未修饰的纳米金结合等位特异性扩增来检测K-ras基因点突变

将等位基因特异性扩增的特异性与纳米金特殊的光学性质相结合, 发展了一种新的基因点突变检测方法. 以肿瘤中常见的K-ras癌基因第12位密码子作为点突变检测对象, 采用突变型引物对待测序列进行等位特异性扩增. 突变型样品扩增产物中大部分是双链DNA; 而野生型样品由于不能被顺利扩增, 产物中大部分是单链DNA. 以纳米金颗粒作为报告基团, 向两种不同基因型扩增产物中依次加入纳米金胶和盐溶液, 野生型基因扩增产物中的单链引物被吸附到纳米金颗粒表面, 使得纳米金在适宜浓度的盐溶液中不发生聚集; 突变型样品扩增产物中的双链DNA由于与纳米金颗粒间存在静电斥力而不能被吸附到纳米金颗粒表面, 纳米金在该浓度的盐溶液中发生聚集, 导致两种基因型的混合液在吸收光谱和颜色方面均存在显著差异, 从而实现了检测基因点突变的目的. 该检测方法直观、快速、简便, 实验成本低, 能够检测到pmol量级的样品, 为点突变检测提供了一种实用的新方法.     

纳米探针芯片技术用于微量乙肝病毒DNA的检测

利用两组探针修饰的微粒:(1)表面标记有可与待测乙肝病毒(HBV) DNA另一端结合的纳米金探针1(信号探针)以及可与信号探针部分结合的纳米金探针2(检测探针);(2)表面标记有可与待测HBV DNA一端结合的磁珠探针(捕捉探针1).检测靶HBV DNA时,磁珠探针与信号探针在液相中可分别与HBV DNA靶序列一端结合最终形成三明治样结构.再以磁场将三明治样复合物从反应液中分离,以DTT溶液将信号探针从纳米金颗粒上洗脱.洗脱后的信号探针数量反映靶基因的多寡,信号探针一段与预先点样的基因芯片上的捕捉探针2结合,检测探针与信号探针另一段相结合,最后用银染液将检测探针显色从而得到靶目标DNA相对定量信息.结果表明,本检测方法的检测灵敏度达到10-15 mol/L水平.检测时间少于1.5 h,检测结果与HBV DNA水平呈现较好的线性关系且无假阳性结果;本方法有望用于乙肝病人血清中HBV DNA的快速筛测及其它微生物基因的检测.     

采用电活性标记物N-(2-乙基-二茂铁)马来酰亚胺检测与表面固定的 一致性双链DNA特异性作用的p53蛋白质

建立了电化学检测表面固定捕获的野生型p53蛋白质的方法. 首先在金电极表面形成巯基化的单链DNA探针/己硫醇(HT)混合自组装膜, 随后巯基化的单链DNA探针与溶液中序列匹配的靶点DNA杂交, 所形成的一致性双链DNA捕获溶液中的野生型p53蛋白质. p53分子表面的半胱氨酸残基采用巯基特异性试剂N-(2-乙基-二茂铁)马来酰亚胺(Fc-Mi)进行衍生. 通过检测二茂铁的电化学信号来指示p53与一致性双链DNA之间的特异性相互作用. p53蛋白质与双链DNA的键合程度取决于双链DNA的序列. 该方法可检测的p53最低浓度为1.33 nmol•L－1.     

双重信号放大的乙酰胆碱酯酶电化学传感器检测有机磷农药

基于生物催化纳米金的生成和纳米金粒子电催化银沉积实现两次信号放大的原理,构建了一种快速、灵敏的乙酰胆碱酯酶电化学传感器,用于检测有机磷农药。固定在金电极表面的乙酰胆碱酯酶催化底物氯化乙酰硫代胆碱产生硫代胆碱,硫代胆碱还原氯金酸生成纳米金,将电极置于1.0 mol/L NH3-2.0×10#3mol/L AgNO3的银增强液中,由于纳米金粒子的催化作用,在#0.10 V的电压下,银只会沉积在生成的纳米金表面,沉积银的量与生成的纳米金颗粒的数目成正比,通过线性扫描伏安法定量检测沉积的银。在0.1~1000μg/L范围内,乙酰胆碱酯酶的抑制剂马拉硫磷的浓度与银的溶出峰呈线性,线性方程为i pa=149.9-40.49lgC(r=0.9963),检出限为0.05μg/L。本方法极大地提高了传感器检测的灵敏度。将其应用于湘江水样中马拉硫磷的检测,回收率在95.5%~102.2%之间,结果满意。     

利用互补核酸杂交富集金胶实现信号扩增的电化学凝血酶蛋白生物传感器研究

介绍了一种利用互补核酸杂交富集金胶实现信号扩增的蛋白质生物传感器. 以凝血酶蛋白为研究对象, 利用凝血酶蛋白相对应的两段核酸适配体, 将适配体Ⅰ固定在磁性颗粒上, 用于特异性地捕获蛋白, 将适配体Ⅱ标记金胶作为检测信标. 由凝血酶蛋白和相对应的两段核酸适配体构建三明治结构的凝血酶蛋白生物传感器. 另外, 再通过信标金胶上过剩的核酸适配体链与另一段标记有金胶的互补核酸进一步杂交, 获得金胶的选择性聚集, 实现了信号扩增. 通过信号扩增, 使此传感器的灵敏度大大提高, 对凝血酶蛋白的检测下限可达到4.52×10-15 mol/L. 平行测定浓度为7.47×10-14 mol/L的凝血酶8次, 其RSD为3.0%. 该生物传感器对凝血酶蛋白有很好的特异性, 其它蛋白如溶菌酶和牛血清白蛋白的存在对于检测没有影响.     

液相表面增强拉曼光谱传感器的制备方法及其核酸检测的应用

本发明公开了液相表面增强拉曼光谱传感器的制备方法及其核酸检测的应用。该传感器包含检测基底和SERS探针两部分。检测基底为四面体DNA探针修饰的磁核枝杈状金壳纳米颗粒,SERS探针为表面修饰有能与目标核酸杂交的特定碱基序列和拉曼信号分子的金纳米颗粒。检测是,将检测基底、SERS探针与待检测液体样品混合,通过碱基互补配对形成"检测基底目标核酸SERS探针"夹心结构复合物,借助外加磁场分离检测液中的复合物并富集后进行SERS测试,利用SERS信号实现了对于血清中核酸的高灵敏、特异性检测,检测限达到f M,可实现在血清等复杂环境中检测核酸标志物。     

基于金纳米颗粒的比色传感体系用于前列腺特异性膜抗原的检测

发展了一种基于金纳米颗粒的比色传感体系用于检测前列腺特异性膜抗原的新方法.实验中合成了带有正电荷的金纳米颗粒,并设计了一段带有负电荷的前列腺特异性膜抗原的底物肽段.该方法基于金纳米颗粒聚集状态不同导致颜色变化的性质以及酶与底物的特异性识别作用,达到前列腺特异性膜抗原的检测.带正电荷的金纳米颗粒与带负电的肽段产生静电相互作用,引起金纳米颗粒的聚集;当体系中加入前列腺特异性膜抗原后,由于前列腺特异性膜抗原与肽段的特异性识别作用,带负电的肽段水解为谷氨酸碎片分子,导致金纳米颗粒的分散,反应体系颜色变化快速、明显.该方法简单、灵敏,线性范围为2～10 nmol/L,检测限为0.5 nmol/L.此外,该方法可用于标准加入法测定尿液中的PSMA.     

基于SERS纳米探针的细胞内硝基还原酶检测

在缺氧的肿瘤细胞内, 硝基还原酶(NTR)通常过表达且其含量高低与缺氧程度呈正相关, 因此开发高选择性检测NTR的方法对早期肿瘤诊断至关重要. 本文通过修饰对硝基苯硫酚(p?NTP)到金纳米粒子(Au NPs)表面构建了一种表面增强拉曼散射(SERS)探针. 在缺氧条件下, 以还原型烟酰胺腺嘌呤二核苷酸(NADH)作为电子供体, NTR可催化还原芳香硝基为芳香胺, 导致纳米探针的SERS光谱发生变化, 从而实现NTR的高选择性检测, 检出限低至18 ng/mL. 该探针毒性低、 生物兼容性好, 可用于缺氧条件下A549细胞内的NTR分析, 为肿瘤细胞的缺氧现象评估提供了一种有效的策略.     

基于金@二氧化锰纳米片超级纳米粒子从比色到单颗粒光谱检测谷胱甘肽

合成了由金纳米球和二氧化锰薄片组成的金@二氧化锰纳米片超级纳米粒子(AMNS-SPs), 将其作为探针, 利用比色和单颗粒光谱2种分析方法进行了谷胱甘肽的传感检测. 该传感检测基于选择性刻蚀探针AMNS-SPs中的二氧化锰纳米片, 使得该探针的局域表面等离子共振波长蓝移. 实验结果表明, 比色法和单颗粒光谱法检测谷胱甘肽的检出限分别为0.018 μmol/L和23.2 fmol/L, 且后者是目前检测谷胱甘肽灵敏度最高的传感方法之一. 该传感方法的优异性能主要源于非常薄的二氧化锰纳米片.     

硫化金包覆金纳米棒局域等离子体共振的纳米生物传感器研究

纳米生物传感技术是近年来迅速发展起来的一种超微生物传感技术,具有高选择性、高灵敏度、快速、方便检测等优点.尤其基于金纳米颗粒的生物探针的研究备受关注.近年来,对基于棒状金纳米结构的生物探针合成及在生物传感及医学成像中的应用的研究是金纳米棒研究的重要方向.纳米金由于其制备简单、易于修饰、稳定性和生物相容性好等优点,被广泛应用于生物分子的识别和检测领域.     

Electrochemical Determination of the p53 Tumor Suppressor Gene Using a Gold Nanoparticle-Graphene Nanocomposite Modified Glassy Carbon Electrode

A novel sensitive and simple electrochemical DNA sensor is reported for the determination of p53 tumor suppressor gene. A gold nanoparticle/graphene nanocomposite-modified glassy carbon electrode was prepared and methylene blue was used as the hybridization redox indicator. Scanning electron microscopic and electrochemical characterization demonstrated that the gold nanoparticles and graphene were present on the electrode. The resulting sensor provided suitable electrochemical response to the p53 tumor suppressor gene with a linear dynamic range from 0.1 to 1000?nM. The limit of detection was 0.012?nM. The sensor was able to differentiate a complete complementary DNA sequence, single-base mismatched DNA sequence, and a three-base mismatched DNA sequence. The precision of the device was satisfactory, with a relative standard deviation of 4.1% for 11 measurements. The combination of gold nanoparticles and a graphene nanocomposite provided enhanced capabilities for the determination of DNA for clinical applications.     

Colloidal gold-polystyrene bead hybrid for chemiluminescent detection of sequence-specific DNA

A sensitive chemiluminescent (CL) detection of sequence-specific DNA has been developed by taking advantage of a magnetic separation/mixing process and the amplification feature of colloidal gold labels. In this protocol, the target oligonucleotides are hybridized with magnetic bead-linked capture probes, followed by the hybridization of the biotin-terminated amplifying DNA probes and the binding of streptavidin-coated gold nanoparticles; the nanometer-sized gold tags are then dissolved and quantified by a simple and sensitive luminol CL reaction. The proposed CL protocol is evaluated for a 30-base model DNA sequence, and the amount as low as 0.01 pmol of DNA is determined, which exhibits a 150 x enhancement in sensitivity over previous gold dissolution-based electrochemical formats and an enhancement of 20 x over the ICPMS detection. Further signal amplification is achieved by the assembly of biotinylated colloidal gold onto the surface of streptavidin-coated polystyrene beads. Such amplified CL transduction allows detection of DNA targets down to the 100 amol level, and offers great promise for ultrasensitive detection of other biorecognition events.     

Homogeneous DNA Detection Based on Fluorescence Quenching by Nanoparticles in Single-step Format :Target-Induced Configuration Transform

A new strategy for homogeneous detection of DNA hybridization in single-step format was developed based on fluorescence quenching by gold nanoparticles. The gold nanoparticle is functionalized with 5’-thiolated 48-base oligonucleotide (probe sequence), whose 3’-terminus is labeled with fluorescein (FAM), a negatively charged fluorescence dye. The oligonucleotide adopts an extended configuration due to the electrostatic repulsion between negatively charged gold nanoparticle and the FAM-attached probe sequence. After addition of the complementary target sequence, specific DNA hybridization induces a conformation change of the probe from an extended structure to an arch-like configuration, which brings the fluorophore and the gold nanoparticle in close proximity. The fluorescence is efficiently quenched by gold nanoparticles. The fluorescence quenching efficiency is related to the target concentration, which allows the quantitative detection for target sequence in a sample. A linear detection range from 1.6 to 209.4 nmol/L was obtained under the optimized experimental conditions with a detection limit of 0.1 nmol/L. In the assay system, the gold nanoparticles act as both nanoscaffolds and nanoquenchers. Furthermore, the proposed strategy, in which only two DNA sequences are involved, is not only different from the traditional molecular beacons or reverse molecular beacons but also different from the commonly used sandwich hybridization methods. In addition, the DNA hybridization detection was achieved in homogenous solution in a single-step format, which allows real-time detection and quantification with other advantages such as easy operation and elimination of washing steps.     

纳米金放大计时库仑法的PML/RARα融合基因检测

应用恒电位在金基底表面电化学沉积纳米金,通过Au—S键将巯基修饰DNA探针固定在纳米金表面,与互补靶序列杂交,构建计时库仑电化学DNA传感器,并检测急性早幼粒细胞白血病(APL)PML/RARα融合基因.采用扫描电子显微术(SEM)与电化学交流阻抗技术(EIS)观察纳米金和表征DNA传感器的构筑过程.以氯化六氨合钌([Ru(NH3)6]Cl3,RuHex)作电化学杂交指示剂,由计时库仑法检测人工合成APL的PML/RARα融合基因.结果表明,纳米金能放大RuHex检测信号,杂交前后电量差值(ΔQ)与靶标链DNA浓度的对数(lgC)值在1.0×10-13～1.0×10-9mol.L-1范围内呈线性关系,检出下限3.7×10-14mol.L-1(S/N=3).该法操作简便、特异性好,有望用于实际样品的检测.     

Rapid Colorimetric Identification and Targeted Photothermal Lysis of Salmonella Bacteria by Using Bioconjugated Oval‐Shaped Gold Nanoparticles

Salmonella bacteria are the major cause for the infection of 16 million people worldwide with typhoid fever each year. Antibiotic‐resistant Salmonella strains have been isolated from various food products. As a result, the development of ultrasensitive sensing technology for detection and new approaches for the treatment of infectious bacterial pathogens that do not rely on traditional therapeutic regimes is very urgent for public health, food safety, and the world economy. Driven by this need, we report herein a nanotechnology‐driven approach that uses antibody‐conjugated oval‐shaped gold nanoparticles to selectively target and destroy pathogenic bacteria. Our experiments have shown the use of a simple colorimetric assay, with an anti‐salmonella antibody conjugated to oval‐shaped gold nanoparticles, for the label‐free detection of S. typhimurium with an excellent detection limit (10⁴ bacteria per mL) and high selectivity over other pathogens. When bacteria conjugated to oval‐shaped gold nanoparticles were exposed to near‐infrared radiation, a highly significant reduction in bacterial cell viability was observed due to photothermal lysis. Ideally, this nanotechnology‐based assay would have enormous potential for rapid, on‐site pathogen detection to avoid the distribution of contaminated foods.     

Mass spectrometry signal amplification for ultrasensitive glycoprotein detection using gold nanoparticle as mass tag combined with boronic acid based isolation strategy

We describe a novel method for rapid and ultrasensitive detection of intact glycoproteins without enzymatic pretreatment which was commonly used in proteomic research. This method is based on using gold nanoparticle (AuNP) as signal tag in laser desorption/ionization mass spectrometry (LDI-MS) analysis combined with boronic acid assisted isolation strategy. Briefly speaking, target glycoproteins were firstly isolated from sample solution with boronic acid functionalized magnetic microparticles, and then the surface modified gold nanoparticles were added to covalently bind to the glycoproteins. After that, these AuNP tagged glycoproteins were eluted from magnetic microparticles and applied to LDI-MS analysis. The mass signal of AuNP rather than that of glycoprotein was detected and recorded in this strategy. Through data processing of different standard glycoproteins, we have demonstrated that the signal of AuNP could be used to quantitatively represent glycoprotein. This method allows femtomolar detection of intact glycoproteins. We believe that the successful validation of this method on three different kinds of glycoproteins suggests the potential use for tracking trace amount of target glycoproteins in real biological samples in the near future.     

Detection of DNA immobilized on bare gold electrodes and gold nanoparticle-modified electrodes via electrogenerated chemiluminescence using a ruthenium complex as a tag

Electrogenerated chemiluminescence (ECL) for DNA hybridization detection is demonstrated based on DNA that was self-assembled onto a bare gold electrode and onto a gold nanoparticles modified gold electrode. A ruthenium complex served as an ECL tag. Gold nanoparticles were self-assembled on a gold electrode associated with a 1,6-hexanedithiol monolayer. The surface density of single stranded DNA (ssDNA) on the gold nanoparticle modified gold electrode was 4.8?×?10¹⁴ molecules per square centimeter which was 12-fold higher than that on the bare gold electrode. Hybridization was induced by exposure of the target ssDNA gold electrode to the solution of ECL probe consisting of complementary ssDNA tagged with ruthenium complex. The detection limit of target ssDNA on a gold nanoparticle modified gold electrode (6.7?×?10^?12 mol L^?1) is much lower than that on a bare gold electrode (1.2?×?10^?10 mol L^?1). The method has been applied to the detection of the DNA sequence related to cystic fibrosis. This work demonstrates that employment of gold nanoparticles self-assembled on a gold electrode is a promising strategy for the enhancement of the sensitivity of ECL detection of DNA.     

Gold nanoparticles for microfluidics-based biosensing of PCR products by hybridization-induced fluorescence quenching

Colloidal gold nanoparticles were used to develop a simple microfluidics-based bioassay that is able to recognize and detect specific DNA sequences via conformational change-induced fluorescence quenching. In this method, a self-assembled monolayer of gold nanoparticles was fabricated on the channel wall of a microfluidic chip, and DNA probes were bonded to the monolayer via thiol groups at one end and a fluorophore dye was attached to the other end of the probe. The created construct is spontaneously assembled into a constrained arch-like conformation on the particle surface and, under which, the fluorescence of fluorophores is quenched by gold nanoparticles. Hybridization of target DNAs results in a conformational change of the construct and then restores the fluorescence, which serves as a sensing method for the target genes. The nanocomposite constructed on the glass surface was characterized by UV absorbance measurement and the quenching efficiency for different fluorophores was evaluated by Stern-Volmer studies. The applicability of proposed assay was first demonstrated by the use of a pair of synthesized complementary and noncomplementary DNA sequences. The method was further applied for the detection of the PCR product of dengue virus with the use of enterovirus as the negative control, and results indicate that the assay is specific for the target gene. Moreover, using this approach, dehybridization, hybridization, and detection of the target genes can be performed in situ on the same microfluidic channel. Thus, this method could be regarded as one-pot reaction and it holds great promises for clinical diagnostics.     

Functionalized gold nanoparticles for ultrasensitive DNA detection

A major challenge in the area of DNA detection is the development of rapid methods that do not require polymerase chain reaction (PCR) amplification of the genetic sample. The PCR amplification step increases the cost of the assay, the complexity of the detection, and the quantity of DNA required for the assay. In this context, methods that are able to perform DNA analyses with ultrasensitivity have recently been investigated with the aim of developing new PCR-free detection protocols. Functionalized gold nanoparticles have played a central role in the development of such methods. Here, possibilities offered by functionalized gold nanoparticle in the ultrasensitive detection of DNA are discussed. The different functionalization protocols available for gold nanoparticles and the principal DNA detection methods that are able to detect DNA at the femtomolar to attomolar level are presented.     

Femtomolar electrochemical detection of DNA targets using metal sulfide nanoparticles

A new electrochemical DNA sensor providing detection capabilities down to 100 attomol of target DNA has been developed. The method applies CdS, ZnS, and PbS nanoparticles conjugated with short DNA sequences which are immobilized via hybridization with complementary sequences on a gold surface. When the DNA target is added, it can be identified by ousting the existing hybridization between one of the DNA-nanoparticle conjugates and the surface DNA. The nanoparticles remaining at the surface are detected by stripping voltammetry. The setup is constructed to give a signal-off response with a build-in control signal as only one of two different metal sulfide signaling probes on the surface is removed by hybridization with the DNA target. The competition assay is, in principle, label-free since no labels are required for detection after addition of DNA target. The dissociation of PbS nanoparticles from the surface after addition of the DNA target has been imaged by fluid phase AFM.