芯片式流通池顺序注射可更新表面反射光谱法用于酶反应检测

将芯片式流通池顺序注射可更新表面反射光谱法用于酶反应检测。HRP催化H2O2氧化BPR底物的反应用于对H2O2的检测。此反应体系与葡萄糖氧化酶联用，用于对血清中葡萄糖的检测。     

Preparation of glucose-sensitive microcapsules with a porous membrane and functional gates

A glucose-sensitive microcapsule with a porous membrane and with linear-grafted polyacrylic acid (PAAC) chains and covalently bound glucose oxidase (GOD) enzymes in the membrane pores acting as functional gates was successfully prepared. Polyamide microcapsules with a porous membrane were prepared by interfacial polymerization, PAAC chains were grafted into the pores of the microcapsule membrane by plasma-graft pore-filling polymerization, and GOD enzymes were immobilized onto the PAAC-grafted microcapsules by a carbodiimide method. The release rates of model drug solutes from the fabricated microcapsules were significantly sensitive to the existence of glucose in the environmental solution. In solution, the release rate of either sodium chloride or VB(12) molecules from the microcapsules was low but increased dramatically in the presence of 0.2mol/L glucose. The prepared PAAC-grafted and GOD-immobilized microcapsules showed a reversible glucose-sensitive release characteristic. The proposed microcapsules provide a new mode for injection-type self-regulated drug delivery systems having the capability of adapting the release rate of drugs such as insulin in response to changes in glucose concentration, which is highly attractive for diabetes therapy.     

高性能自修复微胶囊预聚物组成的研究

为了指导高性能自修复微胶囊的制备研究, 利用偏光显微熔点仪、红外光谱和核磁共振氢谱定量研究了微胶囊预聚物组成随反应条件如反应温度、pH 值和甲醛-尿素物质的量比的变化. 研究结果表明, 升高体系温度和pH 值都会显著促进副反应的发生从而降低产物中二羟甲基脲的产率; 而提高甲醛-尿素的物质的量比, 二羟甲基脲的产率增加,同时三羟甲基脲的产率降低. 此外, 还研究了升温过程中反应体系的温度变化情况. 研究发现: 升温速率一定时, 反应体系的温度变化均匀, 没有温度骤变阶段.     

Sequential fluorometric quantification of γ-aminobutyrate and l-glutamate using a single line flow-injection system with immobilized-enzyme reactors

A single line flow-injection system with immobilized-enzyme reactors is proposed for the sequential quantification of γ-aminobutyrate (GABA) and l-glutamate. A co-immobilized l-glutamate oxidase and catalase reactor and an immobilized GABase reactor were introduced into the flow line in series. Sample and reagent were injected into the flow line using an open sandwich method. GABA was selectively detected by GABase when α-ketoglutarate at a high concentration and NADP⁺ were injected as the reagents with a sample. When GABA at a high concentration and NADP⁺ were injected as the reagents with a sample, l-glutamate only was determined by the series of enzymatic reactions. NADPH produced by the immobilized-enzyme reactors was monitored fluorometrically at 455 nm (excitation at 340 nm). Linear relationships between the responses and concentrations of GABA or l-glutamate were observed in the ranges of 5.0 × 10⁻⁶-5.0 × 10⁻⁴ M and 1.0 × 10⁻⁵-5.0 × 10⁻⁴ M, respectively. The relative standard deviations for ten successive injections were less than 2% at the 0.5 mM level. This analytical method was applied to the sequential quantification of GABA and l-glutamate that were produced and consumed, respectively, by lactic acid bacteria, and the results showed good agreement with those obtained using liquid chromatography.     

Composite poly(dimethylsiloxane)/glass microfluidic system with an immobilized enzymatic particle-bed reactor and sequential sample injection for chemiluminescence determinations

A three-layer poly(dimethylsiloxane) (PDMS)/glass microfluidic system for performing on-chip solid-phase enzymatic reaction and chemiluminescence (CL) reaction was used for the determination of glucose as a model analyte. A novel method for the immobilization of controlled-pore-glass based reactive particles on PDMS microreactor beds was developed, producing an on-chip solid-phase reactor that featured large reactive surface and low flow impedance. Efficient mixing of reagent/sample/carrier streams was achieved by incorporating chaotic mixer structures in the microfluidic channels. A conventional sequential injection (SI) system was adapted for direct coupling with the microfluidic system, and combined with hydrostatic delivery of reagents to achieve efficient and reproducible sample introduction at 10 μl levels. A detection limit of 10 μM glucose (3σ), and a precision of 3.1% RSD (n=7, 0.2 mM glucose) were obtained using the SI-microfluidic-CL system integrated with a glucose oxidase (GOD) reactor. Carryover was <5% at a throughput of 20 samples/h.     

Enzymatic in-capillary derivatization for glucose determination by electrophoresis with spectrophotometric detection

The following paper compares several procedures of in-capillary bienzymatic derivatization with regard to glucose determination with the use of glucose oxidase and horseradish peroxidase. The procedures discussed below include continuous contact in the capillary, plug-plug injection, and sequential injection with incubation in the capillary inlet. The reaction of hydrogen peroxide catalyzed by peroxidase was performed using two different substrates. The best results were achieved for nicotinamide adenine dinucleotide, reduced disodium salt (NADH) acting both as a chromogenic reagent and a substrate for peroxidase, while the method employed was sequential injection and incubation at the capillary inlet. The LOD was estimated to be 25 nM with a linear response up to 0.1 microM.     

模拟过氧化物酶催化性能的研究

过氧化物酶(POD)能催化H₂O₂氧化一系列氢供体(DH₂)转化成氧化型供体(D)。氢供体可以是邻联二茴香胺、4-氨基安替比林和苯酚及某些染料隐色体等。这类反应不仅可提供检测H₂O₂的灵敏方法,还可与产生H₂O₂的其它酶反应系统联用,测定葡萄糖、半乳糖、氨基酸、尿酸及胆醇等生物物质。     

On-line monitoring of glucose and penicillin by sequential injection analysis

A sequential injection analysis (SIA) system has been developed for on-line monitoring of glucose and penicillin during cultivations of the filamentous fungus Penicillium chrysogenum. The SIA system consists of a peristaltic pump, an injection valve, two piston pumps, two multi-position valves and a detector. The glucose analyzer is based on an enzymatic reaction using glucose oxidase, which converts glucose to glucono-lactone with formation of hydrogen peroxide and subsequent detection of H₂O₂ by a chemiluminescence reaction involving luminol. The penicillin analysis is based on formation of penicilloic acid by penicillinase. Penicilloic acid is detected either by a chemiluminescence method or by a decolorization method. In the chemiluminescence method the penicilloic acid is quantified by its quenching effect on the chemiluminescence signal obtained when luminol reacts with iodine. In the decolorization method the penicilloic acid is detected spectrophotometrically by the decrease in the absorbance of an iodine-starch complex.     

Fed-batch Production of Gluconic Acid by Terpene-treated Aspergillus niger Spores

Aspergillus niger spores were used as catalyst in the bioconversion of glucose to gluconic acid. Spores produced by solid-state fermentation were treated with 15 different terpenes including monoterpenes and monoterpenoids to permeabilize and inhibit spore germination. It was found that spore membrane permeability is significantly increased by treatment with terpenoids when compared to monoterpenes. Best results were obtained with citral and isonovalal. Studies were carried out to optimize spores concentration (10(7)-10(10) spores/mL), terpene concentrations in the bioconversion medium and time of exposure (1-18 h) needed for permeabilization of spores. Fed-batch production of gluconate was done in a bioreactor with the best conditions [10(9) spores/mL of freeze-thawed spores treated with citral (3% v/v) for 5 h] followed by sequential additions of glucose powder and pH-regulated with a solution containing 2 mol/L of either NaOH or KOH. Bioconversion performance of the spore enzyme was compared with the commercial glucose oxidase at 50, 60, and 70 degrees C. Results showed that the spore enzyme was comparatively stable at 60 degrees C. It was also found that the spores could be reutilized for more than 14 cycles with almost similar reaction rate. Similar biocatalytic activity was rendered by spores even after its storage of 1 year at -20 degrees C. This study provided an experimental evidence of the significant catalytic role played by A. niger spore in bioconversion of glucose to gluconic acid with high yield and stability, giving protection to glucose oxidase.     

Microfluidic paper-based chemiluminescence biosensor for simultaneous determination of glucose and uric acid

In this study, a novel microfluidic paper-based chemiluminescence analytical device (μPCAD) with a simultaneous, rapid, sensitive and quantitative response for glucose and uric acid was designed. This novel lab-on-paper biosensor is based on oxidase enzyme reactions (glucose oxidase and urate oxidase, respectively) and the chemiluminescence reaction between a rhodanine derivative and generated hydrogen peroxide in an acid medium. The possible chemiluminescence assay principle of this μPCAD is explained. We found that the simultaneous determination of glucose and uric acid could be achieved by differing the distances that the glucose and uric acid samples traveled. This lab-on-paper biosensor could provide reproducible results upon storage at 4 °C for at least 10 weeks. The application test of our μPCAD was then successfully performed with the simultaneous determination of glucose and uric acid in artificial urine. This study shows the successful integration of the μPCAD and the chemiluminescence method will be an easy-to-use, inexpensive, and portable alternative for point-of-care monitoring.     

Bienzyne Electrodes for ATP,NAD+, Starch and Disaccharides Based on a Glucose Sensor

Abstract

A glucose measuring device based on the oxidation of glucose by glucose oxidase and an amperometric kinetic detection was developed. The characteristics obtained with this instrument are comparable with the present glucose instruments but the stability of the enzyme membrane is better and the measuring frequency is higher. In order to expand the applicability of this device to other substrates there was developed a family of bioenzyme electrodes. Enzymes producing glucose as enzymes consuming glucose in addition to glucose oxidase were used.

For determination of peroxidase substrates besides a peroxidase-catalase electrode a three-enzyme system consisting of glucose oxidase, peroxidase and catalase was used.     

新型微胶囊负载环多胺锰配合物的催化氧化性能

采用乳化溶剂蒸发的方法制备了负载型催化剂环多胺锰/乙基纤维素微胶囊(MnAcL-EC), 并确认了MnAcL在微胶囊内负载后结构的完整性, 对其进行了形貌结构表征, MnAcL-EC微胶囊负载型催化剂内部呈特殊的多芯结构. 该催化剂在活性蓝(C.I. Reactive Blue 49)的氧化反应中表现出了优异的催化性能. 催化反应后微胶囊粒径增大, 球体表面孔道增多; 元素分析结果显示, 微胶囊内负载的MnAcL在催化反应后几乎没有减少, 表明负载后的MnAcL是在微胶囊内部催化了外界底物分子的氧化反应. 所制备的MnAcL-EC微胶囊具备很好的循环利用性, 可以有效减少催化活性组分的流失, 方便回收利用.     

Quinone-modified polymers as electron transfer relay systems in amperometric glucose sensors

A polysiloxane and an acrylonitrile–ethylene copolymer with covalently attached p-hydroquinone/benzoquinone moieties were prepared and tested as electron transfer relay systems in amperometric glucose biosensors. Using experiments involving cyclic voltammetry and stationary potential measurements, it was shown that the polysiloxane relay system can efficiently mediate electron transfer from reduced glucose oxidase to a conventional carbon-paste electrode. Sensors containing this polymeric relay system and glucose oxidase respond rapidly to low (<0.1 mm) glucose concentrations, with steady state current responses achieved in less than 1 min. The acrylonitrile–ethylene copolymer was found to be less efficient than the polysiloxane system at mediating the electron transfer from reduced glucose oxidase to the electrode. The dependence of the sensor response on the nature of the polymer backbone is discussed.     

Redox modification of proteins using sequential-parallel electrochemistry in microtiter plates

Redox modification of proteins has frequently been used to improve the electron-transfer properties in amperometric biosensors. One approach is the coordinative labelling of histidine residues with metal complexes like [Ru(bpy)2Cl2] and [Ru(bpy)2CO3]. Although the reaction depends on a variety of parameters no detailed optimisation of these modification procedures has been done, most probably due to the complexity of the parameter matrix and the expected differences for any individual protein. A multi electrode sequential analyser (MESA) system has been developed which allows one to follow in a sequential-parallel scheme a number of modification reactions by performing electrochemical measurements such as cyclic voltammetry or differential pulse voltammetry in individual wells of a conventional microtiter plate. Using this system, the ligand exchange reaction leading to the binding of the Ru-complex to histidine residues could be investigated with imidazole as a model compound. Furthermore, the selective labelling of soluble PQQ (pyrrolochinolinquinone)-dependent glucose dehydrogenase (sGDH) and glucose oxidase (GOx) with Ru complexes could be optimised and the electrochemical and biological properties of the obtained 'electroenzymes' were examined.     

Electrochemical Redundant Microsensor Arrays for Glucose Monitoring with Patterned Polymer Films

Redundant microsensor arrays for glucose sensing were fabricated using photopolymerization of poly(ethylene glycol) diacrylate (PEG‐DA) with 2‐hydroxy‐2‐methyl phenyl‐propanone as photoinitiator to encapsulate the enzyme glucose oxidase. Silicon micro fabrication technologies were used to fabricate microelectrode sensor arrays on flexible polyimide sheets. These microarray sensors were individually addressable as observed using square‐wave voltammetry. Redox polymer, poly[4‐vinylpyridine Os(bipyridine)₂Cl]‐co‐ethylamine, was first immobilized on the electrode surface and then glucose oxidase was entrapped in PEG‐DA hydrogels. The redox polymer was found to exchange electrons with glucose oxidase in biocompatible PEG‐DA hydrogels. The entrapped glucose oxidase was found to respond linearly to glucose in solution (0–20 mM) as determined using square‐wave voltammetry.     

Highly sensitive glucose sensor based on work function changes measured by an EMOSFET

In this paper, glucose is potentiometrically measured by using a specific field effect transistor, the EMOSFET. In this device, glucose oxidase is immobilized within a bovine serum albumin matrix, using glutaraldehyde. This layer is deposited on the top of an electroactive Os-polyvinylpyridine layer containing horseradish peroxidase, which is used as the gate material of the FET. The basic principle of the sensor is to measure the glucose concentration by means of measuring the change in the work function of the electroactive gate due to its redox reaction with the H2O2, generated by the reaction between glucose and glucose oxidase. The change in the work function can be detected as a change in the threshold voltage of the FET. Moreover, a measuring mode called "constant current potentiometry" has been applied to improve the sensitivity of the sensor. The sensitivity of the sensor working in this mode is found to be much higher than the Nernstian value. The experimental results show that the detection limit of the sensor can be tuned depending on the value of the applied current and the glucose oxidase concentration in the gate.     

Development of an on-line immobilized-enzyme reversed-phase HPLC method for protein digestion and peptide separation

This paper describes use of a novel glass bead-based immobilized-enzyme micro column for simple and swift on-line protein digestion then peptide separation by reversed-phase HPLC. The inexpensive and easily made immobilized-enzyme micro column was prepared from aminopropyl controlled-pore glass that was reacted first with glutaraldehyde then with trypsin in the presence of phosphate buffer. Tryptic digestion of bovine serum albumin (BSA) was achieved simply by passing pretreated protein solution through the laboratory made immobilized-trypsin column; the tryptic fragments were then separated by reversed-phase HPLC. The peptide separation was found to be identical to separation of a sample which had undergone conventional enzymatic protein digestion in solution. Digestion of BSA by the immobilized-trypsin column decreased with increasing flow rate of the solution through the column, and 1.0 μL min⁻¹ was found to be the optimum flow rate for on-line protein digestion with our system. It was also found that the sample required pretreatment with urea before injection, because of a change in the properties of the protein in the presence of urea, and the immobilized-trypsin column lost its function in the presence of acetonitrile. This on-line proteomics system enables simple and rapid protein digestion and was successfully applied to partially micro two-dimensional (2D) chromatographic separation of proteins.     

Avidin/PSS membrane microcapsules with biotin-binding activity

Polyelectrolyte microcapsules with avidin-poly(styrene sulfonate) (PSS) membrane were prepared by a layer-by-layer deposition technique. The uptake and release of biotin-labeled fluorescein (b-FITC) as well as immobilization of biotin-labeled glucose oxidase (b-GOx) to the microcapsule were studied. The polyelectrolyte microcapsules were prepared by coating the surface of calcium carbonate (CaCO(3)) microparticles with an avidin/PSS multilayer membrane, followed by dissolution of CaCO(3) core in an ethylenediaminetetraacetic acid solution. Inner and outer poly(allylamine)/PSS films were required to isolate the microcapsules, whereas microcapsules could not be formed without the support. The uptake of b-FITC into the microcapsule was highly enhanced through a strong binding of b-FITC to avidin as compared with the uptake of biotin-free FITC. Release of b-FITC from the microcapsule was accelerated upon addition of biotin due to a competitive binding of the added biotin to the binding site of avidin. Similarly, the surface of microcapsule was modified with b-GOx with retaining its catalytic activity.     

Flow Injection Analysis of Glucose by Fiber Optic Chemiluminescence Measurement

Abstract

A flow injection system was developed for the determination of glucose based on fiber optic chemiluminescence measurements. The hydrogen peroxide produced from the glucose oxidase catalyzed reaction was quantified by measuring the intensity of luminol chemiluminescence in the presence of excess ferricyanide. Glucose oxidase was immobilized on aminopropyl glass using glutaraldehyde and packed in a reactor. The chemiluminescence was transported to the detector using an optical fiber. The system responds linearly to glucose in the concentration range 0.20 mM up to 2.5 mM, with a relative precision of 5%. Several fruit juices were analyzed for their glucose content and the results were compared with a standard AOAC procedure.     

氮、铁共掺杂碳纳米粒子的制备及在过氧化氢和葡萄糖检测中的应用

以L-酒石酸和一水柠檬酸为混合碳源,以乙二胺为氮源和聚合试剂,并添加六水三氯化铁,通过一锅溶剂热法合成了氮、铁共掺杂碳纳米粒子(N/Fe-CNPs),采用制备的N/Fe-CNPs模拟过氧化物酶催化过氧化氢(H₂O₂)氧化3,3',5,5'-四甲基 产生可溶性的蓝色产物,联合葡萄糖氧化酶建立了测定H₂O₂和葡萄糖含量的新方法。 结果显示:H₂O₂及葡萄糖的浓度与反应体系的吸光度呈良好的线性关系,H₂O₂的线性范围为0.2~20 μmol/L,葡萄糖的线性范围为0.1~1.0及1.0~80 μmol/L,最低检出限分别可达42.5和76.1 nmol/L。