Field‐Effect Nanoparticle‐Based Glucose Sensor on a Chip: Amplification Effect of Coimmobilized Redox Species

A capacitive EIS (electrolyte‐insulator‐semiconductor) structure was modified with gold nanoparticles together with glucose oxidase and used as field‐effect‐based glucose biosensor using the constant capacitance mode. Co‐immobilization of ferrocene redox species resulted in a two‐fold increase of the biosensor sensitivity. The effect was explained by the hydrogen peroxide‐mediated oxidation of ferrocene resulting in a pool of charged species at the interface increasing the sensor response towards glucose. The studied approach was suggested as a general means to amplify signals from Si chip‐based field‐effect enzyme biosensors.     

Enzyme Deposition by Polydimethylsiloxane Stamping for Biosensor Fabrication

High‐performance biosensors were fabricated by efficiently transferring enzyme onto Pt electrode surfaces using a polydimethylsiloxane (PDMS) stamp. Polypyrrole and Nafion were coated first on the electrode surface to act as permselective films for exclusion of both anionic and cationic electrooxidizable interfering compounds. A chitosan film then was electrochemically deposited to serve as an adhesive layer for enzyme immobilization. Glucose oxidase (GOx) was selected as a model enzyme for construction of a glucose biosensor, and a mixture of GOx and bovine serum albumin was stamped onto the chitosan‐coated surface and subsequently crosslinked using glutaraldehyde vapor. For the optimized fabrication process, the biosensor exhibited excellent performance characteristics including a linear range up to 2 mM with sensitivity of 29.4±1.3 μA mM⁻¹ cm⁻² and detection limit of 4.3±1.7 μM (S/N=3) as well as a rapid response time of ∼2 s. In comparison to those previously described, this glucose biosensor exhibits an excellent combination of high sensitivity, low detection limit, rapid response time, and good selectivity. Thus, these results support the use of PDMS stamping as an effective enzyme deposition method for electroenzymatic biosensor fabrication, which may prove especially useful for the deposition of enzyme at selected sites on microelectrode array microprobes of the kind used for neuroscience research in vivo .     

A Neural Network Model in the Calibration of Glucose Sensor Based on the Immobilization of Glucose Oxidase into Polypyrrole Matrix

The immobilization of enzymes on an electrode surface is of great importance in bioelectrochemistry. The entrapment of enzymes into a polymer matrix is simple and a speedy technique for the production of biosensors. This procedure of enzyme immobilization by electropolymerization has a great significance in fabrication of micro sensors in the preparation of multiplayer devices. In current study, glucose oxidase enzyme that is specific for the glucose determination was entrapped into polypyrrole matrix containing p‐benzoquinone in PIPES buffer and glucose sensitivity of the biosensor was investigated. Then, artificial neural network analysis was done for the nonlinear calibration plot. This implementation can be used for the sensor failure detection, as well. The estimation power of the neural network used in the direct and inverse calibration modelling was examined by statistical methods. It presented the good performance for the estimation power.     

A novel nanocomposite matrix based on graphene oxide and ferrocene-branched organically modified sol–gel/chitosan for biosensor application

A novel platform for the fabrication of a glucose biosensor was successfully constructed by entrapping glucose oxidase (GOD) in a ferrocene (Fc)-branched organically modified silica material (ormosil)/chitosan (CS)/graphene oxide (GO) nanocomposite. The morphology, structure, and electrochemistry of the nanocomposite were characterized by transmission electron microscopy, X-ray powder diffraction, UV–vis spectroscopy, Fourier transform infrared spectroscopy, and electrochemical techniques. Results demonstrated that the proposed electrochemical platform not only provided an excellent microenvironment to maintain the bioactivity of the immobilized enzyme, but also effectively prevented the leakage of both the enzyme and mediator from the matrix and retained the electrochemical activity of Fc. Furthermore, dispersing GO within the Fc-branched ormosil/CS matrix could significantly improve the stability of GO and make it exhibit a positive charge, which was more favorable for the further immobilization of biomolecules, such as GOD, with higher loading. Moreover, it could also improve the conductivity of the matrix film and facilitate the electron shuttle between the mediator and electrode. Under optimal conditions, the designed biosensor to glucose exhibited a wide and useful linear range of 0.02 to 5.39 mM with a low detection limit of 6.5 μM. The value of K _M ^app was 4.21 mM, indicating that the biosensor possesses higher biological affinity to glucose. The present approach could be used efficiently for the linkage of other redox mediators and immobilize other biomolecules in the process of fabricating novel biosensors.     

A Nanocomposite Chitosan Based on Ferrocene‐Modified Silica Nanoparticles and Carbon Nanotubes for Biosensor Application

A novel amperometric biosensor for glucose was developed by entrapping glucose oxidase (GOD) in a chitosan composite doped with ferrocene monocarboxylic acid‐aminated silica nanoparticles conjugate (FMC‐ASNPs) and multiwall carbon nanotubes (MWNTs). The entrapped FMC‐ASNPs conjugate performed excellent redox electrochemistry and the presence of MWNTs improved the conductivity of the composite film. This matrix showed a biocompatible microenvironment for retaining the native activity of the entrapped GOD and was in favor of the accessibility of substrate to the active site of GOD, thus the affinity to substrates is improved greatly. Under optimal conditions this biosensor was able to detect glucose with a detection limit of 10 μM (S/N=3) in the linear range of 0.04 to 6.5 mM. The proximity of these three components FMC‐ASNPs, MWNTs and GOD enhanced the electron transfer between the film and electrode. This composite film can be extended to immobilize other enzymes and biomolecules, which will greatly facilitate the development of biosensors and other bioelectrochemical devices.     

二茂铁功能化Fe3O4/碳纳米管/壳聚糖复合膜葡萄糖生物传感电极的研究

采用交联法制备了羧基二茂铁功能化Fe₃O₄纳米粒子（FMC-AFNPs）复合材料,并将该复合纳米材料与多壁碳纳米管（MWNTs）、壳聚糖（CS）及葡萄糖氧化酶（GOD）混合修饰于自制的磁性玻碳基底(MGC)表面,制备了GOD/FMC-AFNPs/MWNTs/CS复合膜生物传感器电极. 实验结果表明,FMC-AFNPs复合材料有效地克服了二茂铁在电极表面的泄漏,且FMC-AFNPs/MWNTs/CS复合膜良好的生物兼容性较大地改善了固定化GOD的生物活性. MWNTs具有良好的导电性和大比表面积,在修饰膜内可作为电子传递“导线”,极大地促进电极的电子传递速率,提高电极的电催化活性和灵敏度. 该电极的葡萄糖检测的线性范围为1.0×10^-5 ~ 6.0×10^-3 molL^-1,检测限为3.2×10^-6 mmolL^-1（S/N=3）,表观米氏常数为5.03×10^-3 mmolL^-1,且有较好的稳定性和重现性.     

生物/化学同步聚合法制备纤维蛋白纳米复合物及传感研究

本文以有效提高生物分子包埋率为目的,基于生物/化学同步聚合的新方法制备了一种新型纤维蛋白聚合物基纳米复合物,并研究了该复合物修饰电极的传感性能。该方法在凝血仿生聚合的同时,采用NaAuCl4作为氧化剂化学氧化聚合生成聚多巴胺(PDA),在PDA膜内原位合成纳米金(AuNPs),同时在PDA-纤维蛋白凝胶生长时包埋葡萄糖氧化酶(GOx)。生物/化学同步聚合法操作简单,条件温和。该纳米复合物引入了AuNPs的优异性质,有效提升了GOx的包埋量,所制电化学生物传感器对葡萄糖的检测灵敏度高达117μA/(cm2·mmol/L),检测限为57nmol/L。     

Parallel synthesis of libraries of anodic and cathodic functionalized electrodeposition paints as immobilization matrix for amperometric biosensors

The integration of flexible anchoring groups bearing imidazolyl or pyridyl substituents into the structure of electrodeposition paints (EDP) is the basis for the parallel synthesis of a library containing 107 members of different cathodic and anodic EDPs with a high variation in polymer properties. The obtained EDPs were used as immobilization matrix for biosensor fabrication using glucose oxidase as a model enzyme. Amperometric glucose sensors based on the different EDPs showed a wide variation in their sensor characteristics with respect to the apparent Michaelis-Menten constant (KM(app)) representing the linear measuring range and the maximum current (Imax(app)). Based on these results first assumptions concerning the impact of different side chains in the EDP on the expected biosensor properties could be obtained allowing for an improved rational optimization of EDPs used as immobilization matrix in amperometric biosensors.     

New Carbosilane Polymers with Interacting Ferrocenes as Support and Bioelectrocatalysts of Oxidases to Develop Versatile and Specific Amperometric Biodevices

In this work, the bioelectrocatalytical properties and kinetic characteristics of new oxidase amperometric biosensors based on two different ferrocene functionalized carbosilane polymers, polydiallylmethylsilane (PDAMS) and polymethyldiundecenylsilane (PMDUS) are described. In the development of these biodevices, glucose oxidase has been used as example of oxidase enzyme, and two different immobilization procedures have been studied. The polymer-modified electrodes act as efficient transducers for glucose sensing in anodic and cathodic aerobic conditions and also in anodic anaerobic conditions, and this fact turns them into useful devices for a wide field of applications. PMDUS has shown to be the bioelectrocatalyst with best kinetic and analytical properties in aerobic media while PDAMS was better in anaerobic conditions. The best aerobic biosensor developed displayed a strictly linear range from 0 to 3.0?mM, a detection limit of 7.8???M and a response time less than 2?s in an ascorbate interference free work potential interval. The apparent Michaelis?CMenten constant was calculated to be 1.36?mM according to the Lineweaver?CBurk equation.     

Electrochemical study of mono-6-thio-β-cyclodextrin/ferrocene capped on gold nanoparticles: Characterization and application to the design of glucose amperometric biosensor

A novel amperometric glucose sensor based on inclusion complex of mono-6-thio-β-cyclodextrin/ferrocene capped on gold nanoparticles (GNPs/CD-Fc) and glucose oxidase (GOD) was described. The inclusion complex of mono-6-thio-β-cyclodextrin/ferrocene capped on gold nanoparticles played an effective role of an electron shuttle and allowed the detection of glucose at 0.25 V (versus SCE), with dramatically reduced interference from easily oxidizable constituents. The sensor (GNPs/CD-Fc/GOD) showed a relatively fast response time (5 s), low detection limit (15 μM, S/N = 3), and high sensitivity (ca. 18.2 mA M⁻¹ cm⁻²) with a linear range of 0.08-11.5 mM of glucose. The excellent sensitivity was possibly attributed to the presence of the GNPs/CD-Fc film that can provide a convenient electron tunneling between the protein and the electrode. In addition, the biosensor demonstrated high anti-interference ability, stability and natural life. The good stability and natural life can be attributed to the following two aspects: on the one hand, the fabrication process was mild and no damage was made on the enzyme molecule, on the other hand, the GNPs possessed good biocompatibility that could retain the bioactivity of the enzyme molecules immobilized on the electrode.     

亲水金和憎水二氧化硅纳米颗粒对葡萄糖生物传感器响应灵敏度的增强作用

用亲水金、憎水二氧化硅纳米颗粒固定葡萄糖氧化酶(GOD),采用聚乙烯醇缩丁醛(PVB)为辅助固酶膜基质来制备葡萄糖生物传感器,并考察了亲水金、憎水二氧化硅纳米颗粒对酶电极电流响应的影响.实验表明,引入纳米粒子可显著增强电极响应灵敏度.并对两种不同性质纳米颗粒所起作用的可能机理进行讨论,从理论和实验上证明了纳米颗粒对固定酶的作用.为制备有实用价值的葡萄糖生物传感器提供了可供参考的实验和理论依据.     

A glucose biosensor using methyl viologen redox mediator on carbon film electrodes

A new methyl viologen-mediated amperometric enzyme electrode sensitive to glucose has been developed using carbon film electrode substrates. Carbon film electrodes from resistors fabricated by pyrolytic deposition of carbon were modified by immobilization of glucose oxidase through cross-linking with glutaraldehyde in the presence of bovine serum albumin. The mediator, methyl viologen, was directly immobilised with the enzyme together with Nafion cation-exchange polymer. The electrochemistry of the glucose oxidase/methyl viologen modified electrode was investigated by cyclic voltammetry and by electrochemical impedance spectroscopy. The biosensor response to glucose was evaluated amperometrically; the detection limit was 20 μM, the linear range extended to 1.2 mM and the reproducibility of around 3%. When stored in phosphate buffer at 4 °C and used every day, the sensor showed good stability over more several weeks.     

A New Technique for Chemical Deposition of Pt Nanoparticles and its Applications on Biosensor Design

A new glucose biosensor design based on glucose oxidase (GOD) immobilized by polypyrrole has been described in this paper. The polymerization of pyrrole was initiated by a hexachloroplatinate which itself was reduced into Pt nanoparticles and thus served as a catalyst for the H₂O₂ oxidation. Properties of the produced GOD modified electrode were examined and the activity of the entrapped enzyme was determined by basic application on the amperometric detection of glucose. Much better results were found comparatively with the enzyme electrode for which the enzyme was entrapped by the electrochemically polymerized polypyrrole. This kind of technique for Pt nanoparticles deposition can be generalized to many cases where polypyrrole is used.     

Simple construction of an enzymatic glucose biosensor based on a nanocomposite film prepared in one step from iron oxide, gold nanoparticles, and chitosan

The one-step synthesis is reported of a nanofilm composed of iron oxide and gold nanoparticles in a chitosan matrix that can act as a novel matrix for the immobilization of glucose oxidase (GOx) to fabricate a glucose biosensor. The use for the composite film strongly increased the effective electrode surface for loading of GOx. The size and shape of the iron oxide nanoparticles were examined by transmission electron micrograph. Direct electron transfer and electrocatalysis by GOx was investigated via cyclic voltammetry and chronoamperometry. Under optimized conditions, the biosensor has a response time of 6?s and a linear response in the range between 3???M and 0.57?mM of glucose, with a detection limit of 1.2???M at a signal-to-noise ratio of 3. This novel and disposable mediatorless glucose biosensor may form the basis for a future mass-produced glucose biosensor.

Multi-walled carbon nanotubes for the immobilization of enzyme in glucose biosensors

A novel biosensor, comprised of electrode of gold/multi-walled carbon nanotubes–glucose oxidase (Au/MWNTs–GOD), has been developed. The MWNTs were produced by microwave plasma enhanced chemical vapor deposition. The enzyme of GOD was immobilized using MWNTs. Performance and characteristics of the fabricated glucose biosensor were assessed with respect to response time, detection limit, pH value and storage stability. The results show that the fabricated biosensor is sensitive and stable in detecting glucose, indicating that MWNTs are a good candidate material for the immobilization of enzyme in glucose biosensor construction.     

Potentiometric Cholesterol Biosensor Based on ZnO Nanowalls and Stabilized Polymerized Lipid Film

A novel potentiometric cholesterol biosensor was fabricated by immobilization of cholesterol oxidase into stabilized lipid films using zinc oxide (ZnO) nanowalls as measuring electrode. Cholesterol oxidase was incorporated into the lipid film prior polymerization on the surface of ZnO nanowalls resulting in a sensitive, selective, stable and reproducible cholesterol biosensor. The potentiometric response was 57 mV/ decade concentration. The sensor response had no interferences by normal concentrations of ascorbic acid, glucose, and urea, proteins and lipids. The present biosensor could be implanted in the human body because of the biocompatibility of the lipid film.     

Electrochemical polymerization of (2-dodecyl-4, 7-di (thiophen-2-yl)-2H-benzo[d][1,2,3] triazole): a novel matrix for biomolecule immobilization

A recently synthesized conducting polymer [poly(2-dodecyl-4,7-di(thiophen-2-yl)-2H-benzo[d][1,2,3]triazole (PTBT)] was tested as a platform for biomolecule immobilization. After electrochemical polymerization of the monomer (TBT) on graphite electrodes, immobilization of glucose oxidase (GOx,β-D-glucose: oxygen-1-oxidoreductase, EC 1.1.3.4) was carried out. To improve the interactions between the enzyme and hydrophobic alkyl chain on the polymeric structure, GOx and isoleucine (Ile) amino acid were mixed in sodium phosphate buffer (pH 7.0) with a high ionic strength (250 × 10(-3) M). The solution is then casted on the polymer film, and the amino groups in the protein structure were crosslinked using glutaraldehyde (GA) as the bifunctional agent. Finally, the surface was covered with a perm-selective membrane. Consequently, cross-linked enzyme crystal (CLEC) like assembles with regular shapes were observed after immobilization. Microscopic techniques such as scanning electron microscopy (SEM) and fluorescence microscopy were used to monitor the surface morphologies of both the polymer and the bioactive layer. Electrochemical responses of the enzyme electrodes were measured by monitoring O(2) consumption in the presence of glucose at -0.7 V. The optimized biosensor showed a very good linearity between 0.05 and 2.5 × 10(-3) M with a 52 s response time and a detection limit (LOD) of 0.029 × 10(-3) M to glucose. Also, kinetic parameters, operational and storage stabilities were determined. K(m) and I(max) values were found as 4.6 × 10(-3) M and 2.49 μA, respectively. It was also shown that no activity was lost during operational and storage conditions. Finally, proposed system was applied for glucose biomonitoring during fermentation in yeast culture where HPLC was used as the reference method to verify the data obtained by the proposed biosensor.     

Glucose Biosensor Based on the Fabrication of Glucose Oxidase in the Bio-Inspired Polydopamine-Gold Nanoparticle Composite Film

A highly efficient enzyme immobilization method has been developed for electrochemical biosensors using polydopamine films with gold nanoparticles (AuNPs) embedded. This simple enzyme fabrication method can be performed in very mild conditions and stored in a long time with high bioactivity. The fabricated amperometric glucose biosensor exhibited a high and reproducible sensitivity, wide linear dynamic range and low limit of detection (LOD) (0.1 μmol·L^?1). A low value of 1.5 mmol·L^?1 for the apparent Michaelis‐Menten constant K^app_M was obtained. The high sensitivity, wide linear range, good reproducibility and stability make this biosensor a promising candidate for portable amperometric glucose biosensor.     

Quinone‐Rich Poly(dopamine) Magnetic Nanoparticles for Biosensor Applications

Novel core‐shell quinone‐rich poly(dopamine)–magnetic nanoparticles (MNPs) were prepared by using an in situ polymerization method. Catechol groups were oxidized to quinone by using a thermal treatment. MNPs were characterized by using X‐ray diffraction, X‐ray photoelectron spectroscopy, atomic force microscopy, magnetic force microscopy, UV/Vis, Fourier‐transform infrared spectroscopy, and electrochemical techniques. The hybrid nanomaterial showed an average core diameter of 17 nm and a polymer‐film thickness of 2 nm. The core‐shell nanoparticles showed high reactivity and were used as solid supports for the covalent immobilization of glucose oxidase (Gox) through Schiff base formation and Michael addition. The amount of Gox immobilized onto the nanoparticle surface was almost twice that of the nonoxidized film. The resulting biofunctionalized MNPs were used to construct an amperometric biosensor for glucose. The enzyme biosensor has a sensitivity of 8.7 mA M ^?1 cm^?2, a low limit of detection (0.02 mM ), and high stability for 45 days. Finally, the biosensor was used to determine glucose in blood samples and was checked against a commercial glucometer.     

Plasma-Polymerized Thin Films for Enzyme Immobilization in Biosensors

Abstract

Polymer films deposited on thin film noble metal electrodes on silicon chips, utilizing plasma polymerization are shown to be suited for immobilization of enzymes. Glucose oxidase is covalently coupled via amino- or carboxyl-groups of polymer films made by plasma polymerization of 2-amino-benzotrifluoride, acrylic or methacrylic acid. The concentration of these active surface groups increases by after-treatment in an ammonia- or oxygen-plasma. A biosensor consisting of a thin film metal electrode, plasma polymer film and immobilized glucose oxidase shows an amperometric response to glucose with a fast response time.