适配体结合蛋白质靶标的亲和力表征方法及其在疾病诊断中的应用

核酸适配体是通过体外指数富集配体系统进化（SELEX）技术筛选获得,并能够和蛋白质靶标高特异性、高亲和力结合的单链寡核苷酸。核酸适配体不但具有抗体的识别特性,而且具有自己独特的优良性能,目前已应用于分析检验、食品安全和生物医药等各个领域。蛋白质具有多种多样的生物功能以及临床诊断价值。因此,核酸适配体针对蛋白质靶标并在蛋白质相关的基础研究领域受到广泛的关注。核酸适配体应用性能的优劣取决于与其靶标蛋白质的亲和力与特异性。本文主要综述核酸适配体对蛋白质靶标的亲和力表征方法,以及在药物研发、肿瘤检测、生物成像以及生物传感器方面的应用。     

A review of molecular recognition technologies for detection of biological threat agents

The present review summarizes the state of the art in molecular recognition of biowarfare agents and other pathogens and emphasizes the advantages of using particular types of reagents for a given target (e.g. detection of bacteria using antibodies versus nucleic acid probes). It is difficult to draw firm conclusions as to type of biorecognition molecule to use for a given analyte. However, the detection method and reagents are generally target-driven and the user must decide on what level (genetic versus phenotypic) the detection should be performed. In general, nucleic acid-based detection is more specific and sensitive than immunological-based detection, while the latter is faster and more robust. This review also points out the challenges faced by military and civilian defense components in the rapid and accurate detection and identification of harmful agents in the field. Although new and improved sensors will continue to be developed, the more crucial need in any biosensor may be the molecular recognition component (e.g. antibody, aptamer, enzyme, nucleic acid, receptor, etc.). Improvements in the affinity, specificity and mass production of the molecular recognition components may ultimately dictate the success or failure of detection technologies in both a technical and commercial sense. Achieving the ultimate goal of giving the individual soldier on the battlefield or civilian responders to an urban biological attack or epidemic, a miniature, sensitive and accurate biosensor may depend as much on molecular biology and molecular engineering as on hardware engineering. Fortunately, as this review illustrates, a great deal of scientific attention has and is currently being given to the area of molecular recognition components. Highly sensitive and specific detection of pathogenic bacteria and viruses has increased with the proliferation of nucleic acid and immuno-based detection technologies. If recent scientific progress is a fair indicator, the future promises remarkable new developments in molecular recognition elements for use in biosensors with a vast array of applications.     

Detection of hepatitis B virus surface antigen with the use of an optical biosensor

The detection of hepatitis B virus surface antigen (HBsAg) with the use of a model IAsys+ two-channel optical biosensor is based on the registration of interaction between anti-HBs monoclonal antibodies forming the surface layer of the biochip of the biosensor cuvette and blood serum HBsAg. For the first time a two-channel optical biosensor has been used for the detection of HBsAg in blood serum samples. The comparative analysis of the detection of HBsAg by two methods, viz. with the use of an optical biosensor and the enzyme immunoassay, has demonstrated lower sensitivity, but higher specificity of the detection of this antigen by means of a model IAsys+ biosensor with the biochip, prepared in the process of the work. The main advantages of the biosensor detection lie in the registration of interaction in real time without introducing special markers into the molecules under study.     

极具有应用前景的生物学检测技术-生物传感器

生物传感器是近年逐渐发展起来的一种高新生物学分析检测技术,它将生物学或仿生学信号感应部件紧密连接或整合到传感系统内,具有特异、敏感、快速、便携以及操作简便等优点,发展非常迅速,并且被应用到医疗保健、食品工业、畜牧兽医等多个领域,已成为人们研究的热点之一。本文概述了生物传感器的概念与工作原理、分类、与主要领域的研究应用,分析了生物传感器的产业现状,优点与现存问题,并对其应用发展前景进行了展望。     

Development of a Cryptosporidium oocyst assay using an automated fiber optic-based biosensor

An intestinal protozoan parasite, Cryptosporidium parvum, is a major cause of waterborne gastrointestinal disease worldwide. Detection of Cryptosporidium oocysts in potable water is a high priority for the water treatment industry to reduce potential outbreaks among the consumer populace. Anti-Cryptosporidium oocyst polyclonal and monoclonal antibodies were tested as capture and detection reagents for use in a fiber optic biosensor assay for the detection of Cryptosporidium oocysts. Antibodies were validated using enzyme-linked immunosorbent assays, flow cytometry, Western blotting and fluorescent microscopy. Oocysts could be detected at a concentration of 10⁵ oocysts/ml when the polyclonal antibodies were used as the capture and detection reagents. When oocysts were boiled prior to detection, a ten-fold increase in sensitivity was achieved using the polyclonal antibody. Western blotting and immunofluorescence revealed that both the monoclonal and polyclonal antibodies recognize a large (>300 kDa) molecular weight mucin-like antigen present on the surface of the oocyst wall. The polyclonal antibody also reacted with a small (105 kDa) molecular weight antigen that was present in boiled samples of oocysts. Preliminary steps to design an in-line biosensor assay system have shown that oocysts would have to be concentrated from water samples and heat treated to allow detection by a biosensor assay.     

Determination of trace copper ions with ultrahigh sensitivity and selectivity utilizing CdTe quantum dots coupled with enzyme inhibition

Nanomaterial-based enzyme-linked immunosorbent assay (ELISA) with sufficient sensing specificity is a useful analytical tool for the detection of toxicologically important substances in complicated biological systems. Increasing worldwide demand for nanomaterials and increasing concern on their safe development and use, require a simple, stable, and sensitive detection assay for pathogen evaluation and environmental monitoring. However, this goal is not yet achieved. A design for a hybrid MnO(2) nanowire-ELISA using the sandwich assay format, which provides quantitative binding information for both a specific antibody and the pathogen, sulfate-reducing bacteria, and detects pathogen concentration, is presented. 3,3',5,5'-Tetramethylbenzidine was used as the substrate and was allowed to react with the MnO(2) nanowires without H(2)O(2) in the reaction system. The kinetic parameters were measured with the system acting as a catalytic biosensor. The effectiveness of the MnO(2) nanowire-based biosensor was demonstrated by its sensitive detection of the pathogen.     

基于CRISPR/Cas生物传感原理的病原菌检测技术研究进展*

病原菌的快速准确检测是实现疫情高效防控、疾病精准治疗、污染环境及时处置的关键。而现有的病原菌现场快速检测技术,主要以定性分析为主,假阳性/假阴性受到诟病,检测准确性仍有待提升,亟待发展基于新原理、新方法的病原菌快速检测技术。基于CRISPR(clustered regularly interspaced short palindromic repeats)的生物传感技术因具有高灵活性(对不同的基因靶点只需改变crRNA序列)、高特异性(单碱基分辨)、高灵敏(优于10^-18 mol/L浓度)、可编程、可模块化、低成本、可在各种体外介质中高效稳定运行等独特优势,打破了传统分子诊断与检测技术的局限性,正在成为下一代病原菌检测技术的引领者。在该技术中,Cas效应蛋白被用作高特异性的序列识别元件,结合不同的生物传感机制,即可用于病原菌的高特异性快速灵敏检测。在总结CRISPR/Cas生物传感技术原理的基础上,综述了用于病原菌检测的CRISPR/Cas12和CRISPR/Cas13生物传感技术研究进展。通过阐述CRISPR/Cas生物传感技术在实际应用中面临的挑战,展望其未来的发展前景。     

肽核酸在分子生物学技术中的应用

肽核酸(PNA)作为一种人工合成的核酸类似物,以中性的肽链酰胺2-氨基乙基甘氨酸键取代了DNA中的戊糖磷酸二酯键骨架,其余部分与DNA相同。PNA可通过Watson-Crick碱基配对的形式识别并结合DNA或RNA序列,形成稳定的双螺旋结构。与传统的DNA或RNA相比,PNA具有生物学稳定性高、杂交特异性强、杂合体的稳定性高和杂交速度快等明显优点,使PNA具有良好的物理化学性质和生物学特性,在检测目的核酸序列中单碱基突变、PCR基因分子诊断与检测、荧光原位杂交定量分析、基因芯片和生物传感器技术等调控水平和临床应用上有自己的特点。简要综述了近年来肽核酸在上述分子生物学技术中的运用以及应用前景的展望。     

A conductometric biosensor for biosecurity

The paper describes the development of a conductometric biosensor for detecting foodborne pathogens. The biosensor consists of two components: an immunosensor that is based on electrochemical sandwich immunoassay, and a reader for signal measurement. The architecture of the immunosensor utilizes a lateral flow system that allows the liquid sample to move from one pad to another. The biosensor provides a specific, sensitive, low volume, and near real-time detection mechanism. Results are presented to highlight the performance of the biosensor for enterohemorrhagic Escherichia coli O157:H7 and Salmonella spp., which are of concern to biosecurity. The lower limit of detection is approximately 7.9 x 10(1) colony forming units per milliliter within a 10-min process. The ability to change the specificity of the antibodies will enable the biosensor to be used as a detection device for other types of foodborne pathogens.     

Cell uptake of a biosensor detected by hyperpolarized 129Xe NMR: the transferrin case

For detection of biological events in vitro, sensors using hyperpolarized (129)Xe NMR can become a powerful tool, provided the approach can bridge the gap in sensitivity. Here we propose constructs based on the non-selective grafting of cryptophane precursors on holo-transferrin. This biological system was chosen because there are many receptors on the cell surface, and endocytosis further increases this density. The study of these biosensors with K562 cell suspensions via fluorescence microscopy and (129)Xe NMR indicates a strong interaction, as well as interesting features such as the capacity of xenon to enter the cryptophane even when the biosensor is endocytosed, while keeping a high level of polarization. Despite a lack of specificity for transferrin receptors, undoubtedly due to the hydrophobic character of the cryptophane moiety that attracts the biosensor into the cell membrane, these biosensors allow the first in-cell probing of biological events using hyperpolarized xenon.     

A high density microelectrode array biosensor for detection of E. coli O157:H7

A high density microelectrode array biosensor was developed for the detection of Escherichia coli O157:H7. The biosensor was fabricated from (100) silicon with a 2 microm layer of thermal oxide as an insulating layer, an active area of 9.6 mm2 and consists of an interdigitated gold electrode array. The sensor surface was functionalised for bacterial detection using heterobifunctional crosslinkers and immobilised polyclonal antibodies to create a biological sensing surface. Bacteria suspended in solution became attached to the immobilised antibodies when the biosensor was tested in liquid samples. The change in impedance caused by the bacteria was measured over a frequency range of 100 Hz-10 M Hz. The biosensor was evaluated for E. coli O157:H7 detection in pure culture and inoculated food samples. The biosensor was able to discriminate between cellular concentrations of 10(4)-10(7)CFU/mL and has applications in detecting pathogens in food samples.     

Detection of viral bioagents using a shear horizontal surface acoustic wave biosensor

Viruses are of high medical and biodefense concern and their detection at concentrations well below the threshold necessary to cause health hazards continues to be a challenge with respect to sensitivity, specificity, and selectivity. Ideally, assays for accurate and real time detection of viral agents would not necessitate any pre-processing of the analyte, which would make them applicable for example to bodily fluids (blood, sputum) and man-made as well as naturally occurring bodies of water (pools, rivers). We describe herein a robust biosensor that combines the sensitivity of surface acoustic waves (SAW) generated at a frequency of 325MHz with the specificity provided by antibodies for the detection of viral agents. A lithium tantalate-based SAW transducer with silicon dioxide waveguide sensor platform featuring three test and one reference delay lines was used to adsorb antibodies directed against either Coxsackie virus B4 or the category A bioagent Sin Nombre virus (SNV), a member of the genus Hantavirus, family Bunyaviridae, negative-stranded RNA viruses. Rapid detection (within seconds) of increasing concentrations of viral particles was linear over a range of order of magnitude for both viruses, although the sensor was approximately 5 x 10(5)-fold more sensitive for the detection of SNV. For both pathogens, the sensor's selectivity for its target was not compromised by the presence of confounding Herpes Simplex virus type 1. The biosensor was able to detect SNV at doses lower than the load of virus typically found in a human patient suffering from hantavirus cardiopulmonary syndrome (HCPS). Further, in a proof-of-principle real world application, the SAW biosensor was capable to selectively detect SNV agents in complex solutions, such as naturally occurring bodies of water (river, sewage effluent) without analyte pre-processing. This is the first study that reports on the detection of viral agents using an antibody-based SAW biosensor that has the potential to be used as a hand-held and self-contained device for rapid viral detection in the field.     

Magnetic biosensor for the detection of Yersinia pestis

A novel type of magnetic-beads based magnetic biosensor is described for the detection of Yersinia pestis. Experiments were performed with the antigen fraction F1 of these bacteria. The magnetic sensor platform offers easy and reliable detection of Y. pestis by the use of magnetic beads for labelling and quantification in a single step due to their paramagnetic features. The system uses antiYPF1 antibodies as capture element on ABICAP columns as core element of the magnetic sensor. Several immobilization methods for antibodies on polyethylene were exploited. The established biosensor has a linear detection range of 25-300 ng/ml Y. pestis antigen F1 and a detection limit of 2.5 ng/ml in buffer and human blood serum. The presented sensor system is small, simple, portable and therefore usable as off-lab detection unit for medical and warfare analytes.     

Polyaniline synthesis and its biosensor application

In this study, five polyaniline compounds were synthesized using different protonic acids and incorporated into a conductometric biosensor used for bovine viral diarrhea virus detection. The biosensor was developed and evaluated by the authors for bacterial pathogen detection in previous studies. The biosensor consisted of two parts: the immunosensor and the electronic data collection system. Liquid sample moved through the immunosensor surface by capillary action. The specificity of the biosensor was based on the unique binding characteristics of the polyclonal and monoclonal antibodies immobilized on the immunosensor. Polyaniline was used in the biosensor architecture as the transducer due to its electronic and bio-molecular properties. Results showed that the biosensor was sensitive at a concentration of 10(3) cell culture infective dose per milliliter (CCID/ml) of BVDV antigens. The promising results on the BVDV detection demonstrated that the conductometric biosensor was interchangeable for different target molecules of detection. Further modification could be implemented to evaluate the biosensor as a rapid diagnostic device to detect other infectious disease outbreaks in livestock population.     

Phospho-specific recognition by 14-3-3 proteins and antibodies monitored by a high throughput label-free optical biosensor

Label-free detection of molecular interactions has considerable potential in facilitating assay development. When combined with high throughput capability, it may be applied to small molecule screens for drug candidates. Phosphorylation is a key posttranslational process that confers diverse regulation in biological systems involving specific protein-protein interactions recognizing the phosphorylated motifs. Using a resonant waveguide grating biosensor, the Epic mark System, we have developed a generic assay to quantitatively measure phospho-specific interactions between a trafficking signal-phosphorylated SWTY peptide and 14-3-3 proteins or anti-phosphopeptide antibodies. Compared with a solution-based fluorescence anisotropy assay, our results support that the high throughput resonant waveguide grating biosensor system has favorable technical profiles in detecting protein-protein interactions that recognize phosphorylated motifs. Hence it provides a new generic HTS platform for phospho-detection.     

Current based antibodies detection from human serum enhanced by secondary antibodies labelled with gold nanoparticles immobilized in a nanogap

We present the electrical detection of immunoglobulin G (IgGs) from human serum using a nanogap-based biosensor. The detection method is based on the capture of IgGs by a probe immobilized between gold nanoelectrodes of 30-90nm spacing. The captured IgGs are further reacted with secondary antibodies labelled with gold nanoparticles (GNPs). Insertion of GNPs into the nanogap resulted in increasing the conductance through the nanogap. The use of a chip with 90 nanogaps enabled the calculation of a quality factor for the detection which, coupled with a non-linear regression analysis of the data, easily discriminated specific and differential capture of human antibodies by arrayed probes. We obtained a 500-fold higher quality factor with protein A compared to goat anti-murine antibodies. This method can be applied, through these proof-of-concept experiments, to the detection of protein-protein interactions in biological samples.     

Detection of low-molecular-weight heparin oligosaccharides (Fragmin) using surface plasmon resonance

During the last decades there has been a growing realization of the central biological role that oligosaccharides and oligosaccharide-protein interactions play. One of the most striking examples is the use of heparin and low-molecular-weight heparin oligosaccharides (Fragmin) to modify blood coagulation. Several monoclonal antibodies directed against glycosaminoglycan structures have been produced. However, their clinical use is limited by the difficulty of detection systems for oligosaccharides. In the present study we used a monoclonal antibody directed against heparin oligosaccharides prepared by partial nitrous acid deamination of heparin. Using a biosensor (BIAcore), purified antibody was immobilized on sensor surfaces and binding of oligosaccharide was measured by surface plasmon resonance. Using this technique, it was possible to quantitate low-molecular-weight heparin oligosaccharides in nanomolar concentrations.     

小分子靶标的核糖开关生物传感器研究进展

小分子化合物种类繁多，在众多生化过程中发挥关键作用，具有重要的检测意义与价值,其快速灵敏可视化检测技术的开发是当前的研究热点。基于核糖开关的生物传感器因具有识别特性高、操作简便、成本低等优势，为小分子检测提供了一条新途径。对核糖开关的来源、构成、调控机制、体内外筛选，特别是对基于小分子靶标的核糖开关生物传感器分类进行了介绍，并从核糖开关的筛选、裁剪、理性设计、核糖开关无细胞传感器的应用等几个方向提出了展望，以期为小分子靶标的核糖开关生物传感器的发展和应用提供理论依据。     

Technological advancements in bio-recognition using liquid crystals: Techniques,applications, and performance

The application of liquid crystal (LC) materials has undergone a modern-day renaissance from its classical use in electronics industry as display devices to new-fangled techniques for optically detecting biological and chemical analytes. This review article deals with the emergence of LC materials as invaluable material for their use as label-free sensing elements in the development of optical, electro-optical and electrochemical biosensors. The property of LC molecules to change their orientation on perturbation by any external stimuli or on interaction with bioanalytes or chemical species has been utilized by many researches for the fabrication of high sensitive LC-biosensors. In this review article we categorized LC-biosensor based on biomolecular reaction mechanism viz. enzymatic, nucleotides and immunoreaction in conjunction with operating principle at different LC interface namely LC-solid, LC-aqueous and LC-droplets. Based on bimolecular reaction mechanism, the application of LC has been delineated with recent progress made in designing of LC-interface for the detection of bio and chemical analytes of proteins, virus, bacteria, clinically relevant compounds, heavy metal ions and environmental pollutants. The review briefly describes the experimental set-ups, sensitivity, specificity, limit of detection and linear range of various viable and conspicuous LC-based biosensor platforms with associated advantages and disadvantages therein.     

The investigation of Protein A and Salmonella antibody adsorption onto biosensor surfaces by atomic force microscopy

The investigation of Protein A and antibody adsorption on surfaces in a biological environment is an important and fundamental step for increasing biosensor sensitivity and specificity. The atomic force microscope (AFM) is a powerful tool that is frequently used to characterize surfaces coated with a variety of molecules. We used AFM in conjunction with scanning electron microscopy to characterize the attachment of protein A and its subsequent binding to the antibody and Salmonella bacteria using a gold quartz crystal. The rms roughness of the base gold surface was determined to be approximately 1.30 nm. The average step height change between the solid gold and protein A layer was approximately 3.0 +/- 1.0 nm, while the average step height of the protein A with attached antibody was approximately 6.0 +/- 1.0 nm. We found that the antibodies did not completely cover the protein A layer, instead the attachment follows an island model. Salt crystals and water trapped under the protein A layer were also observed. The uneven adsorption of antibodies onto the biosensor surface might have led to a decrease in the sensitivity of the biosensor. The presence of salt crystals and water under the protein A layer may deteriorate the sensor specificity. In this report, we have discussed the application and characterization of protein A bound to antibodies which can be used to detect bacterial and viral pathogens.