐MWNTs) has been developed. MWNTs were electroless‐plated with a large number of silver nanoparticles to form Ag‐MWNTs. Probe single strand DNA (ss‐DNA) with a thiol group at the 3′‐terminal labeled with Ag‐MWNTs by self‐assembled monolayer (SAM) technique was employed as an electrochemical probe. Target ss‐DNA with a thiol group was immobilized on a gold electrode by SAM technique and then hybridized with the electrochemical probe. Binding events were monitored by differential pulse voltammetric (DPV) signal of silver nanoparticles. The signal difference permitted to distinguish the match of two perfectly complementary DNA strands from the near perfect match where just three base pairs were mismatched. There was a linear relation between the peak current at +120 mV (vs. SCE) and complementary target ss‐DNA concentration over the range from 3.1×10^?14 to 1.0×10^?11 mol/L with a detection limit of 10 fmol/L of complementary target ss‐DNA. The proposed method has been successfully applied to detection of the DNA sequence related to cystic fibrosis. This work demonstrated that the MWNTs loaded with silver nanoparticles offers a great promising approach for sensitive detection of DNA hybridization.     

Electrochemical DNA biosensor for the detection of TT and Hepatitis B virus from PCR amplified real samples by using methylene blue

DNA biosensors based on nucleic acid hybridization processes are rapidly being developed towards the goal of rapid and inexpensive diagnosis of genetic and infectious diseases. Electrochemical transducers are often being used for detecting the DNA hybridization event, due to their high sensitivity, small dimensions, low cost, and compatibility with microfabrication technology. In this study, an electrochemical biosensor for the voltammetric detection of DNA sequences related to the Hepatitis B virus (HBV) and TT virus (TTV) from polymerase chain reaction (PCR) amplified real samples is described for the first time. The biosensor relies on the immobilization of the 21- or 24-mer single stranded oligonucleotides (probe) related to the HBV and TTV sequences and hybridization of these oligonucleotides with their complementary sequences (target) at carbon paste electrode (CPE). The extent of hybridization between the probe and target sequences was determined by using square wave voltammetry (SWV) with moving average baseline correction and methylene blue (MB) as the hybridization indicator. As a result of the interaction between MB and the bound guanine bases of hybrid at CPE surface, the MB signal decreased, when it was compared with the MB signal, which was observed with probe modified CPE. The difference between the MB signals, obtained from the hybrid modified and the probe modified CPE is used to detect the DNA sequences of the infectious diseases from PCR amplified real samples. Numerous factors affecting the target hybridization and indicator binding reactions are optimized to maximize the sensitivity.     

Electrochemical DNA Sensor Using Ferrocenyl Naphthalene Diimide Ligand

Searching for the method for gene detection is vitally important with the development of genetic diagnosis. Generally gene detection is carried out by the judgment of existence of signal of DNA probe (labeled complementary sequence) bound to target DNA sequence. Since sample DNA is immobilized on the solid support, non-bound DNA probe is washed out from the support.