基于核酸适体的电化学生物传感器*

核酸适体是一类体外筛选的、可与目标分子高效、高特异亲合的RNA或DNA寡核苷酸片段,与常规识别分子（如抗体等）相比,核酸适体作为一类新型识别分子具有明显特色和优势,已被广泛应用于生物传感等分子识别和应用研究领域。本文就基于核酸适体的电化学生物传感器（标记型和非标记型）的近期进展作简要评述,包括适体简介、标记型（“信号衰减”型、“信号增强”型、酶标记型和纳米粒子标记型）和非标记型电化学适体生物传感器等内容。     

Electrochemical Biosensors Based on Layer‐by‐Layer Assemblies

Layer‐by‐layer (LBL) assemblies, which have undergone great progress in the past decades, have been used widely in the construction of electrochemical biosensors. The LBL assemblies provide a strategy to rationally design the properties of immobilized films and enhance the performance of biosensors. The following review focuses on the application of LBL assembly technique on electrochemical enzyme biosensors, immunosensors and DNA sensors.     

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。     

Electrochemical Biosensors Based on Enzyme Inhibition Effect

Several electrochemical biosensors based on various enzyme inhibition effects have been designed; their laboratory prototypes have been manufactured and thoroughly investigated. It should be noted that such biosensors are adapted to large-scale production technologies. A number of advantages and disadvantages of developed biosensors based on enzyme inhibition has been discussed. It is important that all developed biosensors are not opposite to traditional analytical methods, but complement them. This is an additional system of quick and early warning about the presence of toxic substances in the environment. Such systems can save time and money in emergencies due to the possibility of quick decision-making on local environmental problems. If necessary, more accurate, but time-consuming and expensive traditional methods could be used for further validation and additional research of samples previously tested by biosensors.     

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.     

石墨烯纳米复合材料在电化学生物传感器中的应用

将石墨烯与其他纳米材料复合,是一种拓展或增强其应用的有效方法。借助不同组分间的协同作用,可以改善石墨烯的电学、化学和电化学性质,拓展和增强石墨烯的电化学效应,为固定氧化还原酶,实现直接电化学提供新型、高效的平台,应用于第三代电化学生物传感器的设计和制备,对葡萄糖、胆固醇、血红蛋白、DNA、H₂O₂、O₂、小生物分子等的检测显示出了优异的灵敏度和选择性。本文综述了基于石墨烯构筑的纳米复合材料在电化学生物传感器中的应用研究,包括石墨烯与贵金属、金属氧化物/半导体纳米粒子、高分子、染料分子、离子液体、生物分子等的纳米复合材料,并对石墨烯材料在电化学领域的发展方向和应用前景进行了展望。     

基于纳米材料电化学生物传感器的研究进展

近年来,纳米材料在电化学生物传感器领域的研究已成为前沿性的内容.纳米材料具备优异的物理、化学、电催化等性能,加之其量子尺寸效应和表面效应,可将传感器的性能提高到一个新的水平.基于纳米材料的电化学生物传感器呈现出体积更小、速度更快、检测灵敏度更高和可靠性更好等优异性能.该文按照纳米结构的分类,综述了近几年基于以下纳米材料...     

葡萄糖生物传感器检测方法的研究进展

葡萄糖生物传感器以其灵敏度高、选择性好、反应速度快以及稳定性好等优点吸引了许多研究者的关注。 本文将已发表的一些葡萄糖检测方法分为两类：葡萄糖酶生物传感器检测方法与无酶葡萄糖生物传感器检测方法,简要介绍了这2种检测方法的一些研究进展,并对葡萄糖检测方法的发展前景进行了展望。     

Recent Progress in the Development of Conducting Polymer‐Based Nanocomposites for Electrochemical Biosensors Applications: A Mini‐Review

Among various immobilizing materials, conductive polymer‐based nanocomposites have been widely applied to fabricate the biosensors, because of their outstanding properties such as excellent electrocatalytic activity, high conductivity, and strong adsorptive ability compared to conventional conductive polymers. Electrochemical biosensors have played a significant role in delivering the diagnostic information and therapy monitoring in a rapid, simple, and low cost portable device. This paper reviews the recent developments in conductive polymer‐based nanocomposites and their applications in electrochemical biosensors. The article starts with a general and concise comparison between the properties of conducting polymers and conducting polymer nanocomposites. Next, the current applications of conductive polymer‐based nanocomposites of some important conducting polymers such as PANI, PPy, and PEDOT in enzymatic and nonenzymatic electrochemical biosensors are overviewed. This review article covers an 8‐year period beginning in 2010.     

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.     

A Mix‐and‐Read Fluorescence Strategy for the Switch‐On Probing of Kinase Activity Based on an Aptameric‐Peptide/Graphene‐Oxide Platform

Protein kinase plays a vital role in regulating signal‐transduction pathways and its simple and quick detection is highly desirable because traditional kinase assays typically rely on a time‐consuming kinase‐phosphorylation process (ca. 1 h). Herein, we report a new and rapid fluorescence‐based sensing platform for probing the activity of protein kinase that is based on the super‐quenching capacity of graphene oxide (GO) nanosheets and specific recognition of the aptameric peptide (FITC‐IP₂₀). On the GO/peptide platform, the fluorescence quenching of FITC‐IP₂₀ that is adsorbed onto GO can be restored by selective binding of active protein kinase to the aptameric peptide, thereby resulting in the fast switch‐on detection of kinase activity (ca. 15 min). The feasibility of this method has been demonstrated by the sensitive measurement of the activity of cAMP‐dependent protein kinase (PKA), with a detection limit of 0.053 mU μL^?1. This assay technique was also successfully applied to the detection of kinase activation in cell lysate.     

Facile Fabrication of a Graphene‐based Electrochemical Biosensor for Glucose Detection

A simple and effective glucose biosensor based on immobilization of glucose oxidase (GOD) in graphene (GR)/Nafion film was constructed. The results indicated that the immobilized GOD can maintain its native structure and bioactivity, and the GR/Nafion film provides a favorable microenvironment for GOD immobilization and promotes the direct electron transfer between the electrode substrate and the redox center of GOD. The electrode reaction of the immobilized GOD shows a reversible and surface‐controlled process with the large electron transfer rate constant (k_s) of 3.42±0.08 s^?1. Based on the oxygen consumption during the oxidation process of glucose catalyzed by the immobilized GOD, the as‐prepared GOD/GR/Nafion/GCE electrode exhibits a linear range from 0.5 to 14 mmol·L^?1 with a detection limit of 0.03 mmol·L^?1. Moreover, it displays a good reproducibility and long‐term stability.     

Recent advances on the development of graphene-based field-effect transistors,electrochemical biosensors and electrochemiluminescence biosensors

Graphene, a honeycomb lattice of carbon material with single-atom-layer structure, demonstrates extraordinary mechanical, thermal, chemical and electronic properties. Thus, it has sparked tremendous interests in various fields, such as energy storage and conversion devices, field-effect transistors (FET), chemical sensors and biosensors. In this review, we will first focus on the synthesis method of graphene and the fabrication strategy of graphene-based materials. Subsequently, the construction of graphene-based biosensors are introduced, in which three kinds of biosensors are discussed in details, including the FET, electrochemical biosensors and electrochemiluminescence (ECL) biosensors. The performances of the state-of-the-art biosensors on the detection of biomolecules are also displayed. Finally, we also highlight some critical challenges remain to be solved and the development in this field for further research.     

Theoretical Assessment of Binding and Mass‐Transport Effects in Electrochemical Affinity Biosensors That Utilize Nanoparticle Labels for Signal Amplification

This paper presents a theoretical study of electrochemical affinity biosensors for the detection of DNA/protein that utilize nanoparticle labels for signal amplification. This study analyzes the effects of binding and mass transport of the analytes on biosensor performance by using numerical simulations. Four cases were considered: 1) nanoparticles used to increase the loading of an electroactive species, or used as catalysts under pseudo‐first‐order conditions; 2) nanoparticles used as ultramicroelectrode arrays for the electrolysis of large concentrations of substrate; 3) nanoparticles used as seeds to deposit electrochemically detectable species; and 4) nanoparticles used to mediate the deposition of electrocatalysts. By using nanoparticle labels, high sensitivity is possible under all conditions considered. However, theoretical findings suggested that nonspecific adsorption could be more problematic in cases 2–4 due to the mismatch between the chemistry of surface binding and the principle of signal amplification that originates from the effect of mass transport. Under these conditions, any given signal would plateau at a much lower analyte concentration, well before the analyte binding had actually reached a plateau. Views on possible solutions to the above limitations are also presented.     

纳米材料电化学与生物传感器——有机微污染物检测新途径

本文介绍了近年来纳米材料电化学与生物传感器在有机微污染物检测中的研究现状,分析了这些传感器中纳米材料修饰电极的特点,重点阐述了纳米材料在有机微污染物检测中的重要作用,列举了一些纳米材料电化学与生物传感器在有机微污染物检测中的应用。最后对纳米材料电化学与生物传感器用于有机微污染物的检测研究进行了简要评述和展望。     

电化学葡萄糖传感器

作为电化学生物传感器中最重要的研究内容之一,葡萄糖生物传感器在数十年的发展中取得了巨大进展。本文综述了近年来利用纳米技术设计的新型电化学葡萄糖传感器的主要研究进展,并从纳米材料维度分类进行了讨论。其中,零维纳米材料主要讨论了包括金纳米颗粒、银纳米颗粒以及铜、铂等金属纳米颗粒材料; 一维纳米材料主要讨论了通过模板法制备的金属或金属氧化物纳米线以及单臂或者多壁纳米管材料; 二维纳米材料主要总结了以碳为基础的石墨烯材料和一些片状的金属材料。纳米材料对电化学葡萄糖传感器的影响主要集中在生物相容性、增强检测灵敏度、酶的固定等方面。此外,本文也对电化学葡萄糖传感器的今后发展做了展望。     

量子点在电化学生物传感研究中的应用

量子点( Quantum dots,QDs )由于具有独特的光学、电化学和电致化学发光特性已受到广泛地重视,而利用量子点构建电化学生物传感器则是量子点最有前途的应用领域之一。量子点具有的高比表面积、高表面活性及小尺寸等特性使它对外界的光、电、温度等十分地敏感,外界环境的微小改变就会迅速引起其表面或界面粒子价态和电子转移行为的显著变化,基于生物大分子引起的QDs表面电化学行为变化而构建的电化学生物传感器,其特点是响应灵敏高、速度快且选择性优良。本文对量子点的光学、电化学和电致化学发光特性作了简单介绍,并重点回顾了其在电致化学发光、免疫分析、DNA杂交、蛋白质检测、农药检测和糖类检测电化学生物传感研究中的应用。同时,对量子点在电化学生物传感研究中的应用前景及研究方向进行了评述和展望。     

Developing Graphene‐Based Nanohybrids for Electrochemical Sensing

Graphene‐based nanohybrid is considered to be the most promising nanomaterial for electrochemical sensing applications due to the defects created on the graphene oxide layers. These defects provide graphene oxide unique properties, such as excellent conductivity, large specific surface area, and electrocatalytic activity. These unique properties encourage scientists to develop novel graphene‐based nanohybrids and improve the sensing efficiency. This review, therefore, addresses this topic by comprehensively discussing the strategies to fabricate novel graphene based nanohybrids with high sensitivity. The combinations of graphene with various nanomaterials, such as metal nanoclusters, metal compound nanoparticles, carbon materials, polymers and peptides, in the direction of electrochemical sensing, were systematically analyzed. Meanwhile, the challenges in the functional design and application of graphene‐based nanohybrids were described and the reasonable solutions were proposed.     

Electrochemical Immunosensor for α‐Fetoprotein Based on Gold Nanoparticles/Graphene‐Prussian Blue

The electrochemical immunosensor for α‐fetoprotein (AFP) was fabricated based on the platform of gold nanoparticles (GNP)/graphene (Gr)‐prussian blue (PB). By electrodeposition, GNP were modified on the surface of the prepared Gr‐PB. The anti‐AFP‐1,1′‐ferrocenedicarboxylic acid (FcDA) as label was directly immobilized on the platform of GNP/Gr‐PB. And after the immunoreactions, the formed complex inhibited the electron transfer and decreased the catalytic current of FcDA toward the reduction of H₂O₂. And in the range of 10–3200 pg·mL^?1, the decreased current is linear with the concentration of AFP, with a detection limit of 3 pg·mL^?1. The developed immunoassay method showed good precision, high sensitivity, acceptable stability and reproducibility, and could be used for the detection of real samples with consistent results in comparison with those obtained by the enzyme linked immunosorbent assay (ELISA) method.