Flow Potentiometric Injection Analysis of Uric Acid Using Lipid Stabilized Films with Incorporated Uricase on ZnO Nanowires

A novel potentiometric uric acid biosensor was fabricated by immobilization of uricase into stabilized lipid films using zinc oxide (ZnO) nanowires as measuring electrode. Uricase was incorporated into the lipid film prior polymerization on the surface of well aligned ZnO nanowires resulting in a sensitive, selective, stable and reproducible uric acid biosensor. The potentiometric response was twice as large from previously reported values due to the presence of a cationic lipid in the lipid film. The sensor response had no interferences by normal concentrations of ascorbic acid, glucose, urea, proteins and lipids.     

Carbon Nanotubes‐Based Amperometric Cholesterol Biosensor Fabricated Through Layer‐by‐Layer Technique

A carbon nanotubes‐based amperometric cholesterol biosensor has been fabricated through layer‐by‐layer (LBL) deposition of a cationic polyelectrolyte (PDDA, poly(diallyldimethylammonium chloride)) and cholesterol oxidase (ChOx) on multi‐walled carbon nanotubes (MWNTs)‐modified gold electrode, followed by electrochemical generation of a nonconducting poly(o‐phenylenediamine) (PPD) film as the protective coating. Electrochemical impedance measurements have shown that PDDA/ChOx multilayer film could be formed uniformly on MWNTs‐modified gold electrode. Due to the strong electrocatalytic properties of MWNTs toward H₂O₂ and the low permeability of PPD film for electroacitve species, such as ascorbic acid, uric acid and acetaminophen, the biosensor has shown high sensitivity and good anti‐interferent ability in the detection of cholesterol. The effect of the pH value of the detection solution on the response of the biosensor was also investigated. A linear range up to 6.0 mM has been observed for the biosensor with a detection limit of 0.2 mM. The apparent Michaelis‐Menten constant and the maximum response current density were calculated to be 7.17 mM and 7.32 μA cm^?2, respectively.     

Tetraethylorthosilicate film modified with protein to fabricate cholesterol biosensor

Sol-gel derived tetraethylorthosilicate (TEOS) films were prepared by spin coating method on indium tin oxide (ITO) coated glass plate. Hydrophobic interaction method was used to coat the bovine serum albumin film over the surface of tetraethylorthosilicate sol-gel film to minimize cracking, biofouling and to improve the stability of the film. Cholesterol oxidase (ChOx) and horseradish peroxidase (HRP) were immobilized using covalent linkage with bovine albumin serum film to enhance the loading of the enzyme to improve the sensitivity of biosensor. Further ITO-TEOS-BSA-ChOx/HRP film was characterized by UV-vis, FTIR and SEM techniques. The optical response of the ITO-TEOS-BSA-ChOx/HRP biosensor was found to be linear in the range of 2-8 mM for cholesterol concentration with response time approximately 20 s. Amperometric response of ITO-TEOS-BSA-ChOx/HRP was observed to be linear in the range of 2-12 mM of cholesterol concentration with 10-s response time. Michaelis-Menten constant was calculated 21.2 mM .The shelf life of ITO-TEOS-BSA-ChOx/HRP biosensor was approximately about 8 weeks in desiccated conditions at room temperature.     

基于蛋白质直接电子转移的全胆固醇传感器

以壳聚糖为载体, 将血红蛋白、胆固醇氧化酶及胆固醇酯酶固定在玻碳电极表面, 在不使用任何电子媒介体的条件下, 利用血红蛋白和电极之间的直接电子转移, 制备出高选择性的全胆固醇生物传感器, 并用于测定血清中总胆固醇含量. 利用循环伏安法和恒电位法研究了该传感器的电化学特性. 在优化的实验条件下, 该传感器对胆固醇响应的线性范围为10~110 mg/dL, 检出限为5 mg/dL(信噪比的3倍), 响应时间为60 s. 对人血清中总胆固醇的测定表明, RSD小于6.2%, 回收率为95%~106%.     

Steady-state oxidation of cholesterol catalyzed by cholesterol oxidase in lipid bilayer membranes on platinum electrodes

Cholesterol oxidase is immobilized in electrode-supported lipid bilayer membranes. Platinum electrodes are initially modified with a self-assembled monolayer of thiolipid. A vesicle fusion method is used to deposit an outer leaflet of phospholipids onto the thiolipid monolayer forming a thiolipid/lipid bilayer membrane on the electrode surface. Cholesterol oxidase spontaneously inserts into the electrode-supported lipid bilayer membrane from solution and is consequently immobilized to the electrode surface. Cholesterol partitions into the membrane from buffer solutions containing cyclodextrin. Cholesterol oxidase catalyzes the oxidation of cholesterol by molecular oxygen, forming hydrogen peroxide as a product. Amperometric detection of hydrogen peroxide for continuous solution flow experiments are presented, where flow was alternated between cholesterol solution and buffer containing no cholesterol. Steady-state anodic currents were observed during exposures of cholesterol solutions ranging in concentration from 10 to 1000 μM. These data are consistent with the Michaelis-Menten kinetic model for oxidation of cholesterol as catalyzed by cholesterol oxidase immobilized in the lipid bilayer membrane. The cholesterol detection limit is below 1 μM for cholesterol solution prepared in buffered cyclodextrin. The response of the electrodes to low density lipoprotein solutions is increased upon addition of cyclodextrin. Evidence for adsorption of low density lipoprotein to the electrode surface is presented.     

Multienzymatic-rotating biosensor for total cholesterol determination in a FIA system

Fabrication of an amperometric-rotating biosensor for the enzymatic determination of cholesterol is reported. The assay utilizes a combination of three enzymes: cholesterol esterase (ChE), cholesterol oxidase (ChOx) and peroxidase (HRP); which were co-immobilizing on a rotatory disk. The method is developed by the use of a glassy carbon electrode as detector versus Ag/AgCl/3 M NaCl in conjunction with a soluble-redox mediator 4-tert-butylcatechol (TBC). ChE converts esterified cholesterol to free cholesterol, which is then oxidized by ChOx with hydrogen peroxide as product. TBC is converted to 4-tert-butylbenzoquinone (TBB) by hydrogen peroxide, catalyzed by HRP, and the glassy carbon electrode responds to the TBB concentration. The system has integrated a micro packed-column with immobilized ascorbate oxidase (AAOx) that works as prereactor to eliminate l-ascorbic acid (AA) interference. This method could be used to determine total cholesterol concentration in the range 1.2 μM-1 mM (r = 0.999). A fast response time of 2 min has been observed with this amperometric-rotating biosensor. Lifetime is up to 25 days of use. The calculated detection limits was 11.9 nM. Reproducibility assays were made using repetitive standards solutions (n = 5) and the percentage standard error was less than 4%.     

光导纤维胆固醇生物传感器的研究

将胆固醇酯酶、胆固醇氧化酶和辣根过氧化物酶通过戊二醛交联反应,固定在牛血清蛋白上,制成光纤胆固醇生物传感器的传感膜.此传感器偶合了胆固醇酯水解、胆固醇的氧化和鲁米诺同过氧化氢的化学发光等3种酶催化反应,通过光纤输出的化学发光信号进行检测.测定总胆固醇和自由胆固醇的线性范围均为0.5～20μg/mL,检测下限为0.1μg/mL,响应时间为2min,寿命在2个月以上,适用于血清中总胆固醇和游离胆固醇的测定.     

Development of a platinized and ferrocene-mediated cholesterol amperometric biosensor based on electropolymerization of polypyrrole in a flow system.

The preparation of a cholesterol amperometric biosensor using a platinized Pt electrode as a support for the electropolymerization of a polypyrrole film, in which cholesterol oxidase and ferrocene monocarboxylic acid (electron-transfer mediator) were co-entrapped, is described. All the biosensor preparation steps (platinization and electropolymerization) and the cholesterol determination take place in the same flow system. The presence of the mediator enhances the sensitivity and selectivity of the platinized biosensor without modifying the dynamic parameters of the response, and the platinized layer improves the operational lifetime of the mediated sensor. The sensitivity obtained was 88.51 nA mM(-1) and the limit of detection was 12.4 microM of cholesterol. The analytical properties of the biosensor for the flow-injection determination of cholesterol were studied and compared with those of other more simple amperometric biosensor configurations.     

A Selective Cholesterol Biosensor Based on Composite Film Modified Electrode for Amperometric Detection

An amperometric cholesterol biosensor based on immobilization of cholesterol oxidase in a Prussian blue (PB)/polypyrrole (PPy) composite film on the surface of a glassy carbon electrode was fabricated. Hydrogen peroxide produced by the enzymatic reaction was catalytically reduced on the PB film electrode at 0 V with a sensitivity of 39 μA (mol/L)^?1. Cholesterol in the concentration range of 10^?5 ? 10^?4 mol/L was determined with a detection limit of 6 × 10^?7 mol/L by amperometric method. Normal coexisting compounds in the bio‐samples such as ascorbic acid and uric acid do not interfere with the determination. The excellent properties of the sensor in sensitivity and selectivity are attributed to the PB/PPy layer modified on the sensor.     

Amperometric cholesterol biosensor based on immobilized cholesterol esterase and cholesterol oxidase on conducting polypyrrole films

Fabrication of an amperometric cholesterol biosensor by co-immobilization of cholesterol esterase (ChEt) and cholesterol oxidase (ChOx) onto conducting polypyrrole (PPY) films using electrochemical entrapment technique is described. Electrochemical polymerization was carried out using a two-electrode cell configuration at 0.8 V. Characterization of resulting amperometric biosensor for the estimation of cholesterol has been experimentally determined in terms of linear response range, optimum pH, applied potential, temperature, and shelf-life. These PPY/ChEt/ChOx electrodes can be used for cholesterol ester estimation from 1 to 8 mM and have shelf-life of about 4 weeks at 4 °C during which about 15 estimations of cholesterol ester could be made. The sensitivity of PPY/ChEt/ChOx electrode has been found to be 0.15 μA/mM and the apparent K_m value for this electrode is 9.8 mM. Conductivity of the polymer films found to be about 3×10⁻³ S/cm.     

Development An Amperometric Microbial-enzyme Hybrid Cholesterol Biosensor Based On Ionic Liquid MWCNT Carbon Paste Electrode

In this study we report the development of an amperometric cholesterol biosensor based on cholesterol oxidase from Pseudomonas sp. and catalase immobilized in carbon paste electrode (CPE) modified with multiwall carbon nanotubes (MWCNT) and ionic liquid (IL). The working electrode (CPE/MWCNT-IL/Microorganism (MO)-Catalase) was characterized by impedance spectroscopy and cyclic voltammetry at different stages of its construction. This proposed cholesterol biosensor performed linear relationship in the range of 5–600 μM with a low detection limit of 1.52 μM. The biosensor showed good sensitivity and high selectivity and it was successfully applied for the measurement of cholesterol levels in lyophilized serum samples.     

An Electrochemical Biosensor with Cholesterol Oxidase/ Sol‐Gel Film on a Nanoplatinum/Carbon Nanotube Electrode

The carbon nanotubes decorated nanoplatinum (CNT‐Pt) were prepared using a chemical reduction method and a novel base electrode was constructed by intercalating CNT‐Pt on the surface of a waxed graphite electrode. The results showed that the nano‐particles of platinum at a waxed graphite electrode exhibits high catalytic activity for the reduction of hydrogen peroxide. The cholesterol oxidase (ChOx), chosen as a model enzyme, was immobilized with sol‐gel on the CNT‐Pt base electrode to construct a biosensor. The current response of the biosensor for cholesterol was very rapid (<20 s). The linear range for cholesterol measurement was 4.0×10^?6 mol/L ?1.0×10^?4 mol/L with a detection limit of 1.4×10^?6 mol/L. The experiments also showed that the ChOx/sol‐gel/CNT‐Pt biosensor was sensitive and stable in detecting cholesterol in serum samples.     

Structural Characterization of Graphene Nanosheets for Miniaturization of Potentiometric Urea Lipid Film Based Biosensors

The present article describes a miniaturized potentiometric urea lipid film based biosensor on graphene nanosheets. Structural characterization of graphene nanosheets for miniaturization of potentiometric urea lipid film based biosensors have been studied through atomic force microscopy (AFM) and transmission electron microscopy (TEM) measurements. UV‐Vis and Fourrier transform IR (FTIR) spectroscopy have been utilized to study the pre‐ and postconjugated surfaces of graphene nanosheets. The presented potentiometric urea biosensor exhibits good reproducibility, reusability, selectivity, rapid response times (～4 s), long shelf life and high sensitivity of ca. 70 mV/decade over the urea logarithmic concentration range from 1×10^?6 M to 1×10^?3 M.     

Enzyme-based determination of cholesterol using the quartz crystal acoustic wave sensor

We have used the AT-cut quartz crystal sensor to measure in real-time the total cholesterol concentration in buffer and serum, using the trienzyme system of cholesterol esterase (ChE), cholesterol oxidase (ChOx) and horseradish peroxidase (HRP). The hydrogen peroxide produced from the ChE-ChOx reaction oxidises diaminobenzidine (DAB), in the presence of HRP. The response of the sensor to cholesterol is optimal in the presence of 0.1% (v/v) Triton X-100 at 0.2 U/ml ChOx, and 1 U/ml ChE. A response is obtained in less than 25 min. Using the optimal concentrations of the reagents, the linear range for free cholesterol and low density lipoprotein (LDL) cholesterol determination was between 50 and 300 μM, and 25 and 400 μM, respectively. It was found that the concentration of high density lipoprotein (HDL) cholesterol could not be determined because it solubilised the oxidised DAB, leading to poor adsorption at the crystal surface. We obtained a response to the use of cholesterol in serum at 300 μM, demonstrating that this biosensor could be used for cholesterol determination in clinical samples.     

Electrochemical Study of Chitosan‐SiO2‐MWNT Composite Electrodes for the Fabrication of Cholesterol Biosensors

We report a novel composite electrode made of chitosan‐SiO₂‐multiwall carbon nanotube (CHIT‐SiO₂‐MWNT) composite coated on the indium‐tin oxide (ITO) glass substrate. Cholesterol oxidase (ChOx) was covalently immobilized on the CHIT‐SiO₂‐MWNT/ITO electrode that resulted in a ChOx/CHIT‐SiO₂‐MWNT/ITO cholesterolactive bioelectrode. The CHIT‐SiO₂‐MWNT/ITO and ChOx/CHIT‐SiO₂‐MWNT/ITO electrodes were characterized with Fourier transform infrared spectroscopy (FTIR), scanning electron microscopy (SEM), cyclic voltammetry (CV) and electrochemical impedance spectroscopy (EIS). The influence of various parameters was investigated, including the applied potential, pH of the medium, and the concentration of the enzyme on the performance of the biosensor. The cholesterol bioelectrode exhibited a sensitivity of 3.4 nA/ mgdL^?1 with a response time of five seconds. The biosensor using ChOx/CHIT‐SiO₂‐MWNT/ITO as the working electrode retained its original response after being stored for six months. The biosensor using ChOx/CHIT‐SiO₂‐MWNT/ITO as the working electrode showed a linear current response to the cholesterol concentration in the range of 50–650 mg/dL.     

Electroactive Prussian Blue Encapsulated Iron Oxide Nanostructures for Mediator‐Free Cholesterol Estimation

Iron oxide nanoparticles of size ～10 nm have been encapsulated into four nanometer thick shells of Prussian blue and were then electrophoretically deposited onto an indium tin oxide substrate. The immobilization of cholesterol oxidase has been done onto the nanostructured film to investigate the kinetic parameters and biosensing characteristics. The fabricated bioelectrode exhibits an electron transfer coefficient and a charge transfer rate constant of 0.45 and 45.15 s^?1, respectively. Direct electron transfer properties of the nanostructured film result in 3^rd generation cholesterol biosensor. The bioelectrode exhibits high sensitivity (2.15 mAM^?1 cm^?2), a low K_m^app value (0.07 mM), good stability and high selectivity towards cholesterol.     

Fabrication of Redox‐Mediator Supported Potentiometric Nitrate Biosensor with Nitrate Reductase

Fabrication of a more superior nitrate potentiometric biosensor than previously achieved with NaR and NADH has been accomplished by co‐entrapment of redox mediators and NaR into polypyrrole (PPy) film during galvanostatic polymerization of pyrrole. The replacement of NADH with redox mediators such as thionin acetate (ThAc), safranin (Saf), and azure A (AzA) gave more sensitive potentiometric responses, better minimum detectable concentration, linear concentration range and response time for nitrate than possible with NADH. The co‐entrapment of ThAc, Saf, AzA and methyl viologen (MV) with NaR into PPy films also improved the Nernstian behavior of the electrode process beyond the capability of the PPy‐NaR‐NADH biosensor. Substantial reduction in volume and quantity of cofactor/mediator and, hence cost, was achieved by the replacement of NADH with a redox mediator. Only 50 μM of AzA was required to form a PPy‐NaR‐AzA biosensor which gave the most sensitive potentiometric response for nitrate, achieving a minimum detectable concentration of 10 μM, a linear concentration range of 50–5000 μM and a response time of 2–4 s.     

Improvement of poly(amphiphilic pyrrole) enzyme electrodes via the incorporation of synthetic laponite-clay-nanoparticles

The electropolymerization of an enzyme-amphiphilic pyrrole ammonium-laponite nanoparticles mixture preadsorbed on the electrode surface provides the simultaneous immobilization of the enzyme and the hydrophilic laponite-clay-nanoparticles in a functionalized polypyrrole film. The presence of incorporated laponite particles within the electrogenerated polymer induces a strong improvement of the analytical performances (I_max and sensitivity) of amperometric biosensors based on polyphenol oxidase. These beneficial effects have been attributed to a marked enhancement of the apparent specific activity of the immobilized enzyme (from 0.21 to 0.85% of the specific activity of the free enzyme), the permeability of the host polymer being unchanged. This strategy of biosensor performance improvement was tested with cholesterol oxidase as an enzyme model. The presence of laponite additive in the poly(amphiphilic pyrrole) host matrix induces a similar enhancement of sensitivity and I_max for cholesterol biosensing as well as a large improvement of the storage stability of the polypyrrole-cholesterol oxidase electrode.     

Improvement of poly(amphiphilic pyrrole) enzyme electrodes via the incorporation of synthetic laponite-clay-nanoparticles

The electropolymerization of an enzyme-amphiphilic pyrrole ammonium-laponite nanoparticles mixture preadsorbed on the electrode surface provides the simultaneous immobilization of the enzyme and the hydrophilic laponite-clay-nanoparticles in a functionalized polypyrrole film. The presence of incorporated laponite particles within the electrogenerated polymer induces a strong improvement of the analytical performances (I_max and sensitivity) of amperometric biosensors based on polyphenol oxidase. These beneficial effects have been attributed to a marked enhancement of the apparent specific activity of the immobilized enzyme (from 0.21 to 0.85% of the specific activity of the free enzyme), the permeability of the host polymer being unchanged. This strategy of biosensor performance improvement was tested with cholesterol oxidase as an enzyme model. The presence of laponite additive in the poly(amphiphilic pyrrole) host matrix induces a similar enhancement of sensitivity and I_max for cholesterol biosensing as well as a large improvement of the storage stability of the polypyrrole-cholesterol oxidase electrode.     

Direct Electrochemistry of Cholesterol Oxidase Immobilized on a Conducting Polymer: Application for a Cholesterol Biosensor

Direct electrochemistry of cholesterol oxidase (ChOx) immobilized on the conductive poly‐3′,4′‐diamine‐2,2′,5′,2″‐terthiophene (PDATT) was achieved and used to create a cholesterol biosensor. A well‐defined redox peak was observed, corresponding to the direct electron transfer of the FAD/FADH₂ of ChOx, and the rate constant (k_s) was determined to be 0.75 s^?1. Glutathione (GSH) covalently bonded with PDATT was used as a matrix for conjugating AuNPs, ChOx, and MP, simultaneously. MP co‐immobilized with ChOx on the AuNPs‐GSH/PDATT exhibited an excellent amperometric response to cholesterol. The dynamic range was from 10 to 130 μM with a detection limit of 0.3±0.04 μM.