共查询到20条相似文献,搜索用时 46 毫秒
1.
2.
Recent advancement in nanoscience and nanotechnologies inspired a wide spectrum of uses of nanodimensional materials ranging from industrial sector to biomedical applications. Inorganic nanomaterials made of noble metals, which are corrosion-resistant, are often included as electrode modifiers in designing electrochemical chemosensors and biosensors because of their unique catalytic, electric, and surface-related properties. This review summarizes the developments in electrochemical biosensors with integrated in their architecture metal nanostructures reported mainly during the last two years with a summary on some of the commonly used methods for the synthesis of metallic nanostructures. Nanodimensional noble metal structures might be considered as multipurpose electrode modifiers because of their abilities to act at the same time as electrocatalysts, signal amplifiers, and tools for immobilization and spatial orientation of redox proteins/enzymes or other type of bioreceptors. 相似文献
3.
Electrocatalytic Properties of a Gold Nanoseed Particle‐modified Indium Tin Oxide Electrode: Comparison of the Shape and Preparation Methods
下载免费PDF全文
![点击此处可从《Electroanalysis》网站下载免费的PDF全文](/ch/ext_images/free.gif)
Md. Abdul Aziz Manzar Sohail M. Nasiruzzaman Shaikh Munetaka Oyama 《Electroanalysis》2016,28(5):1119-1125
Gold nanostructures are the most commonly used nanostructures for fabricating electrochemical sensors and biosensors. In this study, we compared the catalytic performances of three types of gold nanoseed particles having two different morphologies, upon attachment to an amino‐functionalized ITO electrode surface. The ITO electrode surface was modified with 3‐aminopropyltrimethoxysilane (APTMS) and (1) gold nanoseed spheres (AuNSS), prepared using the ion capture and successive reduction method (ICR), (2) commercially available 5 nm AuNSS, and (3) a newly synthesized gold nanoseed wire (AuNSW). The electrocatalytic properties of the three electrodes were evaluated. Among the three electrodes, the AuNSW/APTMS/ITO was found to be the electrode of choice and exhibited excellent electrocatalytic properties toward the biologically important analytes glucose, uric acid, and serotonin. 相似文献
4.
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. 相似文献
5.
电化学生物传感器具有灵敏度高、便携性好、响应快速和易于集成等优点,在临床检测方面有很大应用潜力,并在可穿戴健康监测领域得到了快速发展。但在实际临床生物样本检测中,非靶标生物物质会在电极表面产生非特异性吸附(即生物污染),影响了电化学生物传感器的性能。因此,构建具有防污染能力的传感界面(抗污界面),防止非靶标物质吸附到电极表面,对于扩大电化学生物传感器的实际应用范围,实现在复杂生物样本中的检测至关重要。本文概述了物理、化学和生物抗污电极界面的构建及其在临床相关生物标志物检测中的应用,为电化学生物传感器实际应用性能的提升提供技术参考,并通过对界面抗污原理和存在问题的探讨,对抗污界面发展前景和未来趋势予以展望。 相似文献
6.
生物体内的细胞通常会分泌各种各样的蛋白质,这些蛋白质在生物体中发挥着重要作用,尤其是可被用于诊断各种疾病的发生和发展。多肽具有良好选择性、空间适应能力和识别灵活的特点,可与不同类型的蛋白分子形成非共价键,用于蛋白质的生物检测。将多肽与电化学生物传感器结合用于蛋白质的广谱检测具有良好的发展前景。本文介绍了多肽修饰的电化学传感器在不同蛋白质检测方面的研究进展,分析了待测蛋白质的不同对多肽修饰的电化学传感器分类的影响及其优缺点,提出了基于多肽的电化学传感器在不同蛋白质检测中存在的问题,并展望了其未来发展。 相似文献
7.
Electroanalysis has obtained considerable progress over the past few years, especially in the field of electrochemical sensors. Broadly speaking, electrochemical sensors include not only conventional electrochemical biosensors or non-biosensors, but also emerging electrochemiluminescence (ECL) sensors and photoelectrochemical (PEC) sensors which are both combined with optical methods. In addition, various electrochemical sensing devices have been developed for practical purposes, such as multiplexed simultaneous detection of disease-related biomarkers and non-invasive body fluid monitoring. For the further performance improvement of electrochemical sensors, material is crucial. Recent years, a kind of two-dimensional (2D) nanomaterial MXene containing transition metal carbides, nitrides and carbonitrides, with unique structural, mechanical, electronic, optical, and thermal properties, have attracted a lot of attention form analytical chemists, and widely applied in electrochemical sensors. Here, we reviewed electrochemical sensors based on MXene from Nov. 2014 (when the first work about electrochemical sensor based on MXene published) to Mar. 2021, dividing them into different types as electrochemical biosensors, electrochemical non-biosensors, electrochemiluminescence sensors, photoelectrochemical sensors and flexible sensors. We believe this review will be of help to those who want to design or develop electrochemical sensors based on MXene, hoping new inspirations could be sparked. 相似文献
8.
The objective of this study is to analyze the technical importance, performance, techniques, advantages, and disadvantages of the biosensors in general and of the electrochemical biosensors in particular. A product of reaction diffuses to the transducer in the first generation biosensors (based on Clark biosensors). The mediated biosensors or second generation biosensors use specific mediators between the reaction and the transducer to improve sensitivity. The second generation biosensors involve two steps: first, there is a redox reaction between enzyme and substrate that is reoxidized by the mediator, and eventually the mediator is oxidized by the electrode. No normal product or mediator diffusion is directly involved in the third generation biosensors, direct biosensors. Based on the type of transducer, current biosensors are divided into optical, mass, thermal, and electrochemical sensors. They are used in medical diagnostics, food quality controls, environmental monitoring, and other applications. These biosensors are also grouped under two broad categories of sensors: direct and indirect detection systems. Moreover, these systems could be further grouped into continuous or batch operation. Therefore, amperometric biosensors and their current applications are focused on more in detail since they are the most commonly used biosensors in monitoring and diagnosing tests in clinical analysis. Problems related to the commercialization of medical, environmental, and industrial biosensors as well as their performance characteristics, their competitiveness in comparison to the conventional analytical tools, and their costs determine the future development of these biosensors. 相似文献
9.
《Electroanalysis》2017,29(9):2106-2113
In this article, electrochemical properties of CuO nanostructures based dopamine (DA) sensor was investigated. The morphology, structure, optical, and compositional properties of the CuO nanostructures were characterized by using SEM, XRD, UV‐Vis, and XPS techniques. The electrochemical properties were investigated using cyclic voltammetry (CV) and electrochemical impedance spectroscopy (EIS) techniques. The CV results indicate that biosensors based on CuO nanostructures exhibit a high selectivity and sensitivity of 0.1975 μA μM–1 toward DA and effectively avoids the interference of ascorbic acid (AA) and uric acid (UA). The obtained EIS spectra for CuO sensors were analysed using an electrical equivalent circuit to understand the bulk and surface response via the capacitive and resistive parameters. The EIS measurement also leads to the direct determination of parameters like series resistance and ion diffusion phenomena at electrode‐electrolyte interface. The experimental CV and EIS results along with their analysis will have a significant impact on understanding the mechanism of high sensitivity and selectivity performance of CuO based sensors. This study may also lay the basis for efficient characterization of biosensors by coupling both the CV and EIS characterization techniques. 相似文献
10.
11.
Rivas GA Rubianes MD Rodríguez MC Ferreyra NF Luque GL Pedano ML Miscoria SA Parrado C 《Talanta》2007,74(3):291-307
The aim of this review is to summarize the most relevant contributions in the development of electrochemical (bio)sensors based on carbon nanotubes in the last years.Since the first application of carbon nanotubes in the preparation of an electrochemical sensor, an increasing number of publications involving carbon nanotubes-based sensors have been reported, demonstrating that the particular structure of carbon nanotubes and their unique properties make them a very attractive material for the design of electrochemical biosensors.The advantages of carbon nanotubes to promote different electron transfer reactions, in special those related to biomolecules; the different strategies for constructing carbon nanotubes-based electrochemical sensors, their analytical performance and future prospects are discussed in this article. 相似文献
12.
Ricardo J.B. Leote Mihaela Beregoi Ionut Enculescu Victor C. Diculescu 《Current Opinion in Electrochemistry》2022
Electrospun polymeric fibers present an emerging alternative for the development of flexible electronics, enabling applications in wearable sensors and biosensors for continuous monitoring, and actuators for tissue engineering. The possibility to prepare sub-micrometric polymeric scaffolds, their processing for increasing the conductivity, their modification with different materials, conductive polymers and biomolecules in order to obtain functional flexible electrodes, allows the development of innovative devices for healthcare, and biomedical applications. In this review, the impact of metallized electrospun polymeric fibers in electrochemical (bio)sensors and actuators is discussed. A relation between their structure and functionality is provided, alongside with an overview of the different methods to obtain functional conductive fibers. 相似文献
13.
14.
Mir M Martínez-Rodríguez S Castillo-Fernández O Homs-Corbera A Samitier J 《Electrophoresis》2011,32(8):811-821
Electrokinetic techniques are contact-free methods currently used in many applications, where precise handling of biological entities, such as cells, bacteria or nucleic acids, is needed. These techniques are based on the effect of electric fields on molecules suspended in a fluid, and the corresponding induced motion, which can be tuned according to some known physical laws and observed behaviours. Increasing interest on the application of such strategies in order to improve the detection of DNA strands has appeared during the recent decades. Classical electrode-based DNA electrochemical biosensors with combined electrokinetic techniques present the advantage of being able to improve the working electrode's bioactive part during their fabrication and also the hybridization yield during the sensor detection phase. This can be achieved by selectively manipulating, driving and directing the molecules towards the electrodes increasing the speed and yield of the floating DNA strands attached to them. On the other hand, this technique can be also used in order to make biosensors reusable, or reconfigurable, by simply inverting its working principle and pulling DNA strands away from the electrodes. Finally, the combination of these techniques with nanostructures, such as nanopores or nanochannels, has recently boosted the appearance of new types of electrochemical sensors that exploit the time-varying position of DNA strands in order to continuously scan these molecules and to detect their properties. This review gives an insight into the main forces involved in DNA electrokinetics and discusses the state of the art and uses of these techniques in recent years. 相似文献
15.
《Electroanalysis》2018,30(9):1888-1896
Graphene is one of the most studied materials ever, owing to its exceptional electronic, mechanical and thermal properties, which allow for many different types of application. In this review, we shall concentrate on the use of graphene and derivatives for electrochemical sensors and biosensors, where emphasis is placed on the importance of surface functionalization as this permits synergistic combinations with other nanomaterials and biomolecules. In addition to describing recent advances in graphene‐based electroanalytical applications, we discuss a few examples of their use in detecting small biomolecules and in immunosensing for a few diseases using films and composites. Also discussed are the possible methods for mass production of graphene, which is key to low‐cost biosensors for implantable devices and portable systems in point‐of‐care diagnosis. 相似文献
16.
17.
Dahlin AB Dielacher B Rajendran P Sugihara K Sannomiya T Zenobi-Wong M Vörös J 《Analytical and bioanalytical chemistry》2012,402(5):1773-1784
The enormous progress of nanotechnology during the last decade has made it possible to fabricate a great variety of nanostructures.
On the nanoscale, metals exhibit special electrical and optical properties, which can be utilized for novel applications.
In particular, plasmonic sensors including both the established technique of surface plasmon resonance and more recent nanoplasmonic
sensors, have recently attracted much attention. However, some of the simplest and most successful sensors, such as the glucose
biosensor, are based on electrical readout. In this review we describe the implementation of electrochemistry with plasmonic
nanostructures for combined electrical and optical signal transduction. We highlight results from different types of metallic
nanostructures such as nanoparticles, nanowires, nanoholes or simply films of nanoscale thickness. We briefly give an overview
of their optical properties and discuss implementation of electrochemical methods. In particular, we review studies on how
electrochemical potentials influence the plasmon resonances in different nanostructures, as this type of fundamental understanding
is necessary for successful combination of the methods. Although several combined platforms exist, many are not yet in use
as sensors partly because of the complicated effects from electrochemical potentials on plasmon resonances. Yet, there are
clearly promising aspects of these sensor combinations and we conclude this review by discussing the advantages of synchronized
electrical and optical readout, illustrating the versatility of these technologies. 相似文献
18.
《Electroanalysis》2006,18(4):319-326
The unique chemical and physical properties of nanoparticles make them extremely suitable for designing new and improved sensing devices, especially electrochemical sensors and biosensors. Many kinds of nanoparticles, such as metal, oxide and semiconductor nanoparticles have been used for constructing electrochemical sensors and biosensors, and these nanoparticles play different roles in different sensing systems. The important functions provided by nanoparticles include the immobilization of biomolecules, the catalysis of electrochemical reactions, the enhancement of electron transfer between electrode surfaces and proteins, labeling of biomolecules and even acting as reactant. This minireview addresses recent advances in nanoparticle‐based electrochemical sensors and biosensors, and summarizes the main functions of nanoparticles in these sensor systems. 相似文献
19.
Detection of small metabolite biomarkers at different concentrations could be powerfully used for disease diagnosis and progression. To enhance detection capabilities, nanomaterials possessing excellent optical and electrochemical properties have been integrated into a wide range of sensing or detection platforms. This review will highlight recent developments in creating electrochemical sensors alongside biosensors using carbon nanomaterials and metallic nanoparticles that target small metabolites. Moreover, electrochemical sensors having different detection strategies toward metabolites (such as amino acids, amino acid–derived neurotransmitters, vitamins, adenosine triphosphate, and purine derivatives) will be discussed. Finally, certain challenging issues and future aspects of nanomaterials-integrated electrochemical sensors for small metabolites will be discussed. 相似文献
20.
Dimitrios P. Nikolelis Tibor Hianik Georgia‐Paraskevi Nikoleli 《Electroanalysis》2010,22(23):2747-2763
Lipid membrane based electrochemical biosensors have been exploited for the last 40 years. However, a major obstacle that limited their applications and commercialization was their fragility. Recent advances in stabilization of lipid membranes have tremendously increased the number of publications in the last 5 years. The objective of the present article is to present procedures for the stabilization of lipid film biosensors and recent advances in their analytical uses. These novel devices are used as chemo‐ and biosensors for the quantification of environmental contaminants and food toxicants. Recent research is directed to the construction of a portable mini electrochemical device that will be commercialized and readily be used by non‐skilled personnel for in the field measurements. 相似文献