Label-free Electrochemical Aptasensor for the Determination of Serotonin

A label-free electrochemical aptasensor was fabricated for the determination of serotonin (5-HT) by the employment of specific binding between 5-HT and aptamer and directly electrochemical measurement of 5-HT oxidation. The comparison between two aptasensors and two strategies was studied. An electrochemical aptasensor fabricated using 57-mer aptamer was facilely used to determine 5-HT in the range from 1 μM to 100 μM with detection limit of 0.3 μM via one step recognition and detection. This work demonstrates that electrochemical method combing aptamer recognition and 5-HT oxidation provides an alternative and promising method for the determination of 5-HT with good selectivity and simplicity.     

漆酶在纳米金溶胶/多重壁碳纳米管复合载体上固定方法的比较及粒子尺寸效应

以纳米金溶胶（NGS）和多重壁碳纳米管（MWCNTs）的共混物(NGS/MWCNTs)作为固定漆酶的载体,研究了3种固定漆酶方法在酶固定量、比活力上的差异。 研究了不同的固定方法对固定酶热稳定性和重复使用性及纳米金溶胶颗粒粒径对酶固定量和固定酶动力学参数的影响。 实验结果表明,NGS/MWCNTs具有良好的固定漆酶能力和高固酶比活力,NGS/MWCNTs（NGS粒径37 nm）通过简单物理吸附法固定漆酶的量和固酶的比活力最高,分别可达33.80 mg/g和9.433 U/mg。 在NGS-MWCNTs上采用化学键合方法固定的漆酶在70 ℃放置2 h后仍然保持初始活力的75％,重复使用20次后仍保持初始活力的70％。 纳米金溶胶粒子越小（24 nm）,底物和固定漆酶间亲和力越好（KM=0.027 mmol/L）,表观速率常数越大。     

Artful union of a zirconium-porphyrin MOF/GO composite for fabricating an aptamer-based electrochemical sensor with superb detecting performance

More and more attentions have been focused on design and synthesis of novel metal-organic framework/graphene oxide (MOF/GO) composites with unique performance. Zirconium-porphyrin MOF (PCN-222) is in-situ synthesis with the existence of GO with −COOH group to artfully fabricate a PCN-222/GO composite. This composite can be employed as functional material to modify the working electrode. Thanks to excellent electrical conductivity of GO, abundant mesoporous channels and numerous Zr(IV) metal sites of PCN-222, this composite can immobilize a large amount of aptamer through strong π-π stacking interaction and high affinity between phosphate group of aptamer and Zr(IV) site of PCN-222 simultaneously. Hence, an ultra-sensitive electrochemical aptasensor based on PCN-222/GO composite can quantificationally detect trace chloramphenicol with limit of detection of 7.04 pg/mL (21.79 pmol/L) from 0.01 ng/mL to 50 ng/mL by electrochemical impedance spectroscopy even in real samples. Meanwhile, this fabricated aptasensor reveals good repeatability, outstanding selectivity and preferable long-term storage. This research provides a useful approach to construct MOF/GO composites for fabricating electrochemical aptasensors in the electrochemical detection field.     

Impedimetric Aptasensor Based on Disposable Graphite Electrodes Developed for Thrombin Detection

The impedimetric aptasensor for Thrombin (THR) was developed for the first time herein by measuring changes at the charge‐transfer resistance, R_ct upon to protein? aptamer complex formation. After covalent activation of pencil graphite electrode (PGE) surface using covalent agents, amino linked aptamer (APT) was immobilized onto activated PGE surface. Then APT‐THR interaction was explored by electrochemical impedance spectroscopy (EIS). After the optimization of experimental conditions (e.g., APT and THR concentration, immobilization and interaction times), the selectivity of impedimetric aptasensor was tested in the presence of other biomolecules: factor Va and bovine serum albumine (BSA) both in buffer media, or in diluted fetal bovine serum (FBS).     

Ultrasensitive Detection and Binding Mechanism of Cocaine in an Aptamer‐based Single‐molecule Device

Aptamer serves as a potential candidate for the micro‐detection of cocaine due to its high specificity, high affinity and good stability. Although cocaine aptasensors have been extensively studied, the binding mechanism of cocaine‐aptamer interactions is still unknown, which limits the structural refinement in the design of an aptamer to improve the performance of cocaine aptasensors. Herein, we report a label‐free, ultrasensitive detection of single‐molecule cocaine‐aptamer interaction by using an electrical nanocircuit based on graphene‐molecule‐ graphene single‐molecule junctions (GMG‐SMJs). Real‐time recordings of cocaine‐aptamer interactions have exhibited distinct current oscillations before and after cocaine treatment, revealing the dynamic mechanism of the conformational changes of aptamer upon binding with cocaine. Further concentration‐dependent experiments have proved that these devices can act as a single‐molecule biosensor with at least a limit of detection as low as 1 nmol?L^–1. The method demonstrated in this work provides a novel strategy for shedding light on the interaction mechanism of biomolecules as well as constructing new types of aptasensors toward practical applications.     

Affinity Covalent Immobilization of Glucoamylase onto ρ-Benzoquinone-Activated Alginate Beads: II. Enzyme Immobilization and Characterization

A novel affinity covalent immobilization technique of glucoamylase enzyme onto ρ-benzoquinone-activated alginate beads was presented and compared with traditional entrapment one. Factors affecting the immobilization process such as enzyme concentration, alginate concentration, calcium chloride concentration, cross-linking time, and temperature were studied. No shift in the optimum temperature and pH of immobilized enzymes was observed. In addition, K _m values of free and entrapped glucoamylase were found to be almost identical, while the covalently immobilized enzyme shows the lowest affinity for substrate. In accordance, V _m value of covalently immobilized enzyme was found lowest among free and immobilized counter parts. On the other hand, the retained activity of covalently immobilized glucoamylase has been improved and was found higher than that of entrapped one. Finally, the industrial applicability of covalently immobilized glucoamylase has been investigated through monitoring both shelf and operational stability characters. The covalently immobilized enzyme kept its activity over 36 days of shelf storage and after 30 repeated use runs. Drying the catalytic beads greatly reduced its activity in the beginning but recovered its lost part during use. In general, the newly developed affinity covalent immobilization technique of glucoamylase onto ρ-benzoquinone-activated alginate carrier is simple yet effective and could be used for the immobilization of some other enzymes especially amylases.     

Immobilization of Chymotrypsin on Silica Beads Based on High Affinity and Specificity Aptamer and Its Applications

Aptamers with high affinity and specificity to targets, bring new approaches to immobilizing proteins or enzymes. In this work, a group of single-stranded DNA aptamers specific for chymotrypsin were obtained by SELEX method in vitro. After investigation and characterization of all aptamers, AptC.1 (abbreviation for the aptamer with the highest affinity for chymotrypsin) was selected and grafted onto silica matrix with the help of glutaraldehyde as linker, and used subsequently to immobilize chymotrypsin. Specifically, it is shown in experiment that, 12.65 µg of chymotrypsin could be immobilized on 10 mg of AptC.1-Silica in 10 mM pH 8.0 borate solutions, and the activity of immobilized enzyme was not inhibited. Bovine serum albumin, myoglobin and cytochrome c were introduced to investigate the enzymatic performance of prepared immobilized chymotrypsin reactor. All these results demonstrated that aptamer could serve as a potential medium for the immobilization of proteins or enzymes.     

Advantages of Carbon Nanomaterials in Electrochemical Aptasensors for Food Analysis

Electrochemical aptasensors appear as promising tools in food analysis, able to provide sensitive, fast and cost‐effective analysis, with the added advantage of portability. Carbon nanomaterials and in particular carbon nanotubes and graphene are among the nanomaterials most often used to build electrochemical aptasensors due to their good electrical conductivity, large surface area and multiple functionalisation possibilities. This review aims to give an overview of the types of carbon nanomaterials and their composites which have been used to enhance the performance of electrochemical aptasensors. Examples are detailed for the biosensors which were tested with real food samples. In these aptasensors, carbon nanomaterials have played different roles, from facilitating the immobilization of high amounts of aptamer and enhancing the electroactive area of the sensors to roles as nanocarrier for signaling probes in amplification schemes or even as electroactive probes generating the output signal. The survey of recent literature shows a positive evolution towards increased aptasensor testing with food samples. However, many challenges remain related to the better characterization of nanomaterials used, clarifying the roles of specific components in multi‐component nanocomposites and widening the types of food matrices and analytes tested with the aptasensors. Although we are still far from knowing when these novel tools will replace classic analytical methods in food analysis, carbon nanomaterials will certainly continue to play an important role in the design of future electrochemical aptasensors for food analysis.     

Preparation of an ultrafiltration membrane from the copolymer of acrylonitrile–glycidylmethacrylate utilized for immobilization of glucose oxidase

Ultrafiltration membrane has been prepared from the copolymer of acrylonitrile–glycidylmethacrylate and the porosity of the membrane was studied. The asymmetric structure was proved by scanning electron microscopy. The basic characteristics of the membrane were measured – water permeability, water content, membrane selectivity, etc. The membrane obtained was used as a carrier for immobilization of glucose oxidase. The immobilization was carried out covalently by two methods: direct bonding of the enzyme and indirectly by a spacer (hexamethylenediamine) and cross-linking agent (glutar aldehyde). The amount of bound protein and relative activity of the immobilized glucose oxidase were determined. Temperature optimum, pH optimum and storage stability of the immobilized glucose oxidase were determined. It was proved that glucose oxidase immobilized by the direct method shows better characteristics compared with the indirect method.     

Affinity Covalent Immobilization of Glucoamylase onto ρ-Benzoquinone Activated Alginate Beads: I. Beads Preparation and Characterization

ρ-Benzoquinone-activated alginate beads were presented as a new carrier for affinity covalent immobilization of glucoamylase enzyme. Evidences of alginate modification were extracted from FT-IR and thermal gravimetric analysis and supported by morphological changes recognized through SEM examination. Factors affecting the modification process such as ρ-benzoquinone (PBQ) concentration, reaction time, reaction temperature, reaction pH and finally alginate concentration, have been studied. Its influence on the amount of coupled PBQ was consequently correlated to the changes of the catalytic activity and the retained activity of immobilized enzyme, the main parameters judging the success of the immobilization process. The immobilized glucoamylase was found kept almost 80% of its native activity giving proof of non-significant substrate, starch, diffusion limitation. The proposed affinity covalent immobilizing technique would rank among the potential strategies for efficient immobilization of glucoamylase enzyme.     

Physical and Covalent Immobilization of <Emphasis Type="Italic">Lipase</Emphasis> onto Amine Groups Bearing Thiol-Ene Photocured Coatings

In this study, amine groups containing thiol-ene photocurable coating material for lipase immobilization were prepared. Lipase (EC 3.1.1.3) from Candida rugosa was immobilized onto the photocured coatings by physical adsorption and glutaraldehyde-activated covalent bonding methods, respectively. The catalytic efficiency of the immobilized and free enzymes was determined for the hydrolysis of p-nitrophenyl palmitate and also for the synthesis of p-nitrophenyl linoleate. The storage stability and the reusability of the immobilized enzyme and the effect of temperature and pH on the catalytic activities were also investigated. The optimum pH for free lipase and physically immobilized lipase was determined as 7.0, while it was found as 7.5 for the covalent immobilization. After immobilization, the optimum temperature increased from 37 °C (free lipase) to 50–55 °C. In the end of 15 repeated cycles, covalently bounded enzyme retained 60 and 70 % of its initial activities for hydrolytic and synthetic assays, respectively. While the physically bounded enzyme retained only 56 % of its hydrolytic activity and 67 % of its synthetic activity in the same cycle period. In the case of hydrolysis V _max values slightly decreased after immobilization. For synthetic assay, the V _max value for the covalently immobilized lipase was found as same as free lipase while it decreased dramatically for the physically immobilized lipase. Physically immobilized enzyme was found to be superior over covalent bonding in terms of enzyme loading capacity and optimum temperature and exhibited comparable re-use values and storage stability. Thus, a fast, easy, and less laborious method for lipase immobilization was developed.     

DNA-modified electrodes; part 4: optimization of covalent immobilization of DNA on self-assembled monolayers

The covalent immobilization of DNA onto self-assembled monolayer (SAM) modified gold electrodes (SAM/Au) was studied by X-ray photoelectron spectrometry and electrochemical method so as to optimize its covalent immobilization on SAMs. Three types of SAMs with hydroxyl, amino, and carboxyl terminal groups, respectively, were examined. Results obtained by both X-ray photoelectron spectrometry and cyclic voltammetry show that the largest covalent immobilization amount of dsDNA could be gained on hydroxyl-terminated SAM/Au. The ratio of amount of dsDNA immobilized on hydroxyl-terminated SAMs to that on carboxyl-terminated SAMs and to that on amino-terminated SAMs is (3-3.5): (1-1.5): 1. The dsDNA immobilized covalently on hydroxyl-terminated SAMs accounts for 82.8-87.6% of its total surface amount (including small amount of dsDNA adsorbed). So the hydroxyl-terminated SAM is a good substrate for the covalent immobilization of dsDNA on gold surfaces.     

Immobilization ofAspergillus niger NRC 107 xylanase and β-xylosidase,and properties of the immobilized enzymes

Aspergillus niger NRC 107 xylanase and β-xylosidase were immobilized on various carriers by different methods of immobilization, including physical adsorption, covalant binding, ionic binding, and entrapment. The immobilized enzymes were prepared by physical adsorption on tannin-chitosan, ionic binding onto Dowex-50W, covalent binding on chitosan beads through glutaraldehyde, and entrapment in polyacrylamide had the highest activities. In most cases, the optimum pH of the immobilized enzymes were shifted to lower than those of free enzymes. The optimum reaction temperature of immobilized xylanase was shifted from 50°C to 52.5–65°C, whereas that of immobilized β-xylosidase was shifted from 45°C to 50–60°C. TheK _m values of immobilized enzymes were higher than those of native enzymes. The operational stability of the immobilized enzymes was evaluated in continuous operation in packed-bead column-type reactors. The enzymes covalently bounded to chitosan showed the highest operational stability. However, the enzymes immobilized by physical adsorption or by ionic binding showed a low operational stability. The enzymes entrapped in polyacrylamide exhibited lower activity, but better operational stability.     

The effect of polymeric supports and methods of immobilization on the performance of an optical copper(II)-sensitive membrane based on the colourimetric reagent Zincon

A comparative study on the effect of different immobilization methods and matrix materials on the performance of copper(II)-sensitive membrane layers is presented. The indicator dye Zincon was immobilized in hydrophilic and hydrophobic polymers by various methods including: (a) physical entrapment of the Zincon-tetraoctylammonium ion pair in plasticized PVC, hydrogel, polystyrene, ethyl cellulose, poly-HEMA, AQ-polymer and in sol-gel glass; (b) electrostatic immobilization on an anion exchanger cellulose; and (c) covalent immobilization on cellulose via a sulfatoethylsulfonyl reactive group. The response to copper(II) ion was evaluated kinetically via the initial slope of the change in absorbance within 1 min. Layers made of hydrogel and PVC provide the highest sensitivity, while covalent immobilization is the most reproducible one, and sol-gel layers display the best mechanical stability.     

A comparison of four protocols for the immobilization of an aptamer on graphite composite electrodes

We have performed a comparative study on four protocols for the immobilization of the thrombin aptamer on a graphite-epoxy composite electrode with the aim to identify the most practical method for designing the corresponding impedimetric aptasensor. The protocols included (a) physical adsorption, (b) avidin-biotin affinity interaction, (c) electrochemical activation and covalent bonding via amide groups, and (d) electrochemical grafting using 4-carboxybenzenediazonium coupling. The properties of the sensing surface were probed by electrochemical impedance measurements in the presence of the (ferri/ferro)hexacyanide redox couple. An increase in the interfacial charge transfer resistance (R_ct) was noted in all cases after the aptamer-thrombin interaction had occurred. The selectivity of the aptasensor over common serum proteins was also systematically investigated. Physical adsorption resulted in the lowest detection limit of the probe (4.5 pM), while avidin-biotin interaction resulted in highest selectivity and reproducibility exhibiting a 4.9 % relative standard deviation at pM thrombin concentration levels.

Surface immobilization methods for aptamer diagnostic applications

In this review we examine various methods for the immobilization of aptamers onto different substrates that can be utilized in a diverse array of analytical formats. In most cases, covalent linking to surfaces is preferred over physisorption, which is reflected in the bulk of the reports covered within this review. Conjugation of aptamers with appropriate linkers directly to gold films or particles is discussed first, followed by methods for conjugating aptamers to functionally modified surfaces. In many aptamer-based applications, silicates and silicon oxide surfaces provide an advantage over metallic substrates, and generally require surface modification prior to covalent attachment of the aptamers. Chemical protocols for covalent attachment of aptamers to functionalized surfaces are summarized in the review, showing common pathways employed for aptamer immobilization on different surfaces. Biocoatings, such as avidin or one of its derivatives, have been shown to be highly successful for immobilizing biotin-tethered aptamers on various surfaces (e.g., gold, silicates, polymers). There are also a few examples reported of aptamer immobilization on other novel substrates, such as quantum dots, carbon nanotubes, and carbohydrates. This review covers the literature on aptamer immobilization up to March 2007, including comparison of different linkers of varying size and chemical structure, 3′ versus 5′ attachment, and regeneration methods of aptamers on surfaces.     

New extraction sorbent based on aptamers for the determination of ochratoxin A in red wine

A new solid phase extraction method based on aptamers, an oligosorbent, was developed and applied to the determination of ochratoxin A (OTA) from red wine. Two solid supports were chosen to immobilize OTA aptamer by covalent binding (cyanogen bromide-activated sepharose) or noncovalent binding (streptavidin-activated agarose). The resulting oligosorbents were evaluated in terms of retention, selectivity, and capacity. To assess the selectivity of the resulting oligosorbents, control supports made only of a solid support without immobilized aptamers were simultaneously studied. After optimization of the selective extraction procedure, extraction recoveries close to 100% were obtained on both materials. No retention was observed on the control supports. A similar capacity was also found for both oligosorbents. However, the immobilization by covalent bonding appeared more robust for the determination of OTA in the wine. A conventional sorbent and an immunoaffinity column were also applied to the determination of OTA in red wine to compare the potential of the various approaches for the treatment of such complex samples.     

硅基芯片表面化学性质对蛋白质固定化的影响

制备蛋白质芯片的关键在于将蛋白质固定到芯片表面并保持其生物学活性.本实验中,我们分别采用物理吸附、直接化学固定、加入间隔臂化学固定和生物亲和作用固定的方法将癌胚抗原(CEA)抗体固定到硅基芯片的二氧化硅表面.基于抗原-抗体的特异性相互作用,利用双抗体夹心酶联免疫法(ELISA)评价各种方法固定抗体的效果.实验结果表明,在修饰有氨基的表面采用戊二醛作为偶联试剂固定CEA抗体具有最高的偶联效率,引入多聚赖氨酸(poly-L-lysine)作为间隔臂可以显著增强固定效果,并可进一步降低非特异性吸附.而利用生物亲和作用固定CEA抗体也可获得较好的固定效果,但是非特异性吸附较严重.     

Synthesis and Characterization of Bis-1,2,3-Triazole Ligand and its Corresponding Copper Complex for the Development of Electrochemical Affinity Biosensors

The bis-triazole ligand and its corresponding copper complexes were synthesized and characterized for the first time and proposed as new labels for the development of electrochemical aptasensors. The bis-triazole ligand was prepared from methyl 1,6-heptadiyne-4-carboxylate and 2-(azidomethyl)phenol using classical CuAAC in presence of different copper salts. The X-ray structure of bis-triazole showed a symmetry center (C1). UV-Vis and X-band EPR spectra showed that the coordination capacity of the bis-triazole ligand was improved in the presence of triethylamine due to deprotonation of the triazole and phenolate moieties. After complexation with copper, the obtained complex was successfully attached to an anti-estradiol aptamer through thiol-maleimide coupling, and the resulting labelled aptamer was immobilized on a carbon screen-printed electrode by carbodiimide coupling. The electrochemical response of the resulting sensor was shown to decrease in the presence of estradiol, demonstrating that the developed complexes can be applied for the development of aptasensors.