微囊藻属DNA电化学传感器的研制

利用自组装法将巯基修饰的DNA探针与6-巯基-1-己醇(MCH)固定到金电极表面,制备了微囊藻属特定DNA传感器,将该传感器与完全互补的微囊藻DNA序列、完全不互补序列,以及单碱基错配序列进行杂交,以Hoechst 33258为杂交指示剂,应用循环伏安法和线性扫描伏安法研究了该传感器对目标DNA的电化学检测行为.研究表明,当与完全互补DNA杂交后,Hoechst 33258氧化信号有明显的增强.实验对自组装时间、MCH浸泡时间及杂交液离子浓度进行了优化.结果表明,当自组装时间为90 min,MCH浸泡时间为1 h,杂交溶液中NaCl浓度为0.3 mol/L时,电化学信号最好.目标DNA的氧化峰电流值与其浓度在1×10~(-8) ～1×10~(-6) mol/L范围内呈良好的线性关系,检出限为8.1×10~(-9) mol/L.     

Catalytic Hairpin Assembly‐Programmed DNA Three‐Way Junction for Enzyme‐Free and Amplified Electrochemical Detection of Target DNA

DNA three‐way junctions (DNA 3WJ) have been widely used as important building blocks for the construction of DNA architectures and dynamic assemblies. Herein, we describe for the first time a catalytic hairpin assembly‐programmed DNA three‐way junction (CHA‐3WJ) strategy for the enzyme‐free and amplified electrochemical detection of target DNA. It takes full advantage of the target‐catalyzed hairpin assembly‐induced proximity effect of toehold and branch‐migration domains for the ingenious execution of the strand displacement reaction to form the DNA 3WJ on the electrode surface. A low detection limit of 0.5 pM with an excellent selectivity was achieved for target DNA detection. The developed CHA‐3WJ strategy also offers distinct advantages of simplicity in probe design and biosensor fabrication, as well as enzyme‐free operation. Thus, it opens a promising avenue for applications in bioanalysis, design of DNA‐responsive devices, and dynamic DNA assemblies.     

电化学DNA生物传感器*

对特异DNA序列的检测在基因相关疾病的诊断、军事反恐和环境监测等方面均具有非常重要的意义,DNA传感器的研究就是为了满足对特异DNA序列的快速、便捷、高灵敏度和高选择性检测的需要。近年来涌现出了多种传感策略,根据检测方法的不同可以大致分为光学传感器、电化学传感器、声学传感器等。由于电化学检测方法本身所具有的灵敏、快速、低成本和低能耗等特点,电化学DNA传感器已成为一个非常活跃的研究领域并在近几年中得到了快速发展。本文概括了近年来在DNA传感器的重要分支——电化学DNA传感器领域内的一些重要进展,主要包括DNA探针在传感界面上的固定方法和各种电化学DNA杂交信号的检测方法。     

Amplified Electrochemical DNA Sensor Based on Polyaniline Film and Gold Nanoparticles

In this work, an electrochemical DNA biosensor, based on a dual signal amplified strategy by employing a polyaniline film and gold nanoparticles as a sensor platform and enzyme‐linked as a label, for sensitive detection is presented. Firstly, polyaniline film and gold nanoparticles were progressively grown on graphite screen‐printed electrode surface via electropolymerization and electrochemical deposition, respectively. The sensor was characterized by scanning electron microscopy (SEM), cyclic voltammetry and impedance measurements. The polyaniline‐gold nanocomposite modified electrodes were firstly modified with a mixed monolayer of a 17‐mer thiol‐tethered DNA probe and a spacer thiol, 6‐mercapto‐1‐hexanol (MCH). An enzyme‐amplified detection scheme, based on the coupling of a streptavidin‐alkaline phosphatase conjugate and biotinylated target sequences was then applied. The enzyme catalyzed the hydrolysis of the electroinactive α‐naphthyl phosphate to α‐naphthol; this product is electroactive and has been detected by means of differential pulse voltammetry. In this way, the sensor coupled the unique electrical properties of polyaniline and gold nanoparticles (high surface area, fast heterogeneous electron transfer, chemical stability, and ease of miniaturisation) and enzymatic amplification. A linear response was obtained over a concentration range (0.2–10 nM). A detection limit of 0.1 nM was achieved.     

Electrochemical Biosensor for the Detection of Interaction Between Arsenic Trioxide and DNA Based on Guanine Signal

The interaction of arsenic trioxide (As₂O₃) with calf thymus double‐stranded DNA (dsDNA), calf thymus single‐stranded DNA (ssDNA) and also 17‐mer short oligonucleotide (Probe A) was studied electrochemically by using differential pulse voltammetry (DPV) with carbon paste electrode (CPE) at the surface and also in solution. Potentiometric stripping analysis (PSA) was employed to monitor the interaction of As₂O₃ with dsDNA in solution phase by using a renewable pencil graphite electrode (PGE). The changes in the experimental parameters such as the concentration of As₂O₃, and the accumulation time of As₂O₃ were studied by using DPV; in addition, the reproducibility data for the interaction between DNA and As₂O₃ was determined by using both electrochemical techniques. After the interaction of As₂O₃ with dsDNA, the DPV signal of guanine was found to be decreasing when the accumulation time and the concentration of As₂O₃ were increased. Similar DPV results were also found with ssDNA and oligonucleotide. PSA results observed at a low DNA concentration such as 1 ppm and a different working electrode such as PGE showed that there could be damage to guanine bases. The partition coefficients of As₂O₃ after interaction with dsDNA and ssDNA in solution by using CPE were calculated. Similarly, the partition coefficients (PC) of As₂O₃ after interaction with dsDNA in solution was also calculated by PSA at PGE. The features of this proposed method for the detection of DNA damage by As₂O₃ are discussed and compared with those methods previously reported for the other type of DNA targeted agents in the literature.     

A Piezoelectric Biosensor For DNA Hybridisation Detection

Abstract

In this paper the realisation of a piezoelectric biosensor for DNA hybridisation detection is reported. A biotinylated 25-mer, was immobilised on a (strept)avidin coated piezoelectric crystal; avidin was covalently bound to the thiol/dextran modified gold surface of the crystal. Hybridisation of the probe with a complementary sequence was detected. The device was able to distinguish among targets of different lengths. Many cycles of measurements could be performed on the same crystal surface regenerating the single strand with HCl (ImM). No signal was detected when the probe reacted with a non complementary sequence. The same experiments were performed immobilising the biotinylated DNA probe on the gold surface coated with avidin by adsorption and the results were compared.     

电化学DNA生物传感器研究的应用进展*

电化学DNA生物传感器因快速、灵敏、低耗和易于操作等优点在基因序列测定中受到了广泛的关注,已逐渐成为分子生物学和生物技术研究的重要领域。具有电活性的小分子和纳米材料因它们独特的性质,已被应用到电化学DNA生物传感器中。本文介绍了电化学DNA生物传感器的基本概念和分类,综述了近年来电活性小分子和纳米材料在电化学DNA生物传感器中的应用进展,并对此领域的未来发展做了展望。     

DNA电化学传感器在DNA片段识别与测定中的应用

本文用乙基－（３－二甲基丙基）碳二亚胺盐酸盐（ＥＤＣ）和羟基丁二酰亚胺（ＮＨＳ）活化已被氧化的石墨电极,然后将单链ＤＮＡ（ｓｓＤＮＡ－１）固定在石墨电极上。运用核酸杂交技术,使具有电化学活性的染料Ｈｏｅｃｈｓｔ ３３２５８ 嵌入双链ＤＮＡ 分子（ｄｓＤＮＡ）的碱基对中,在石墨电极表面形成ｄｓＤＮＡ－Ｈｏｅｃｈｓｔ ３３２５８ 层,通过伏安法测定嵌入Ｈｏｅｃｈｓｔ ３３２５８的氧化峰电流,可以识别和测定溶液中互补的ｓｓＤＮＡ－２ 片段,ｓｓＤＮＡ－２ 的浓度在４．８×１０－ ５～１．１×１０－ ７ ｍ ｇ／ｍ Ｌ范围内,有线性关系,检测限可达６．０×１０－ ８ ｍ ｇ／ｍ Ｌ。     

纳米粒子在电化学DNA生物传感器研究中的应用

简要介绍了电化学DNA生物传感器的原理和分类,对纳米粒子在电化学DNA生物传感器研究中的应用进行了详细评述.     

新型DNA电化学传感器的研制及其用于DNA氧化性损伤检测的研究

用溶胶-凝胶法在玻碳电极上制备了纳米多孔羟基磷灰石(HAp)-聚乙烯醇(PVA)涂层膜固定双链DNA,得到了一种新型DNA电化学传感器,检测了由Fenton反应引起的DNA氧化性损伤.结果表明,一定量浓度的抗坏血酸(AA)能加速Fenton反应的进行,使DNA损伤很快达到极限;损伤试剂中Fe²⁺的浓度越大,产生的羟基自由基(OH.)越多,对DNA的损伤就越严重;损伤试剂中EDTA的浓度越小,溶液中游离的Fe²⁺以及与DNA键合的Fe²⁺的浓度则相对越大,对DNA的损伤也就越严重.     

血清样品中乙肝病毒的DNA电化学传感器检测

利用自组装单分子膜技术，将巯己基修饰的具有乙肝病毒(HBV)DNA序列特异性的单链DNA探针固定在金电极表面，制得DNA电化学传感器；以电活性的Hoechst 33258为指示剂，考察了该传感器对血清样品中乙肝病毒DNA的响应；探讨DNA电化学传感器在临床检测中的应用；将传感器法与荧光聚合酶链反应(PCR)法进行对比，两者的分析结果具有一致性。     

A Reagentless Electrochemical DNA Sensor Based on a Self-powered DNA Machine

Herein, a reagentless electrochemical DNA sensor based on a self-powered DNA machine for detecting survivin mRNA in cells is developed. The metal-organic framework (MOFs) loaded with DNAzyme cofactors (Mn²⁺) is coated on PTFE rods on the Au surface and assembled with the DNA walker, overcoming the complexity of adding metal ions from the external environment. In addition, the orbital chain is modified by a synthetic bisferrocene signal marker, which further enables signal amplification. Under optimal conditions, the sensor exhibits a range from 1×10⁻¹⁴ mol/L to 1×10⁻⁸ mol/L with a detection limit (S/N=3) of 1.28 fM.     

Electrochemical Biosensors for Cancer Biomarker Detection

Cancer is still one of the leading causes of death in the world. There are over 200 types of cancers currently known according to the National Cancer Institute. However, early diagnosis continues to be an important integral part of cancer treatment even though many advances in therapeutics have been made in the past decade. Quick diagnosis and early prevention are critical for the control of the disease status. Biomarkers are commonly indicative of a particular disease process and the cancer biomarkers are also widely used in oncology to help detecting the presence of various carcinomas. The detection of cancer biomarkers plays an important role in clinical diagnoses and evaluation of treatment for patients. Many immunoassay methods are developed for detection of cancer biomarkers. As the detection devices are normally viewed with high sensitivity, simple preparation and rapid response, electrochemical biosensors are increasingly used for the detection of cancer markers. This review describes the status, the latest research and trends of electrochemical sensors in the quantitation of cancer markers in recent years. In particular, the strategy to improve the sensitivities of the electrochemical biosensors by the aid of enzymatic amplification, nanoparticle amplification, ultilization of magnetic microspheres etc. is described herein. At last, we discuss some special features and limitations associated with the described systems that summarize the application and the development prospects of electrochemical immunoassay technology.     

Fabrication of a Sensitive Electrochemical Biosensor for Detection of DNA Hybridization Based on Gold Nanoparticles/CuO Nanospindles Modified Glassy Carbon Electrode

In this work, a sensitive electrochemical DNA biosensor for the detection of sequence‐specific target DNA was reported. Firstly, CuO nanospindles (CuO NS) were immobilized on the surface of a glassy carbon electrode (GCE). Subsequently, gold nanoparticles (Au NPs) were introduced to the surface of CuO NS by the electrochemical deposition mode. Probe DNA with SH (HS‐DNA) at the 5′‐phosphate end was covalently immobilized on the surface of the Au NPs through Au? S bond. Scanning electron microscopy (SEM) was used to elucidate the morphology of the assembled film, and electrochemical impedance spectroscopy technique (EIS) was used to investigate the DNA sensor assembly process. Hybridization detection of DNA was performed with differential pulse voltammetry (DPV) and the methylene blue (MB) was hybridization indicator. Under the optimal conditions, the decline of reduction peak current of MB (ΔI) was linear with the logarithm of the concentration of complementary DNA from 1.0×10^?13 to 1.0×10^?6 mol·L^?1 with a detection limit of 3.5×10^?14 mol·L^?1 (S/N=3). In addition, this DNA biosensor has good selectivity, and even can distinguish single‐mismatched target DNA.     

检测痕量Hg~(2+)的DNA电化学生物传感器

通过自组装方法将修饰有二茂铁基团的富T序列DNA分子(DNA-Fc)固定在金电极表面,得到了一种基于DNA修饰电极的电化学汞离子(Hg2+)传感器.当溶液中有Hg2+存在时,Hg2+可与修饰电极上DNA的T碱基发生较强的特异结合,形成T-Hg2+-T发卡结构,使DNA分子构象发生改变,其末端具有电化学活性的二茂铁基团远离电极表面,电化学响应随之发生变化.示差脉冲伏安法(DPV)结果显示:DNA末端二茂铁基团的还原峰在0.26V(vs饱和甘汞电极(SCE))附近,峰电流随溶液中Hg2+浓度的增加而降低;Hg2+浓度范围在0.1nmol·L-1-1μmol·L-1时,电流相对变化率与Hg2+浓度的对数呈现良好的线性关系.该修饰电极对Hg2+的检测限为0.1nmol·L-1,可作为痕量Hg2+检测的电化学生物传感器.干扰实验也表明,该传感器对Hg2+具有良好的特异性与灵敏度.     

Electrochemical DNA Hybridization Detection Using DNA Cleavage

We report the new method for detection of DNA hybridization using enzymatic cleavage. The strategy is based on that S1 nuclease is able to specifically cleave only single strand DNA, but not double strand DNA. The capture probe DNA, thiolated single strand DNA labeled with electroactive ferrocene group, was immobilized on a gold electrode. After hybridization of target DNA of complementary and noncomplementary sequences, nonhybridized single strand DNA was cleaved using S1 nuclease. The difference of enzymatic cleavage on the modified gold electrode was characterized by cyclic voltammetry and differential pulse voltammetry. We successfully applied this method to the sequence‐selective discrimination between perfectly matched and mismatched target DNA including a single‐base mismatched target DNA. Our method does not require either hybridization indicators or other exogenous signaling molecules which most of the electrochemical hybridization detection systems require.     

Programmable Engineering of a Biosensing Interface with Tetrahedral DNA Nanostructures for Ultrasensitive DNA Detection

Self‐assembled DNA nanostructures with precise sizes allow a programmable “soft lithography” approach to engineer the interface of electrochemical DNA sensors. By using millimeter‐sized gold electrodes modified with several types of tetrahedral DNA nanostructures (TDNs) of different sizes, both the kinetics and thermodynamics of DNA hybridization were profoundly affected. Because each DNA probe is anchored on an individual TDN, its lateral spacing and interactions are finely tuned by the TDN size. By simply varying the size of the TDNs, the hybridization time was decreased and the hybridization efficiency was increased. More significantly, the detection limit for DNA detection was tuned over four orders of magnitude with differentially nanostructured electrodes, and achieved attomolar sensitivity with polymeric enzyme amplification.     

Harnessing Effective Molarity to Design an Electrochemical DNA-based Platform for Clinically Relevant Antibody Detection

Easy-to-use platforms for rapid antibody detection are likely to improve molecular diagnostics and immunotherapy monitoring. However, current technologies require multi-step, time-consuming procedures that limit their applicability in these fields. Herein, we demonstrate effective molarity-driven electrochemical DNA-based detection of target antibodies. We show a highly selective, signal-on DNA-based sensor that takes advantage of antibody-binding-induced increase of local concentration to detect clinically relevant antibodies in blood serum. The sensing platform is modular, rapid, and versatile and allows the detection of both IgG and IgE antibodies. We also demonstrate the possible use of this strategy for the monitoring of therapeutic monoclonal antibodies in body fluids. Our approach highlights the potential of harnessing effective molarity for the design of electrochemical sensing strategies.