用鲁米诺功能化金纳米粒子修饰的金电极电化学发光法测定多巴胺

采用鲁米诺功能化金纳米粒子修饰的金电极制备了新型的电化学发光传感器(ECLS),并对其电化学发光(ECL)性质作了研究。结果表明:该修饰电极具有良好的ECL性能,在含有1.0×10~(-3) mol·L~(-1)过氧化氢的0.02mol·L~(-1)碳酸钠-碳酸氢钠缓冲溶液(pH 10.0)中,其ECL强度值与多巴胺浓度的对数值在1.0×10-10~1.0×10~(-5) mol·L~(-1)范围内呈线性关系,检出限(3σ)为6.3×10~(-11) mol·L~(-1)。据此,应用该传感器测定了尿样中的多巴胺含量,并对方法的回收率作了试验,测得平均回收率为103%。     

基于电化学阻抗谱的致病菌检测传感器的研究进展（英文）

几千年来,致病菌对人类健康构成了巨大威胁。实现致病菌的实时监测可有效阻止致病菌的传播,从而降低对人类健康的威胁。迄今为止,已有电化学、光学、压电和量热等多种技术用于细菌的检测。其中,基于电化学阻抗技术的传感器由于其成本低、读取时间短、重现性好、设备便携等优点,在实时细菌检测中展现出了巨大的应用潜力。本文主要综述了近三年来电化学阻抗技术在细菌传感中的典型应用。众所周知,电极材料在基于电化学阻抗的传感器的构建中发挥着极其重要的作用,因为细菌生物识别元件的固定化,以及所制备的传感器的灵敏度、经济性和便携性都主要取决于电极材料。因此,为了向新入行的研究人员提供基于不同电极材料制备电化学阻抗传感器清晰的制备过程,我们尝试根据不同的电极平台对基于电化学阻抗技术的传感器进行分类。此外,还讨论了目前的难点、未来的应用方向和前景。我们希望通过本文的综述,能够为刚进入该领域的研究人员开展基于电化学阻抗技术,制备快速、灵敏、准确地检测多种致病菌的传感器研究提供指导。     

电化学酶传感器在环境污染监测中的应用

电化学酶传感器是一种应用广泛的生物传感器,它将酶及其底物相互作用的特异性与电化学的强大分析功能相结合,已经被广泛应用于药理学、临床、食品、农业以及环境监测中。制备电化学酶传感器的关键步骤是酶的固定化,选择用于制备电化学酶传感器的合适的酶固定化方法,在传感器电子转移动力学、稳定性和重现性等方面起着主要作用。本文在阐述电化学酶传感器工作原理的基础上,简要介绍了用于电化学酶传感器制备过程中的酶固定化方法,重点讨论了电化学酶传感器在监测环境中广泛存在的有机污染物、无机污染物和重金属等方面的应用,并对电化学酶传感器的发展方向进行了展望。     

微机械加工的微结构型电化学传感器

微结构型电化学传感器是应用发展中的微机械加工技术结合传统的电化学传感技术创立的新一代的电化学传感器，而微机械加工技术与多种高新技术学科的相互交叉，又将拓宽微结构型电化学传感器研究的新领域。本文在简要介绍微机械加工技术的基础，对前类微结构型电化学传感器作了归纳，其中也提及作者年来来的研究工作，并对后者作一展望性评述。     

电化学联用表面等离子体共振光谱法对苯胺电化学聚合过程的研究

采用双光电池传感器作为检测器件,设计并构建了新型表面等离子体共振( SPR)光谱仪,在一定范围内实现了SPR角度的快速测量。将此SPR光谱仪与电化学工作站联用,构建了电化学联用-时间分辨SPR ( EC-TR-SPR)光谱仪,以聚苯胺电化学制备过程为研究体系,验证了此EC-TR-SPR光谱仪的特性。同时通过对聚苯胺膜的暂态电化学方法测试(计时电流法和差分脉冲法),考察了仪器的时间分辨能力及其响应速度,验证了此仪器系统在小分子反应动力学以及稳态和暂态电化学联用方法研究中的应用价值。实验结果表明,此SPR光谱仪具有高的时间分辨能力,其时间分辨率可达0.1 ms;对聚苯胺膜的暂态电化学测试结果表明,此联用技术可实时监测SO2-4在聚苯胺膜中的掺杂和去掺杂过程,而单纯的电化学电流-时间曲线无法区分。     

MOF构筑的电化学传感器及应用

金属-有机框架化合物(以下简称金属-有机框架)是一类有机配体与金属中心通过自组装形成的具有三维框架结构的多孔材料,其特异复杂的结构使其具有良好的化学性能。金属-有机框架化合物在分析化学方面的应用受到广泛关注,在电化学传感器应用方面也取得了显著进展。本文简要介绍近年来金属-有机框架用于构建电化学传感器的方法及在电化学传感器中的作用;对基于金属-有机框架的电化学传感器的应用进行了综述;分析了目前金属-有机框架-电化学传感器研究中存在的问题和局限性并对其应用进行了展望。     

磁性石墨烯修饰辛基酚印迹传感器制备及应用研究

以辛基酚(4-OP)为模板分子,多巴胺为功能单体,采用电聚合技术在磁性石墨烯修饰碳电极表面制备对辛基酚具有高选择性与灵敏性的印迹电化学传感器。采用循环伏安法(CV)和差分脉冲伏安法(DPV)对此印迹传感器的电化学性能进行详细表征;采用扫描电子显微技术对修饰电极的形貌进行表征。结果表明,此印迹电化学传感器对辛基酚具有良好的特异识别性能。采用 DPV 法考察了孵化时间和洗脱溶剂对印迹传感器性能影响,结果表明,最佳孵化时间为14 min。此印迹电化学传感器的响应电流(△IR )与辛基酚在5.0×10-6~5.0×10-9 mol/ L 范围内浓度的负对数(-lgC)呈良好的线性关系,线性方程为△IR ( mA)=-0.25lgC(mol/ L)+2.35,检出限为3.64×10-10 mol/ L (S/ N=3)。此印迹电化学传感器对辛基酚具有良好的选择性和灵敏性,成功用于实际水样中辛基酚的检测,回收率为96.0%~104.0%。     

基于石墨烯修饰碳电极的铜离子印迹电化学传感器的制备与应用

以铜离子为模板,多巴胺为功能单体,采用电聚合法在石墨烯修饰碳电极表面成功制备对铜离子有高选择性和灵敏性的印迹电化学传感器。采用差分脉冲伏安法和循环伏安法对该印迹传感器的电化学行为进行详细研究。在优化检测条件下,该印迹电化学传感器的响应电流与铜离子浓度的负对数在5.0×10~(-6)~5.0×10~(-11)mol/L浓度范围内呈良好的线性关系,最低检测限为1.0×10~(-11)mol/L。该印迹电化学传感器成功用于实际水样中的微量铜离子分析。     

石墨烯修饰电化学适配体传感器测定双酚A

构建了一种检测双酚A(BPA)的电化学适配体传感器。利用在线电化学方法将氧化石墨烯还原为石墨烯,通过石墨烯与单链DNA之间的相互作用,将BPA适配体单链DNA吸附固定在修饰电极上,制备了BPA电化学适配体传感器。以铁氰化钾-亚铁氰化钾平衡电对为电化学探针,利用电化学循环伏安法和差分脉冲伏安法对BPA传感器的性能进行了研究。结果表明,在最优化实验条件下,传感器对BPA的检测线性范围在1.0×10~(-15)~1.0×10~(-10)mol/L之间,检出限为3.3×10~(-16)mol/L(S/N=3)。     

水热法合成过渡金属氧化物纳米材料及其在食品安全检测传感器中的应用进展

以Fe,Co,Mn,Zn等过渡金属制备的氧化物纳米材料具有制备简单、形貌可控以及电化学活性高等特点,且可以固定在电极表面,在电化学传感器的应用中显示了广阔前景。该文重点介绍了过渡金属氧化物水热合成方法的研究进展,并简要阐述了基于过渡金属氧化物纳米材料的新型电化学传感器在食品安全快速检测领域的应用进展。     

Molecularly Imprinted Polymers Combined with Electrochemical Sensors for Food Contaminants Analysis

Detection of relevant contaminants using screening approaches is a key issue to ensure food safety and respect for the regulatory limits established. Electrochemical sensors present several advantages such as rapidity; ease of use; possibility of on-site analysis and low cost. The lack of selectivity for electrochemical sensors working in complex samples as food may be overcome by coupling them with molecularly imprinted polymers (MIPs). MIPs are synthetic materials that mimic biological receptors and are produced by the polymerization of functional monomers in presence of a target analyte. This paper critically reviews and discusses the recent progress in MIP-based electrochemical sensors for food safety. A brief introduction on MIPs and electrochemical sensors is given; followed by a discussion of the recent achievements for various MIPs-based electrochemical sensors for food contaminants analysis. Both electropolymerization and chemical synthesis of MIP-based electrochemical sensing are discussed as well as the relevant applications of MIPs used in sample preparation and then coupled to electrochemical analysis. Future perspectives and challenges have been eventually given.     

普鲁士蓝在化学传感器中的研究及应用

综述了普鲁士蓝化学传感器的研究和应用进展。介绍了传感器敏感膜的制备方法，在电化学传感器和光学传感器中的应用及机理研究方面的成果。普鲁士蓝优越的氧化还原性质使普鲁士蓝化学传感器对于许多物质的检测有着重要的意义。     

微纳电化学传感界面的构建及其用于单细胞实时监测

细胞是生物体形态结构和生命活动的基本单位.常规检测群体细胞的方法往往会掩盖细胞间的个体差异,因此亟需发展高效的单细胞分析策略,深入研究细胞生命活动过程,揭示疾病发生发展机制,推动个体化诊疗.超微电化学传感器具有尺寸小、灵敏度高、时空分辨率高等特点,在单细胞实时动态监测方面发挥了非常重要的作用.目前,微纳电化学传感器在电...     

溶胶凝胶技术在化学及生物传感器领域中的应用

本文介绍了一种新的用于化学或生物传感器固定敏感试剂的溶胶凝胶技术,用此技术制成的传感器基质具有优异的光学特性和热力学,机械稳定性,且它形成的化学条件温和,尤其适用于包埋生物大分子。     

Chemically modified electrodes with amperometric response in enantioselective analysis

Estimation of the enantiomeric purity of chiral biologically active compounds, as well as the determination of particular optical isomers, is very important for the control of medicines, food, and biological fluids. The main approaches to the development of electrochemical enantioselective sensors with the amperometric detection of the signal are considered in this review. Examples of the use of biochemical and supramolecular receptors providing enantiomer recognition and techniques of their inclusion into the corresponding sensors are given. The main characteristics of enantioselective sensors for the determination of optically active medicines, organic acids, aminoacids, carbohydrates, alcohols, and other biologically important compounds are considered.     

Scanning probe microscopies for high-resolution characterization of electrochemical sensors. Plenary lecture.

A better understanding of tailored electrodes and electrochemical sensors requires a more detailed picture of their surfaces. New scanning probe techniques, such as scanning tunnelling or scanning bioelectrochemical microscopies, offer unique opportunities for high-resolution in situ characterization of tailored electrodebased sensors. Scanning tunnelling microscopy provides valuable information on the topography of pre-treated surfaces, the heterogeneity of composite electrodes, the morphology of electropolymerized films, the packing arrangement of adsorbed monolayers and the microdistribution of immobilized biological components. Scanning bioelectrochemical microscopy is shown to be extremely useful for the mapping of localized biological activity and the monitoring of dynamic biological events. Valuable insights are achieved by correlating the structural features with the preparation/modification conditions and the subsequent sensing performance. Such correlations can facilitate the predictive design of increasingly better sensors.     

Molecularly Imprinted Electrochemical Sensors

In this review, the applications of molecularly imprinted polymer (MIP) materials in the area of electrochemical sensors have been explored. The designs of the MIPs containing different polymers, their preparation and their immobilization on the transducer surface have been discussed. Further, the employment of various transducers containing the MIPs based on different electrochemical techniques for determining analytes has been assessed. In addition, the general protocols for getting the electrochemical signal based on the binding ability of analyte with the MIPs have been given. The review ends with describing scope and limitations of the above electrochemical based MIP sensors.     

Stretchable Electrochemical Sensor for Real‐Time Monitoring of Cells and Tissues

Stretchable electrochemical sensors are conceivably a powerful technique that provides important chemical information to unravel elastic and curvilinear living body. However, no breakthrough was made in stretchable electrochemical device for biological detection. Herein, we synthesized Au nanotubes (NTs) with large aspect ratio to construct an effective stretchable electrochemical sensor. Interlacing network of Au NTs endows the sensor with desirable stability against mechanical deformation, and Au nanostructure provides excellent electrochemical performance and biocompatibility. This allows for the first time, real‐time electrochemical monitoring of mechanically sensitive cells on the sensor both in their stretching‐free and stretching states as well as sensing of the inner lining of blood vessels. The results demonstrate the great potential of this sensor in electrochemical detection of living body, opening a new window for stretchable electrochemical sensor in biological exploration.     

The double life of conductive nanopipette: a nanopore and an electrochemical nanosensor

The continuing interest in nanoscale research has spurred the development of nanosensors for liquid phase measurements. These include nanopore-based sensors typically employed for detecting nanoscale objects, such as nanoparticles, vesicles and biomolecules, and electrochemical nanosensors suitable for identification and quantitative analysis of redox active molecules. In this Perspective, we discuss conductive nanopipettes (CNP) that can combine the advantages of single entity sensitivity of nanopore detection with high selectivity and capacity for quantitative analysis offered by electrochemical sensors. Additionally, the small physical size and needle-like shape of a CNP enables its use as a tip in the scanning electrochemical microscope (SECM), thus, facilitating precise positioning and localized measurements in biological systems.

Conductive nanopipettes: a useful tool for localized detection and analysis of single nanoscale objects.     

Sensing mechanism of non-equilibrium solid-electrolyte-based chemical sensors

Solid electrolytes can be used in several different types of chemical sensors. A common approach is to use the equilibrium potential generated across a solid electrolyte given by the Nernst equation as the sensing signal. However, in some cases, stable electrode materials are not available to establish equilibrium potentials, so non-equilibrium approaches are necessary. The sensing signal generated by such sensors is often described by the mixed potential theory, in which a pair of electrochemical reactions establishes a steady state at the electrode, such that the electrons produced by an oxidation reaction are consumed by a reduction reaction. The rates of both reactions depend on several factors, such as electron exchange, active area, and gas phase diffusion, so establishment of the steady-state potential is complex and alternative explanations have been proposed. This paper will review and discuss the mechanisms proposed to explain the sensor response of non-equilibrium-based electrochemical sensors.