Nylon tube-immobilized creatinine iminohydrolase and glutamate dehydrogenase in serum and urine creatinine analysis

Immobilized enzyme nylon-tube reactors incorporating creatinine iminohyrolase (CI) and glutamate dehydrogenase (GDH) were used to assay creatinine in serum and urine. Optimum substrate concentrations for the assay were determined. The reactors were incorporated into a continuous flow system for creatinine analysis. The method was evaluated with respect to linearity, sample interaction, precision, accuracy, and analytical recovery. Comparison studies were carried out with a standard Jaffé method and the effect of interfering substances was investigated. From the results obtained, it was concluded that the assay was suitable as a simple, reliable, and specific method for serum and urine creatinine determinations.     

开管柱固定化葡萄糖氧化酶反应器的制备及其在流动注射分析中的应用

本文将葡萄糖氧化酶化学键合到粗糙化的玻璃毛细管内壁上,用开管柱固定化酶反应器-安培检测器进行葡萄糖的流动注射分析。讨论了流速对流动注射分析体系峰电流和分散度的影响,提出了测量开管柱固定化酶表观活力的方法。     

Enzymatic Assay by Flow Injection Analysis with Detection by Chemiluminescence: Determination of Glucose,Creatinine, Free Cholesterol and Lactic Acid Using an Integrated Fia Microconduit

Abstract

A miniaturized flow injection system for the determination of D-glucose, L-lactic acid, creatinine and free cholesterol is described. All substrates are degraded enzymatically by means of oxidases which, along with ancillary coenzymes (creatinine assay), are immobilized on controlled porosity glass and incorporated into small PVC column reactors. The hydrogen peroxide generated by the individual oxidases is determined by chemiluminescence with an alkaline reagent containing luminol and hexacyanofer rate (III). The injection valve, flow channels, enzyme reactor and light detector are integrated into a FIA microconduit. The detection limits were 0.03 mg glucose/dl, 0.03 mg lactate/dl, 0.3 mM creatinine and 0.5 mg cholesterol/dl. The enzyme reactors all showed little change in activity over a 3 months period of operation and were found fully compatible with serum samples.     

Capillary electrophoresis integrated immobilized enzyme reactor for kinetic and inhibition assays of β‐secretase as the Alzheimer's disease drug target

Capillary electrophoresis integrated immobilized enzyme reactors are becoming an increasingly popular alternative for enzyme kinetic and inhibition assays thanks to their unique set of features including cost effectiveness, repeated use of the enzyme, minuscule sample consumption, rapid analysis time and easy automation. In this work we present the development and application of a capillary electrophoresis integrated immobilized enzyme reactor based on magnetic particles for kinetic and inhibition studies of β‐secretase, a key enzyme in the development of Alzheimer's disease and a promising drug target. We document the optimization of the immobilization procedure, characterization of immobilized β‐secretase, optimization of a mutually compatible incubation protocol and separation method as well as the production of the capillary electrophoresis integrated immobilized enzyme reactor. The applicability of the capillary electrophoresis integrated immobilized enzyme reactor was demonstrated by kinetic assay with an unlabelled substrate and by inhibition assays using three structurally different reference inhibitors. The resulting kinetic and inhibition parameters clearly support the applicability of the herein presented method as well as document the fundamental phenomena which need to be taken in account when comparing the results to other methods.     

Determination by the enzyme thermistor of cellobiose formed on degradation of cellulose

A calorimetric assay procedure for the determination of cellobiose has been developed. The cellobiose is hydrolyzed by β-glucosidase and the glucose formed is measured calorimetrically by an enzyme thermistor containing co-immobilized glucose oxidase and catalase. The system was optimized with regard to the arrangement of the enzymes, the pH-dependence of the separate enzymic steps, and of the total system. By placing the β-glucosidase in a precolumn that could be switched in and out of the flow through the enzyme thermistor, both cellobiose and glucose present in the sample could be determined. The performance with standard solutions and with crude samples from cellulose degradation experiments was investigated.     

基于DNA定向固定化技术构建毛细管固定化酶微反应器的研究进展

生物酶影响着物质代谢和质能转换等生命活动,生物体内某些酶的活性变化会导致疾病的发生。发展新型的酶分析方法对深刻理解生物代谢过程、疾病诊断和药物研发等具有重要意义。毛细管电泳（CE）具有分离效率高、分析速度快、操作简单和样品消耗少以及可与多种检测手段联用等优点,在酶分析研究中越来越受到关注。CE酶分析主要包括离线和在线两种模式,其中,固定化酶微反应器与毛细管电泳联用（CE-IMER）的在线酶分析已经成为主要的酶分析方法之一。CE-IMER充分结合了固定化酶和CE的优势,将游离酶固定在毛细管内,不仅可以显著提高酶的稳定性和重复使用性,而且可以实现纳升规模溶液的自动化酶分析,进而显著降低酶分析成本。目前已有大量方法制备IMER用于CE酶分析,然而如何构建性能良好、可再生使用、酶固载量大、自动化程度高的CE-IMER一直是该领域重点研究的问题。DNA定向固定化技术（DDI）可以充分利用DNA分子的碱基互补配对（A-T,C-G）,在温和的生理条件下特异性固定生物大分子。由于短链双螺旋DNA分子具有较强的机械刚性和物理化学稳定性,通过DDI将酶固定在载体表面,有利于降低传质阻力,提高酶与底物的接触能力,进而促进酶促分析过程。该文主要综述了利用DDI构建新型IMER在CE酶分析中的应用现状,并对其未来发展进行了展望。     

Immobilized enzyme reactor chromatography: optimization of protein retention and enzyme activity in monolithic silica stationary phases

Our group recently reported on the application of protein-doped monolithic silica columns for immobilized enzyme reactor chromatography, which allowed screening of enzyme inhibitors present in mixtures using mass spectrometry for detection. The enzyme was immobilized by entrapment within a bimodal meso/macroporous silica material prepared by a biocompatible sol-gel processing route. While such columns proved to be useful for applications such as screening of protein-ligand interactions, significant amounts of entrapped proteins leached from the columns owing to the high proportion of macropores within the materials. Herein, we describe a detailed study of factors affecting the morphology of protein-doped bioaffinity columns and demonstrate that specific pH values and concentrations of poly(ethylene glycol) can be used to prepare essentially mesoporous columns that retain over 80% of initially loaded enzyme in an active and accessible form and yet still retain sufficient porosity to allow pressure-driven flow in the low μL/min range. Using the enzyme γ-glutamyl transpeptidase (γ-GT), we further evaluated the catalytic constants of the enzyme entrapped in capillary columns with different silica morphologies as a function of flowrate and backpressure using the enzyme reactor assay mode. It was found that the apparent activity of the enzyme was highest in mesoporous columns that retained high levels of enzyme. In such columns, enzyme activity increased by ∼2-fold with increases in both flowrate (from 250 to 1000 nL/min) and backpressure generated (from 500 to 2100 psi) during the chromatographic activity assay owing to increases in k_cat and decreases in K_M, switching from diffusion controlled to reaction controlled conditions at ca. 2000 psi. These results suggest that columns with minimal macropore volumes (<5%) are advantageous for the entrapment of soluble proteins for bioaffinity and bioreactor chromatography.     

固定化酶纳升微反应器用于痕量蛋白质快速肽谱分析的研究

利用毛细管作为酶固定化的载体,将酶直接键合到毛细管内壁,制成毛细管纳升反应器,结合质谱分析水解产物,获得了蛋白质的肽谱.实验发现,以毛细管为反应器后,蛋白质肽谱分析所需量大大减少,只需10^-13mol,甚至几个10^-15mol的量就可满足分析要求.     

Diffusion and reaction in an immobilized enzyme starch saccharification catalyst

Effectiveness factors were predicted from measurements of basic parameters made on single oligosaccharides, and the prediction was compared to experimental effec tiveness factors for the reaction of each oligosaccharide in the immobilized enzyme catalyst. Kinetic parameters were obtained for the hydrolysis of each oligosaccharide catalyzed by soluble glucoamylase, and were fit with a subsite model equation capable of generalization to all sizes of oligosaccharide. Diffusion coefficients in free solution were determined from movement out of a capillary tube. Spatial characteristics of the immobilized enzyme bed were obtained from pulse response experiments, allowing the calculation of effective diffusivities. Experimental effectiveness factors plotted against modulus were in reasonable agreement with the predictions.     

Development of an In-Line Enzyme Reactor Integrated into a Capillary Electrophoresis System

The goal of this paper was to develop an in-line immobilized enzyme reactor (IMER) integrated into a capillary electrophoresis platform. In our research, we created the IMER by adsorbing trypsin onto the inner surface of a capillary in a short section. Enzyme immobilization was possible due to the electrostatic attraction between the oppositely charged fused silica capillary surface and trypsin. The reactor was formed by simply injecting and removing trypsin solution from the capillary inlet (~1–2 cms). We investigated the factors affecting the efficiency of the reactor. The main advantages of the proposed method are the fast, cheap, and easy formation of an IMER with in-line protein digestion capability. Human tear samples were used to test the efficiency of the digestion in the microreactor.     

Controllable and high-performance immobilized enzyme reactor: DNA-directed immobilization of multienzyme in polyamidoamine dendrimer-functionalized capillaries

In recent years, CE-integrated immobilized enzyme reactors (IMERs) for single-enzyme immobilization have attracted considerable attention. However, there has been little research on multienzyme immobilization in CE. Here, we introduce a method for fabricating a CE-integrated IMER, using DNA-directed immobilization to fix glucose oxidase and horseradish peroxidase in the capillary, which had been functionalized with polyamidoamine dendrimer (PAMAM). Owing to the reversibility of DNA hybridization, the reactor is capable of dynamic immobilization. Moreover, by introducing the PAMAM, the loading capacity of the IMER is greatly enhanced, and the PAMAM can spontaneously form complexes with DNA and then contribute to the efficiency and stability of the reactor. After 25 days storage, the prepared IMER ultimately retained approximately 70% of its initial activity. We also used the IMER to detect glucose, and the favorable linearity was obtained over the concentration range of 0.78–12.5 mM, with an LOD of 0.39 mM, demonstrating that the CE-integrated IMER can be applied to actual samples. We believe that this strategy can be extended to other multienzyme immobilization systems, and CE-integrated IMERs are potentially useful in a wide range of biochemical research applications.     

Immobilized‐enzyme reactors integrated with capillary electrophoresis for pharmaceutical research

Enzymes play an essential role in many aspects of pharmaceutical research as drug targets, drug metabolizers, enzyme drugs and more. In this specific field, enzyme assays are required to meet a number of specific requirements, such as low cost, easy automation, and high reliability. The integration of an immobilized‐enzyme reactor to capillary electrophoresis represents a unique approach to fulfilling these criteria by combining the benefits of enzyme immobilization, that is, increased stability and repeated use, as well as the minute sample consumption, short analysis time, and efficient analysis provided by capillary electrophoresis. In this review, we summarize, analyze, and discuss published works where pharmaceutically relevant enzymes were used to prepare capillary electrophoresis‐integrated immobilized‐enzyme reactors in an online manner. The presented assays are divided into three distinct groups based on the drug–enzyme relationship. The first, more extensively studied group employs enzymes that are considered to be therapeutic targets, the second group of assays present tools to assess drug metabolism and the third group assesses enzyme drugs. Furthermore, we examine various methods of enzyme immobilization and their implications for assay properties.     

Electrochemical Measurements of Glucose Using a Micro Flow‐Through Immobilized Enzyme Reactor

A new fast, cheap and efficient epoxy‐amine immobilized enzyme reactor (IMER) is demonstrated. Polyethyleneimine (PEI) was used as the curing agent of an epoxy resin (bisphenol‐A diglycidyl ether (BADGE)) in order to introduce a high number of reactive –NH₂ groups at the substrate. A ratio mixture of 3:2 PEI:BADGE (w/w) was shown to be the most suitable for curing, taking into account the number of immobilization sites and the resistance of the material towards channeling. Electrochemical measurements made by a three electrode system, adapted at the IMER, showed that the K_m value for immobilized glucose oxidase (GOx) was half the value commonly reported for GOx immobilized at PEI derived substrates. The IMER response decreased by around 41 % after one week of intense usage. Even so, the remaining activity was sufficient for quantifications of approximately 0.1 mmol L⁻¹, merely requiring a new calibration of the reactor before its utilization. The developed system was applied to D‐glucose quantification of beverage samples, requiring an injection volume of only 10 μL and a flow rate of 150 μL min⁻¹ (almost 60 samples per hour). Low detection and quantification limits (1.94 and 5.89 μmol L⁻¹, respectively) and a wide linear range (from 8 μmol L⁻¹ to 2 mmol L⁻¹) were also found, which are useful characteristics for quality control analysis.     

A Split-Flow Enzyme Thermistor

Abstract

The split-flow system is comprised of two identical micro-columns, one of which contains an immobilized enzyme preparation, the other an inert support material.

The heat produced in each column on introduction of a sample is measured with thermistors placed in these columns. The use of a reference column virtually eliminates the influence on the measurements of artifactual signals as unspecific heat, i.e., heat not produced by the enzymic reaction. The performance of the split-flow enzyme thermistor at a variety of pH's, ionic strengths or viscosities associated with the sample has been investigated and compared with previously described alternative enzyme thermistor arrangements. In this comparative study glucose at a concentration of 5 · 10^?4 M was used throughout. On passage through the imnobilized glucose oxidase preparation this solution gave rise to a heat change At of about 0.01°C. The insensitivity of the system described herein towards such variations makes it particularly suitable for the analysis of metabolities present in crude solutions such as urine and skim-milk.     

基于中心辐射树枝状介孔二氧化硅构筑CPO固定化酶反应器及应用

首先制备粒径均匀的具有开放的三维中心辐射树枝状结构的介孔二氧化硅(DSP)粒子, 再通过静电相互作用在孔道内负载氯过氧化物酶(CPO)构筑了CPO@DSP固定化酶反应器. 通过改变硅源正硅酸乙酯(TEOS)和模板剂十六烷基三甲基氯化铵(CTAC)的浓度调控孔径大小, 研究了孔径对固定化酶反应器催化活性的影响; 同时基于酶促反应动力学分析探讨了孔道内酶催化反应的限域效应, 并进一步在CPO@DSP表面包覆海藻酸钠(SA)水凝胶薄膜以抑制酶反应器在使用过程中酶分子的泄露, 所得SA-CPO@DSP固定化酶反应器的重复使用性显著提高, 循环使用10次后, 仍能保持90%以上的催化活性. 将SA-CPO@DSP酶反应器用于环境水体中残留抗生素左氧氟沙星的降解, 对100 μg/mL的底物在25 min内降解率可达88%以上; 将该反应器用于苯酚的视觉比色检测, 裸眼可检测到5 μmol/L的苯酚, 表明SA-CPO@DSP酶反应器在环境保护方面具有良好的应用前景.     

The effect of hydrogen ion production on the steady-state multiplicity of substrate-inhibited enzymatic reactions

The phenomenon of multiplicity is investigated for an isothermal continu ous stirred tank reactor (CSTR) in which an enzyme reaction producing hydrogen ions is taking place. The activity of the enzyme considered is sensitive to the hydrogen ion concentration and is inhibited by excess substrate. The enzyme is bound and the washout phenomenon is negligible. The investigation has uncovered a new type of hysteresis, consisting of a closed curve on the multiplicity diagram, and is disconnected from the rest of the multiplicity curve. This phenomenon has also been observed and analyzed by Uppal et al. (1) in their investigation of the non-isothermal, non-adiabatic (CSTR), and they have termed those closed curves “Isolas.” In the present paper we have elucidated the physical reason for the occurrence of those “Isolas” for the enzymatic reaction under consideration. We have also investigated the effect of different parameters on the appearance, disappearance, and size of the “Isolas.”     

Effect of enzyme concentration on the dynamic behavior of a membrane-bound enzyme system

The dynamic behavior of the reaction-diffusion system, composed of glucose oxidase (EC 1.1.3.4) immobilized at a uniform concentration in a membrane, used as a glucose electrode is represented by a diffusion equation with a nonlinear reaction-term in one-dimensional space. The mathematical model is analyzed by computer simulation, that is, numerical integration of the equation under various initial and boundary conditions, to examine the effect of enzyme concentration on the response characteristics (responsiveness and linearity in response) of the electrode. The analysis of the responses of the system to stepwise changes in the boundary value (glucose concentration in simple solution) infers that the enzyme concentration governs the patterns of the spatial distributions of the substrates (glucose and dissolved oxygen) in steady states and transient responses. It is also revealed that the response characteristics of the electrode are optimized with concentration of immobilized enzyme and that the system establishes the steady states at the same spatial distributions of the substrates, regardless of the boundary value. The diffusion of the substrates and the oxygen concentration also have significant effects on the response characteristics of the electrode.     

Analysis of a theoretical model for anisotropic enzyme membranes application to enzyme electrodes

A theoretical model of diffusion and reaction in an anisotropic enzyme membrane is presented with particular emphasis on the application of such membranes in enzyme electrodes. The dynamic response of systems in which the kinetics are linear, which comprises the practical operating regime for enzyme electrodes in analysis, is investigated via an analytic solution of the governing differential equations. The response is presented as a function of a single dimensionless group, Μ, that is the membrane modulus.     

Simultaneous flow-injection assay of creatinine and creatine in serum by the combined use of a 16-way switching valve, some specific enzyme reactors and a highly selective hydrogen peroxide electrode

Creatine and creatinine in serum were assayed simultaneously in a noble flow-injection system made up by a 16-way switching valve with two sample loops, three enzyme reactors positioned in a serial way, and a delay coil needed to separate two peaks corresponding to two sample portions injected simultaneously. A Nafion/poly(1,2-diaminobenzene) bilayer modified electrode was used to selectively detect the hydrogen peroxide generated as one of the end products in the last enzyme reactor, without any interferences from electroactive species (such as l-ascorbate and urate) and proteins present in the serum. Because two sample portions passed through the flow line with different residence time, two peaks were obtained. The first peak corresponded to creatine and the second peak to the total of creatine and creatinine. The maximum currents of both peaks were linearly related to the concentration of creatine and total of creatine and creatinine in the range of 1-100 μM, respectively; 20 samples h⁻¹ could be processed with an R.S.D. <1.6%.     

Determination of l-alanine in a flow-injection system with an immobilized enzyme reactor

A flow-injection system for the determination of l-alanine is described. Alanine dehydrogenase is immobilized on poly(vinyl alcohol) beads and used in a packed-bed enzyme reactor. The system responds linearly to injected samples (50 μl) in the concentration range 0.5–500 μM. The maximum throughput was 40 samples per hour. The immobilized enzyme reactor was stable for at least 6 weeks. Its usefulness for assay of l-alanine in serum and beverages is described.