生物传感器应用于食源性致病菌检测研究进展

生物传感器技术是一种由生物、化学、物理、医学、电子技术等多种学科互相渗透形成起来的高新微量分析技术,具有选择性好、灵敏度高、分析速度快、成本低、能在复杂的体系中进行在线连续监测的特点.本文根据生物传感器的分子识别元件将生物传感器分为DNA传感器、免疫传感器、细胞传感器三大类,简要介绍各种生物传感器的原理及其在检测食源性致病菌方面的应用情况,并对未来生物传感器应用于实际检测进行了展望.     

适配体传感器在微生物检测中的应用

适配体是一类特异的核酸序列,具有靶分子广、特异性强、稳定等优点.该类核酸分子在体外通过SELEX(systematic evolution of ligands by exponential enrichment)技术(系统进化的指数富集技术)鉴定和筛选得到.相对于抗体,适配体为诊断和检测分析系统中的识别配基提供了另一个选择.适配体生物传感器是将生物识别元件和信号转换元件紧密结合,从而检测目标化合物的分析装置.适配体生物传感器在微生物检测方面具有分析速度快、灵敏度高、专一性强等特点,在微生物检测中显示出良好的应用前景.介绍了适配体、SELEX流程以及适配体传感器,综述了适配体传感器在微生物检测中的应用.     

生物传感器

生物传感器是对被分析物具有高度的选择性的分析器件。它的敏感元件是生物活性单元,转换元件是物理、化学等转换元件。生物传感器具有检测速度快、灵敏度高、成本低、操作简便以及可进行连续动态监测等优点。本文介绍了生物传感器的发展现状及工作原理,并对生物传感器在环境监测、食物质量和医学方面的应用研究进行了阐述。     

生物传感器在食源性致病菌检测中应用的研究进展

食源性致病菌作为引起食源性疾病的主要因素,受到人们的高度重视,发展简便、快速、高灵敏度和低成本的食源性致病菌检测方法对降低食源性疾病发病率具有重要意义。生物传感器技术是一种由多学科交叉渗透发展形成的全新微量分析技术,具有灵敏度高、分析速度快等特点,被广泛应用于食源性致病菌的检测。文中介绍了生物传感器的基本原理,综述了常见的生物传感器在食源性致病菌检测中的应用,并对其发展趋势进行了展望。     

PCR技术检测单核细胞增生李斯特氏菌研究进展

单核细胞增生李斯特氏菌(Listeria monocytogenes)是危害公共卫生和食品行业的一种重要人畜共患病致病菌.PCR技术是近年来被广泛地运用到食源性致病菌快速检测的分子生物学方法之一.就PCR技术检测单核细胞增生李斯特氏菌中的特异性鉴别基因、模板DNA制备等关键因素及多重PCR、巢式PCR、反转录PCR与定量PCR等主要技术进行了综述.     

土拉弗朗西斯菌检测研究进展

土拉弗朗西斯菌（Francisella tularensis）是土拉菌病（Tularemia）的致病菌,是最具传染性的致病菌之一,在自然界中已发现一百种以上的动物感染此菌。因其传播途径多样,易扩散、毒性强而被美国疾病控制预防中心列入A类生物恐怖制剂。土拉菌病是一种人畜共患病,致死率高,及时、准确的检测土拉菌对于土拉菌病患者及时治疗和防止扩散具有重要的意义。土拉菌检测方法很多,如菌培养,微凝集实验、酶联免疫吸附、快速检测试纸条、生物传感器、PCR、核酸杂交检测、质谱分析、基因芯片等。但到目前为止还没有一种成熟的用于土拉菌检测方法,其主要原因在于土拉菌致病性强,且不易分离培养。本文综述了土拉菌细菌学、免疫学、分子生物学方法检测的最新研究进展。     

食源性致病菌快速检测技术研究进展

食源性致病菌是影响食品安全的主要因素之一,传统的细菌分离、培养与鉴定由于需时较长,特别是有的细菌难以培养,难以适应食源性疾病预防控制的需要,因而快速、简便、特异的检测方法成为研究的热点。对电阻抗、放射测量、微热量、ELISA、PCR、基因芯片和生物传感器技术在金黄色葡萄球菌、沙门菌、肠出血性大肠埃希菌等食源性致病菌快速检测中的应用研究进行综述。     

单核细胞增生李斯特氏菌PCR-DHPLC检测新技术的建立

应用PCR结合变性高效液相色谱(DHPLC)技术建立食品中单核细胞增生李斯特氏菌fimY的快速检测方法。根据单核细胞增生李斯特氏菌prfA和hlyA基因序列的特点设计特异性引物,PCR扩增的产物经DHPLC技术进行快速检测。以单核细胞增生李斯特氏菌等61株参考菌株做特异性试验;单核细胞增生李斯特氏菌菌株稀释成不同梯度,进行灵敏度试验。试验结果表明该方法具有很好的特异性,灵敏度较高,检测低限可达到为181CFU/ml。可以快速、准确检测单核细胞增生李斯特氏菌,是食品中致病菌快速检测的新技术。     

食源性致病菌检测免疫传感器研究进展

食源性致病菌是造成食品安全事件的主要原因之一,因此其检测方法已成为人们研究的热点.食源性致病菌的检测方法主要有病原体培养法、免疫学方法、核酸检测和生物传感器等.其中,免疫传感器基于抗原抗体特异性结合,整合光学、电化学等多学科交叉技术,具有特异性强、检测速度快等特点.本文对比食源性致病菌传统检测方法,综述了近年来免疫传感...     

DNA生物传感器在环境污染监测中的应用

基于生物催化和免疫原理的生物传感器在环境领域中获得了广泛应用.近年来,随着分子生物学和生物技术的发展,人们开发了以核酸探针为识别元件,基于核酸相互作用原理的DNA生物传感器.该传感器可用于受感染微生物的核酸序列分析、优先控制污染物的检测以及污染物与DNA之间相互作用的研究,在环境污染监测中具有潜在的巨大应用前景.简要介绍了核酸杂交生物传感器的基本原理及其在环境微生物和优先控制污染物（priority pollutant）检测中的应用研究进展.     

Advances in Cell‐Free Biosensors: Principle,Mechanism, and Applications

Synthetic biology has promoted the development of biosensors as tools for detecting trace substances. In the past, biosensors based on synthetic biology have been designed on living cells, but the development of cell biosensors has been greatly limited by defects such as genetically modified organism problem and the obstruction of cell membrane. However, the advent of cell‐free synthetic biology addresses these limitations. Biosensors based on the cell‐free protein synthesis system have the advantages of higher safety, higher sensitivity, and faster response time over cell biosensors, which make cell‐free biosensors have a broader application prospect. This review summarizes the workflow of various cell‐free biosensors, including the identification of analytes and signal output. The detection range of cell‐free biosensors is greatly enlarged by different recognition mechanisms and output methods. In addition, the review also discusses the applications of cell‐free biosensors in environmental monitoring and health diagnosis, as well as existing deficiencies and aspects that should be improved. In the future, through continuous improvement and optimization, the potential of cell‐free biosensors will be stimulated, and their application fields will be expanded.     

Biosensors for the evaluation of lipase activity

In the review a comprehensive analysis is given of instrumental analytical approaches to control the activity of lipolytic enzymes and their substrates. A special attention is attached to the methods based on the biosensor technology. A number of electrochemical, optical and mechanical biosensors that were developed in several laboratories are analyzed in detail. In addition, perspectives are evaluated for the development of these biosensors and their practical application. It was concluded that biosensors may provide all practical demands which are in enzymology field at the express determination of lipase activity and triacylglycerol levels in biological objects.     

Progress of new label-free techniques for biosensors: a review

The detection techniques used in biosensors can be broadly classified into label-based and label-free. Label-based detection relies on the specific properties of labels for detecting a particular target. In contrast, label-free detection is suitable for the target molecules that are not labeled or the screening of analytes which are not easy to tag. Also, more types of label-free biosensors have emerged with developments in biotechnology. The latest developed techniques in label-free biosensors, such as field-effect transistors-based biosensors including carbon nanotube field-effect transistor biosensors, graphene field-effect transistor biosensors and silicon nanowire field-effect transistor biosensors, magnetoelastic biosensors, optical-based biosensors, surface stress-based biosensors and other type of biosensors based on the nanotechnology are discussed. The sensing principles, configurations, sensing performance, applications, advantages and restriction of different label-free based biosensors are considered and discussed in this review. Most concepts included in this survey could certainly be applied to the development of this kind of biosensor in the future.     

A new helicase assay based on graphene oxide for anti-viral drug development

Recently, graphene oxide (GO), one of the carbon nanomaterials, has received much attention due to its unique physical and chemical properties and high potential in many research areas, including applications as a biosensor and drug delivery vehicle. Various GO-based biosensors have been developed, largely based on its surface adsorption properties for detecting biomolecules, such as nucleotides and peptides, and real-time monitoring of enzymatic reactions. In this review, we discuss recent advances in GO-based biosensors focusing on a novel assay platform for helicase activity, which was also employed in high-throughput screening to discover selective helicase inhibitors.     

New insights into the molecular mechanisms of biomembrane structural changes and interactions by optical biosensor technology

Biomolecular-membrane interactions play a critical role in the regulation of many important biological processes such as protein trafficking, cellular signalling and ion channel formation. Peptide/protein–membrane interactions can also destabilise and damage the membrane which can lead to cell death. Characterisation of the molecular details of these binding-mediated membrane destabilisation processes is therefore central to understanding cellular events such as antimicrobial action, membrane-mediated amyloid aggregation, and apoptotic protein induced mitochondrial membrane permeabilisation. Optical biosensors have provided a unique approach to characterising membrane interactions allowing quantitation of binding events and new insight into the kinetic mechanism of these interactions. One of the most commonly used optical biosensor technologies is surface plasmon resonance (SPR) and there have been an increasing number of studies reporting the use of this technique for investigating biophysical analysis of membrane-mediated events. More recently, a number of new optical biosensors based on waveguide techniques have been developed, allowing membrane structure changes to be measured simultaneously with mass binding measurements. These techniques include dual polarisation interferometry (DPI), plasmon waveguide resonance spectroscopy (PWR) and optical waveguide light mode spectroscopy (OWLS). These techniques have expanded the application of optical biosensors to allow the analysis of membrane structure changes during peptide and protein binding. This review provides a theoretical and practical overview of the application of biosensor technology with a specific focus on DPI, PWR and OWLS to study biomembrane-mediated events and the mechanism of biomembrane disruption. This article is part of a Special Issue entitled: Lipid–protein interactions.     

基于转录因子的代谢物生物传感器的研究进展

基于转录因子的代谢物生物传感器在代谢工程和合成生物学中发挥着重要的作用。生物传感器感应代谢物浓度信号,将其转换为特定信号输出,具有灵敏度高、特异性强、分析速度快等特点,被广泛应用于目标代谢物的响应。文中介绍了基于转录因子生物传感器的作用原理,以及近年来在微生物细胞中的应用实例和应用方面面临的挑战,主要包括目标代谢物浓度的检测、高通量筛选、自适应实验室进化选择和动态控制,同时为了克服应用中的挑战,也着重介绍了基于转录因子生物传感器的性能调节策略,主要包括传统调节和计算机辅助的调节策略,讨论了生物传感器在实际应用中可能面临的机遇与挑战,并对其发展趋势进行了展望。     

生物电化学及其在环境监测中的应用

简要概述了生物电化学的研究领域,包括生物体系和生物界面模拟、生物分子的电化学、生物电催化、光合作用模拟和活组织电化学;总结了生物电化学传感器、生物芯片和生物电化学反应器在环境监测中的应用现状,并提出了其发展趋势,即不断向商品化方向发展,实现环境污染物的在线检测;利用基因技术,创造出检测能力更强的生物传感器和生物芯片;与其他精密分析仪器相结合,向多功能、集成化、智能化、微型化方向发展。     

Controlling Optical Absorption of Graphene in Near-infrared Region by Surface Plasmons

Nowadays, graphene has many applications in optical instruments, biosensors, gas sensors, photovoltaic cells, and so on. In this study, we aimed at investigating the optical properties of graphene under the influence of plasmons created in one-dimensional photonic crystal structure by making use of the absorption spectrum. We put the gold photonic crystal in adjacent to graphene and placed an antireflection layer on top of it. Then, we studied the behavior of graphene absorption peaks in a near-infrared region. By analyzing the graphene behavior in this region, we observed that graphene absorption was increased up to 40% and graphene absorption value in absorption peak, absorption peak wavelength, absorption spectra width, and also its absorption spectra in a wide wavelength range from 1000 to 2500 nm, could be controlled by making use of different factors such as the substance of antireflection layer and photonic crystal geometric dimensions. This structure can make many applications possible for graphene such as using it to build biosensors to identify uric acid and some of the lipids that have specific significances in detecting atherosclerotic lesions as well as diagnosing the states of disease.     

Detection of physiologically active compounds using cell-based biosensors.

Cell-based biosensors are portable devices that contain living biological cells that monitor physiological changes induced by exposure to environmental perturbations such as toxicants, pathogens or other agents. Methods of detecting physiological changes include extracellular electrical recordings, optical measurements, and, in the future, functional genomics and proteomics. Several technical developments are occurring that will increase the feasibility of cell-based biosensors for field applications; these developments include stem cell and 3D culture technologies. Possible scenarios for the use of cell-based biosensors include broad-range detectors of unknown threat agents and functional assessment of identified agents.