Electrochemical Biosensor Based on Bienzyme and Carbon Nanotubes Incorporated into an Os‐complex Thin Film for Continuous Glucose Detection in Human Saliva

Saliva opens a door for noninvasive and painless glucose testing since it reflects changes in the body physiology of diabetic individuals as compared to healthy ones. In this paper, a unique, disposable saliva biosensor has been developed for accurate, low cost, and continuous glucose monitoring. The biosensor exhibits linear dependence of the catalytic current upon glucose bulk concentration over the 0.05–1.5 mM range (R=0.998). A detection limit of 0.003 mM can be calculated considering three times the standard deviation of the blank signal divided by the sensitivity of the sensor. The selectivity of the biosensor was evaluated by adding the interferent species of lactate, ascorbic acid and uric acid into in 0.5 mM glucose; the nearly negligible interference current indicates its good selectivity. The operational stability of the biosensor was measured in 1 mM glucose over a 2 h period (RSD=3.27 %). A clinical trial on real‐time noninvasive salivary glucose monitoring was carried out on 30 individuals by measuring subjects’ salivary glucose and blood glucose in parallel. The results show that there is a good correlation of glucose levels in saliva and in blood 2 h after breakfast. Thus, the disposable biosensor would be a potential alternative for continuous glucose detection in human saliva.     

Tannic Acid Modified Electrochemical Biosensor for Glucose Sensing Based on Direct Electrochemistry

A novel glucose biosensor was constructed through the immobilization of glucose oxidase (GOx) on gold nanoparticles (Au NPs) deposited, and chemically reduced graphene oxide (rGO) nanocomposite. In the synthesis, tannic acid (TA) was used for the reduction of both graphene oxide, and Au³⁺ to rGO, and Au NPs, respectively. Also, by harnessing the π‐π interaction between graphene oxide and TA, and protein‐TA interaction, a novel nanocomposite for the fabrication of a third generation biosensor was successfully constructed. Upon the oxidation of TA to quinone, which is easily reducible at the negative potential range, enhanced electron transfer was obtained. The cyclic voltammetry (CV) results demonstrated a pair of well‐defined and quasi‐reversible redox peaks of active site molecule of GOx. The biosensor exhibited a linear response to glucose concentrations varying from 2 to 10 mM with a sensitivity of 18.73 mA mM⁻¹ cm⁻². The fabricated biosensor was used for the determination of glucose in beverages.     

Simulation of Electrochemical Process for Glucose Oxidase Immobilized Conducting Polymer Electrodes

Abstract

Computer simulation of electrochemical processes that govern the operation of conducting polymer modified electrodes (CPME) have been reported in this paper. Comparison of the behaviour of a biocatalyst (GOX) in free solution and in the immobilized phase in conducting polymer modified electrodes (CPME) has been provided The output has been obtained using the Runga Kutta numerical method solved by programming in FORTRAN 77. The results point out that the catalytic current generated by an immobilized enzyme in layer is larger as compared to that for the enzyme in solution, and that it varies with the thickness of the diffusion layer.     

Nonenzymatic Electrochemical Sensor for Wearable Interstitial Fluid Glucose Monitoring

We report on a nonenzymatic electrochemical sensor for wearable glucose monitoring in interstitial fluid. The sensor exhibited acceptable selectivity and reliability for continuous glucose detection for up to 30 days. The sensor tip is coated with polyurethane, and the biocompatibility of the tip is investigated by tissue staining. A fully integrated wearable glucose monitoring system is developed with a wireless connection with a smartphone. The test results are in agreement with reference methods. So, we believe the sensor is promising for the development of a continuous glucose monitoring system and diabetes management.     

流动注射分析血清中葡萄糖的电化学检测池

测定血清中葡萄糖含量是临床检验的重要项目之一。何立千曾对各种血糖测定方法做过综述。葡萄糖氧化酶-4-氨基安替比林-苯酚光度法(酶制剂法)虽能较好地测定血清中葡萄糖的含量,但成本较高,耗时长。因此有必要研究一种快速、廉价、稳定的分析方法。人们考虑到酶的专属性,对葡萄糖氧化酶电极做了大量工作,然而,这种电极的寿命仍不理想。     

Preparation of GOD/Sol‐Gel Silica Film on Prussian Blue Modified Electrode for Glucose Biosensor Application

A novel amperometric glucose biosensor was fabricated by in situ incorporating glucose oxidase (GOD) within the sol‐gel silica film on a Prussian blue (PB) modified electrode. The method is simple and controllable, which combined the merits of in situ immobilizing biomolecules in sol‐gel silica film by electrochemical method and the synergic catalysis effects of PB and GOD molecules. Scanning electron microscopy (SEM) showed that the GOD/sol‐gel silica film was homogeneous with a large number of three‐dimensional nanopores, which not only enhanced mass transport, but also maintained the active configuration of the enzyme molecule and prevented the leakage of enzyme, therefore improved the stability and sensitivity of the biosensor. The fabricated biosensor showed fast response time (10 s), high sensitivity (26.6 mA cm^?2 M^?1), long‐term stability, good suppression of interference, and linear range of 0.01 mM–5.8 mM with a low detection limit of 0.94 μM for the detection of glucose. In addition, the biosensor was successfully applied to determine glucose in human serum samples.     

Osmium Redox Hydrogel Mediated Biosensor for Measurement of Low Concentration Glucose Extracted by Reverse Iontophoresis

An osmium redox hydrogel mediated biosensor for continuous monitoring of glucose extracted from subcutaneous solution by reverse iontophoresis has been developed. For the measurement of low concentration glucose, osmium‐poly(vinylpyridine) wiring horseradish peroxidase was introduced to modify the smooth Au electrodes, and the developed glucose biosensor exhibited a high sensitivity of 11.45 nA μM^?1 cm^?2 and a low detection limit of 2 μM, as well as a high operational stability of more than 97% of its initial activity over a test period of 13.5 h in stirred glucose solution at low applied potential (?0.1 V vs. Ag|AgCl), efficiently inhibiting the electroactive interferences. Permeability of the hydrogels was studied and a diffusion coefficient of 2.4×10^?5 cm²/s for H₂O₂ was obtained. In addition, the effects, such as temperature and the variation happening on Ag|AgCl counter electrode, on determination of glucose were also considered. The proof‐of‐feasibility of the biosensors for the monitoring of the glucose extracted from the subcutaneous solution was tested in vitro, and the responses of the sensors were analyzed. A linear response to current produced by extracted glucose in the concentration range of subcutaneous glucose from 1.0 to 12 mM was obtained with a correlation coefficient up to 0.989. These results testify the feasibility of the developed sensors for measuring the low concentration glucose and have significance for the development of noninvasive glucose monitoring system for the control of diabetes.     

基于铂纳米颗粒电沉积镁铝水滑石修饰电极的电化学葡萄糖生物传感器

采用成核/晶化隔离法合成了镁铝水滑石纳米颗粒,将其修饰到氧化铟锡导电玻璃电极表面;在此修饰电极基础上,利用电沉积还原氯铂酸盐法制备了铂纳米颗粒/水滑石复合修饰电极.由于水滑石层板表面的外限域作用有效抑制了铂纳米颗粒的聚集,使该电极对过氧化氢具有较好的电催化性能.基于镁铝水滑石良好的生物相容性,将葡萄糖氧化酶进一步修饰到该电极表面,实现了对葡萄糖高灵敏的电化学检测,检出限(S/N=3)达1.0μmol/L.     

Reduced Graphene Oxide/Pt Nanoparticles/Zn‐MOF‐74 Nanomaterial for a Glucose Biosensor Construction

In this study, a new glucose biosensor was fabricated by immobilizing glucose oxidase (GOx) on platinum nanoparticles (Pt NPs) decorated reduced graphene oxide (rGO)/Zn‐MOF‐74 hybrid nanomaterial. Herein, the biosensor fused the advantages of rGO with those of porous Zn‐MOF and conductive Pt NPs. This has not only enlarged the surface area and porosity for the efficient GOx immobilization and faster mass transport, but also provided favorable electrochemical features such as high current density, remarkable electron mobility through metal nanoparticles, and improved electron transfer between the components. The GOx‐rGO/Pt NPs@Zn‐MOF‐74 coated electrode displayed a linear measurement range for glucose from 0.006 to 6 mM, with a detection limit of 1.8 μM (S/N: 3) and sensitivity of 64.51 μA mM^?1 cm^?2. The amperometric response of the enzyme biosensor demonstrated the typical behavior of Michaelis‐Menten kinetics. The obtained satisfying sensitivity and measurement range enabled fast and accurate glucose measurement in cherry juice using the fabricated biosensor. The water‐stable Zn‐MOF‐74 demonstrated higher enzyme loading capacity and can be potent supporting material for biosensor construction.     

Electrochemical Reduction of a Conjugated Cinnamic Acid Diazonium Salt as an Immobilization Matrix for Glucose Biosensor

Initial results on the synthesis of a new conjugated diazonium salt of trans‐4‐cinnamic acid diazonium fluoroborate, which is used for the chemical modification of the glassy carbon (GC) electrode with trans‐4‐cinnamic acid groups through electrochemical reduction, and direct covalent immobilization of glucose oxidase (GOD) on the cinnamic acid groups are presented. The chemically modified GC electrode exhibits a good selectivity relative to the bare GC electrode for the various possible interfering compounds in glucose analysis: namely ascorbic acid and 4‐acetamidophenol. Covalent immobilization of GOD on the chemically modified GC electrode produces a biosensor which responds to glucose concentration changes in the presence of a soluble redox mediator (ferrocenemethanol). The chemical modification of GC by cinnamic acid groups is potentially useful for the attachment of other enzymes and biochemical reagents.     

Bi‐enzyme Electrochemical Sensor for Selective Determination of Organophosphorus Pesticides with Phenolic Leaving Groups

An amperometric bi‐enzyme sensor for detection of organophosphorus pesticides (OPs) with phenolic leaving groups, which are not electroactive, is presented in this work. The biosensing platform was created by a simple, controllable, and reproducible one‐step electrodeposition onto the surface of a glassy carbon electrode of a chitosan bionanocomposite with entrapped carboxylated multi walled carbon nanotubes, organophosphorus hydrolase (OPH), and horseradish peroxidase (HRP). The OPs determination involved a sequence of OPH and HRP‐catalyzed reactions resulting in phenolic radicals production, which were quantified by registering the current of their reduction at a potential of −50 mV vs. Ag, AgCl/KCl_sat.The developed sensor was applied for the determination of prothiofos, as an example. At optimized conditions (pH 7.25 and H₂O₂ concentration 200 μmol L⁻¹), a LOD as low as 0.8 μmol L⁻¹ was attained, while the linear concentration range was extended from 2.64 μmol L⁻¹ up to 35 μmol L⁻¹. The main advantage of the proposed bi‐enzyme sensor is its selectivity toward the OPs with phenolic leaving groups, excluding the interference of the nitrophenyl‐substituted OPs.     

Magnetite NPs@C with Highly‐Efficient Peroxidase‐Like Catalytic Activity as an Improved Biosensing Strategy for Selective Glucose Detection

This work reports the novel application of carbon‐coated magnetite nanoparticles (mNPs@C) as catalytic nanomaterial included in a composite electrode material (mNPs@C/CPE) taking advantages of their intrinsic peroxidase‐like activity. The nanostructured electrochemical transducer reveals an enhancement of the charge transfer for redox processes involving hydrogen peroxide. Likewise, mNPs@C/CPE demonstrated to be highly selective even at elevated concentrations of ascorbic acid and uric acid, the usual interferents of blood glucose analysis. Upon these remarkable results, the composite matrix was further modified by the addition of glucose oxidase as biocatalyst, in order to obtain a biosensing strategy (GOx/mNPs@C/CPE) with enhanced properties for the electrochemical detection of glucose. GOx/mNPs@C/CPE exhibit a linear range up to 7.5×10^?3 mol L^?1 glucose, comprising the entirely physiological range and incipient pathological values. The average sensitivity obtained at ?0.100 V was (1.62±0.05)×10⁵ nA L mol^?1 (R²=0.9992), the detection limit was 2.0×10^?6 M while the quantification limit was 6.1×10^?6 mol L^?1. The nanostructured biosensor demonstrated to have an excellent performance for glucose detection in human blood serum even for pathological values.     

Ni3S2 Supported on Porous Ball‐milled Silicon,a Highly Selective Electrochemical Sensor for Glucose Determination

In this work, an electrochemical sensor based on Ni₃S₂ nanoparticles supported on porous ball‐milled silicon was fabricated for measuring glucose. At first, the glassy carbon electrode (GCE) surface was modified by Ni₃S₂ nanoparticles supported on a porous ball‐milled silicon substrate. To characterize the modified electrode, N₂ adsorption‐desorption isotherms and BHJ, transmission electron microscopy (TEM), scanning electron microscopy (SEM), energy‐dispersive X‐ray spectroscopy (EDX), elemental mapping and X‐ray diffraction (XRD) were used. In the following, the effective parameters on the sensor response such as pH, NaOH concentration, catalyst concentration, applied potential, and rotational speed of the electrode were optimized using cyclic voltammetric (CV) and hydrodynamic amperometric methods. Under the optimal conditions, the calibration curve was plotted using the hydrodynamic amperometric method. Three linear regions were obtained from 0.5–134, 134–1246, and 1246–3546 μM, with a detection limit of 0.2 μM for glucose. Finally, the proposed method was used for measuring glucose levels in human blood serums.     

An Electrochemical Sensor Based on Ni(II) Complex and Multi Wall Carbon Nano Tubes Platform for Determination of Glucose in Real Samples

In the present paper, a stable and selective non‐enzymatic sensor is reported for determination of glucose (Glc) by using a carbon paste electrode modified with multiwall carbon nanotubes and Ni(II)‐SHP complex as modifier in an alkaline solution. This modified electrode showed impressive activity for oxidation of glucose in NaOH solution. Herein, Ni(II)‐SHP acts as a suitable platform for oxidation of glucose to glucolactone on the surface of the modified electrode by decreasing the overpotential and increasing in the current of analyte. Under the optimum conditions, the rate constant and electron transfer coefficient between electrode and modifier, were calculated to be 1.04 s⁻¹ and 0.64, respectively. The anodic peak currents indicated a linear dependency with the square root of scan rate and this behavior is the characteristic of a diffusion controlled process. So, the diffusion coefficient of glucose was found to be 3.12×10⁻⁶ cm² s⁻¹ due to the used number of transferred electron of 1. The obtained results revealed two linear ranges (5 to 190.0 μM (R²=0.997), 210.0 to 700.0 μM (R²=0.999)) and the detection limit of 1.3 μM for glucose was calculated by using differential pulse voltammetry (DPV) method. Also, the designed sensor was used for determination of glucose in the blood serum and urine samples. Some other advantages of Ni(II)‐SHP/CNT/CPE sensor are remarkable reproducibility, stability and selectivity which can be related to using nanomaterial of carbon nanotubes due to enhancement of electrode surface area.     

An Electrochemical Biosensor with Uricase Immobilized on Functionalized Gold Coated Copper Wire Electrode for Urinary Uric Acid Assay

A new second generation uricase electrode for urinary uric acid determination has been developed by chemically binding both uricase and redox mediator to inexpensive copper wire through simple electrodeposition of gold on copper surface and subsequent functionalization of the gold with L‐methionine. During a 209‐day testing period, the overall electrode performance exhibits in average a low oxidation potential of 0.33 V, a response time of 5 s, a widest linear calibration concentration range (0–2.38 mM, r²>0.9952), a sensitivity of 50 μA mM^?1, and a detection limit of 2.4 μM. The measurement accuracy and precision for the determination of uric acid in human urine specimens were 85.6–95.5 % and 0.3–2.4 %, respectively. The developed uricase electrode is potential for clinical applications.     

A Microdialysis Probe Coupled with A Miniaturized Thermal Glucose Sensor for In Vivo Monitoring

Abstract

A miniaturized thermal flow injection analysis biosensor has been coupled with a microdialysis probe for continuous subcutaneous glucose monitoring. Thermal biosensors are based on the principle of measuring the heat evolved during enzyme catalysed reactions. The system presented here consists of a miniaturized thermal biosensor with a small column containing coimmibolized glucose oxidase and catalase. The analysis buffer passes through the column at a flow rate of 60μL/min via an 1μL sample loop which is connected to a microdialysis probe.

Invitro results showed constant permeability of the probe and stability of the biosensor response during 24 hours. The response time was 85 sec giving a sample rate of 42 samples/hour.

During a load experiment, the glucose profile in a healthy volunteer was followed both in the subcutaneous tissue and blood using the microdialysis set-up proposed and comparing to blood glucose analyser.     

利用互补核酸杂交富集金胶实现信号扩增的电化学凝血酶蛋白生物传感器研究

介绍了一种利用互补核酸杂交富集金胶实现信号扩增的蛋白质生物传感器. 以凝血酶蛋白为研究对象, 利用凝血酶蛋白相对应的两段核酸适配体, 将适配体Ⅰ固定在磁性颗粒上, 用于特异性地捕获蛋白, 将适配体Ⅱ标记金胶作为检测信标. 由凝血酶蛋白和相对应的两段核酸适配体构建三明治结构的凝血酶蛋白生物传感器. 另外, 再通过信标金胶上过剩的核酸适配体链与另一段标记有金胶的互补核酸进一步杂交, 获得金胶的选择性聚集, 实现了信号扩增. 通过信号扩增, 使此传感器的灵敏度大大提高, 对凝血酶蛋白的检测下限可达到4.52×10-15 mol/L. 平行测定浓度为7.47×10-14 mol/L的凝血酶8次, 其RSD为3.0%. 该生物传感器对凝血酶蛋白有很好的特异性, 其它蛋白如溶菌酶和牛血清白蛋白的存在对于检测没有影响.     

Plasma‐functionalized Highly Aligned CNT‐based Biosensor for Point of Care Determination of Glucose in Human Blood Plasma

In this study, a new method for modification of vertically aligned carbon nanotube arrays (VACNTs) for selective detection of glucose was developed. VACNTs were grown by chemical vapor deposition method on a silicon substrate deposited with alumina as a buffer layer and iron as a catalyst using radio frequency (RF) sputtering and electron beam evaporation, respectively. The surface of the electrode was modified with electrodeposition of polyaniline (PANI) followed by covalent attachment of glucose oxidase (GOx). The electrode was characterized using field emission scanning electron microscopy (FESEM), micro‐Raman spectroscopy, and attenuated total reflectance Fourier transform infrared spectrometer (ATR‐FTIR) techniques. Cyclic voltammetry and differential pulse voltammetry were used to investigate the electrochemical behavior of the electrode. The fabricated electrode was successfully employed as a point‐of‐care (POC) biosensor for the detection of glucose in human blood plasma. The detection limit was 1.1 μM, and the sensitivity was 620 μA mM^?1 cm^?2 at the linear range of 2–426 μM.     

A New Molecularly Imprinted Polymer (MIP)‐based Electrochemical Sensor for Monitoring Cardiac Troponin I (cTnI) in the Serum

A novel molecularly imprinted polymer (MIP) sensor for rapid determination of cardiac troponin (cTnI) was established. Since it can bind to the template molecule cTnI specifically, it can be used to detect concentration of cTnI in serum without much sample pretreatment. What's more, the electrochemical signals depend on the concentration of template molecules. The synthetic sensor possesses advantages including simplicity, high specificity, low cost of preparation, good chemical and mechanical properties, sensitive and label‐free determination. The synthetic sensor shows good dynamic linearity at concentration range from 0.05 to 5.00 nM. The limit of detection (LOD) was found to be 0.027 nM. The detection time of whole process was within 5 minutes.     

An Electrochemical DNA Sensor Based on Electrodepositing Aluminum Ion Films on Stearic Acid‐Modified Carbon Paste Electrode and Its Application for the Detection of Specific Sequences Related to Bar Gene and CP4 Epsps Gene

An electrochemical DNA biosensor was fabricated by immobilizing DNA probe on aluminum ion films that were electrodeposited on the surface of the stearic acid‐modified carbon paste electrode (CPE). DNA immobilization and hybridization were characterized with cyclic voltammetry (CV) by using methylene blue (MB) as indicator. MB has a couple of well‐defined voltammetric redox peaks at the CPE. The currents of redox peaks of MB decreased after depositing aluminum ion films on the CPE (Al(III)/CPE) and increased dramatically after immobilizing DNA probe (ssDNA/Al(III)/CPE). Hybridization of DNA probe led to a marked decrease of the peak currents of MB, which can be used to detect the target single‐stranded DNA. The conditions for the preparation of Al(III)/CPE, and DNA immobilization and hybridization were optimized. The specific sequences related to bar transgene in the transgenic corn and the PCR amplification of CP4 epsps gene from the sample of transgenic roundup ready soybean were detected by differential pulse voltammetry (DPV) with this new electrochemical DNA biosensor. The difference between the peak currents of MB at ssDNA/Al(III)/CPE and that at hybridization DNA modified electrode (dsDNA/Al(III)/CPE) was applied to determine the specific sequence related to the target bar gene with the dynamic range comprised between 1.0×10^?7 mol/L to 1.0×10^?4 mol/L. A detection limit of 2.25×10^?8 mol/L of oligonucleotides can be estimated.