Development of glucose sensor using two-photon adsorbed photopolymerization

A novel glucose sensor was constructed, and its analytical potential examined. A chip-type three-electrode system for use in a flow-type electrochemical glucose sensor was fabricated using a UV lithography technique on a glass slide. An Ag/AgCl reference electrode was made by electroplating silver onto a Pt electrode and dipping in a saturated KCl solution for 30 min. In addition, a glucose-sensing electrode was fabricated using a two-photon adsorbed photopolymerization technique with a photo-reactive resin containing a glucose oxidase enzyme, ferrocene mediator, non-ionic surfactant, and carbon nanotubes. The cyclic voltammetry of the potassium ferrocyanide in the Pt sensor system showed a stable electrode condition. The response of the modified Pt sensor confirms the feasibility of using a two-photon adsorbed photopolymerization technique for the easy fabrication of functional biosensors.     

Glucose biosensor prepared by glucose oxidase encapsulated sol-gel and carbon-nanotube-modified basal plane pyrolytic graphite electrode

A new glucose biosensor has been fabricated by immobilizing glucose oxidase into a sol-gel composite at the surface of a basal plane pyrolytic graphite (bppg) electrode modified with multiwall carbon nanotube. First, the bppg electrode is subjected to abrasive immobilization of carbon nanotubes by gently rubbing the electrode surface on a filter paper supporting the carbon nanotubes. Second, the electrode surface is covered with a thin film of a sol-gel composite containing encapsulated glucose oxidase. The carbon nanotubes offer excellent electrocatalytic activity toward reduction and oxidation of hydrogen peroxide liberated in the enzymatic reaction between glucose oxidase and glucose, enabling sensitive determination of glucose. The amperometric detection of glucose is carried out at 0.3 V (vs saturated calomel electrode) in 0.05 M phosphate buffer solution (pH 7.4) with linear response range of 0.2-20 mM glucose, sensitivity of 196 nA/mM, and detection limit of 50 microM (S/N=3). The response time of the electrode is < 5s when it is stored dried at 4 degrees C, the sensor showed almost no change in the analytical performance after operation for 3 weeks. The present carbon nanotube sol-gel biocomposite glucose oxidase sensor showed excellent properties for the sensitive determination of glucose with good reproducibility, remarkable stability, and rapid response and in comparison to bulk modified composite biosensors the amounts of enzyme and carbon nanotube needed for electrode fabrication are dramatically decreased.     

Amperometric mediated carbon paste biosensor based on D-fructose dehydrogenase for the determination of fructose in food analysis

A new mediated amperometric biosensor for fructose is described. The sensor is based on a commercially available D-fructose dehydrogenase. The enzyme is incorporated in a carbon paste matrix containing Os(bpy)₂Cl₂ as redox mediator that achieves electron transfer at 0·1 V (versus Ag/AgCl) with maximum apparent current densities of 1·2 mA/cm². The dependence of the steady-state current on the loading of the mediator and the enzyme, other electrode construction parameters, the operating potential, the pH and the temperature was studied. In the steady-state mode the response current was directly proportional to D-fructose concentration from 0·2 to 20mM with a detection limit of 35 μM (signal-to-noise ratio, S/N, 3). In the flow injection analysis mode the response current was directly proportional to D-fructose concentration from 0·5 to 15 M with a detection limit of 115 μM (S/N 3). The sensor was used for the determination of fructose in food samples in a flow injection system and validated with a commercial enzyme kit.     

Immobilization of horseradish peroxidase with a regenerated silk fibroin membrane and its application to a tetrathiafulvalene-mediating H2O2 sensor

Horseradish peroxidase (HRP) was immobilized onto a membrane of the regenerated silk fibroin (RSF) from waste milk. The structure of the blend membrane of RSF and HRP was characterized by the use of IR spectra. A second generation of H₂O₂ sensor on the basis of the immobilized HRP was fabricated, in which tetrathiafulvalene acts as mediating electron transfer between the immobilized enzyme and a glassy carbon electrode. Dependencies of pH and temperature on the H₂O₂ biosensor were checked by utilizing cyclic voltammetry. The sensor exhibits high sensitivity, good reproducibility and storage stability.     

Detection of pesticides using an amperometric biosensor based on ferophthalocyanine chemically modified carbon paste electrode and immobilized bienzymatic system

A new highly sensitive amperometric method for the detection of organophosphorus compounds has been developed. The method is based on a ferophthalocyanine chemically modified carbon paste electrode coupled with acetylcholinesterase and choline oxidase co-immobilized onto the surface of a dialysis membrane. The activity of cholinesterase is non-competitively inhibited in the presence of pesticides. The highest sensitivity to inhibitors was found for a membrane containing low enzyme loading and this was subsequently used for the construction of an amperometric biosensor for pesticides. Analyses were done using acetylcholine as substrate; choline produced by hydrolysis in the enzymatic layer was oxidized by choline-oxidase and subsequently H(2)O(2) produced was electrochemically detected at +0.35 V vs. Ag/AgCl. The decrease of substrate steady-state current caused by the addition of pesticide was used for evaluation. With this approach, up to 10(-10) M of paraoxon and carbofuran can be detected.     

MWCNT-ruthenium oxide composite paste electrode as non-enzymatic glucose sensor

A non-enzymatic glucose sensor of multi-walled carbon nanotube-ruthenium oxide/composite paste electrode (MWCNT-RuO(2)/CPE) was developed. The electrode was characterized by using XRD, SEM, TEM and EIS. Meanwhile, cyclic voltammetry and amperometry were used to check on the performances of the MWCNT-RuO(2)/CPE towards glucose. The proposed electrode has displayed a synergistic effect of RuO(2) and MWCNT on the electrocatalytic oxidation of glucose in 3M NaOH. This was possible via the formation of transitions of two redox pairs, viz. Ru(VI)/Ru(IV) and Ru(VII)/Ru(VI). A linear range of 0.5-50mM glucose and a limit of detection of 33μM glucose (S/N=3) were observed. There was no significant interference observable from the traditional interferences, viz. ascorbic acid and uric acid. Indeed, results so obtained have indicated that the developed MWCNT-RuO(2)/CPE would pave the way for a better future to glucose sensor development as its fabrication was without the use of any enzyme.     

A novel glucose biosensor using bi-enzyme incorporated with peptide nanotubes

A novel amperometric glucose biosensor was developed using the bio-inspired peptide nanotube (PNT) as an encapsulation template for enzymes. Horseradish peroxidase (HRP) was encapsulated by the PNT and glucose oxidase (GO(x)) was co-immobilized with the PNT on a gold nanoparticle (AuNP)-modified electrode. A binary SAM of 3-mercaptopropionic acid (MPA) and 1-tetradecanethiol (TDT) was formed on the surface of the electrode to immobilize the PNT and GO(x). The resulting electrode appeared to provide the enzymes with a biocompatible nanoenvironment as it sustained the enhanced enzyme activity for an extended time and promoted possible direct electron transfer through the PNT to the electrode. Performance of the biosensor was evaluated in terms of its detection limit, sensitivity, pH, response time, selectivity, reproducibility, and stability in a lab setting. In addition the sensor was tested for real samples. The composite of AuNP-SAM-PNT/HRP-GO(x) to fabricate a sensor electrode in this study exhibited a linear response with glucose in the concentration range of 0.5-2.4mM with a R(2)-value of 0.994. A maximum sensitivity of 0.3mAM(-1)and reproducibility (RSD) of 1.95% were demonstrated. The PNT-encapsulated enzyme showed its retention of >85% of the initial current response after one month of storage.     

Fabrication of butyrylcholinesterase sensor using polyurethane-based ion-selective membranes.

A simple method of enzyme immobilization was investigated which is useful for fabrication of enzyme sensors based on polymeric ion-selective membranes. The enzyme membrane was built by coating a thin hydrophilic polyurethane (HPU) film directly mixed with an enzyme over an underlying polyurethane (PU)-based ion-selective membrane. This highly simple method of enzyme immobilization was applied to the fabrication of a potentiometric butyrylcholinesterase-based biosensor for the determination of organophosphorus pesticides. The enzyme was well entrapped within the HPU film and the intrinsic potentiometric response of the underlying ion-selective PU membrane was not influenced significantly by the outer HPU/enzyme membrane. The enzyme electrode was optimized by changing systematically the composition of the enzyme membrane to evaluate the effect of the changes on sensor response. The sensor was successfully applied to the analysis of paraoxon, an organophosphorus pesticide.     

P-chip and P-chip bienzyme electrodes based on recombinant forms of horseradish peroxidase immobilized on gold electrodes

Adsorption and bioelectrocatalytic activity of native horseradish peroxidase (HRP) and its recombinant forms on polycrystalline gold electrodes were studied. Recombinant forms of HRP were produced by a genetic engineering approach using an E. coli expression system. According to direct mass measurements with a quartz crystal microbalance, all the forms of HRP formed monolayer coverage of the enzyme on the gold surface. However, only gold electrodes modified with the recombinant HRP forms (non-glycosylated) exhibited high and stable current response to H₂O₂ due to its bioelectrocatalytic reduction based on direct electron transfer (ET) between gold and the active site of the enzyme. Introduction of a six-His tag either at the C-terminus or at the N-terminus of the enzyme molecule additionally increased the strength of the enzyme binding with the gold surface and the efficiency of direct ET. Immobilization of recombinant forms of HRP containing histidine functional groups on the surface of the gold electrode was used both for the development of a P-chip, a biosensor for hydrogen peroxide determination based on direct ET, and for the development of a bienzyme biosensor electrode for the determination of L-lysine based on co-immobilized recombinant forms of HRP and L-lysine--oxidase.     

Carbon post-microarrays for glucose sensors

A novel design and fabrication method of glucose sensors based on high aspect ratio carbon post-microarrays is reported in this paper. Apart from the fact that carbon has a wide electrochemical stability window, a major advantage of using carbon post-microarrays as working electrodes for an amperometric glucose sensor is the large reactive surface per unit footprint substrate area, improving sensitivity of the glucose sensor. The carbon post-microarrays were fabricated by carbon-microelectromechanical systems (C-MEMS) technology. Immobilization of enzyme onto the carbon post-electrodes was carried out through co-deposition of glucose oxidase (GOx) and electrochemically polymerized polypyrrole (PPy). Sensing performance of the glucose sensors with different post-heights and various post-densities was tested and compared. The carbon post-glucose sensors show a linear range from 0.5 mM to 20 mM and a response time of about 20 s, which are comparable to the simulation result. Sensitivity per unit footprint substrate area as large as 2.02 mA/(mM cm²) is achieved with the 140 μm high (aspect ratio around 5:1) carbon post-samples, which is two times the sensitivity per unit footprint substrate area of the flat carbon films. This result is consistent with the hypothesis that the number of reaction sites scales with the reactive surface area of the sensor. Numerical simulation based on enzymatic reaction and glucose diffusion kinetics gives the optimum geometric design rules for the carbon post-glucose sensor. Glucose sensors with even higher sensitivity can be achieved utilizing higher carbon post-microarrays when technology evolution will permit it.     

Enzyme-entrapping membranes for biosensors obtained by radiation-induced polymerization

A new method of physically immobilizing enzymes in poly(2-hydroxyethyl methacrylate) membranes was developed in order to obtain suitable biosensors. It was possible to prepare an enzyme sensor based on an oxygen Clark electrode and on glucose oxidase immobilized by low-temperature gamma radiation-induced polymerization. Temperature and pH effects on the activity of immobilized enzyme are described and the response characteristics of the resulting biosensor are summarized. The determination of glucose in standard solutions was carried out and a linear calibration curve, with an R² value of 0·9993, from the detection limit 5 × 10⁻⁵ to 1·2 × 10⁻³ was obtained. The biosensor was employed to analysis of control sera and the results were compared to those obtained by enzymatic-spectrophotometric detection.     

Electrochemical imprinted sensor for determination of oleanic acid based on poly (sodium 4-styrenesulfonate-co-acrylic acid)-grafted multi-walled carbon nanotubes-chitosan and cobalt hexacyanoferrate nanoparticles

A novel sensitive and selective imprinted electrochemical sensor for the determination of oleanic acid was constructed on a carbon electrode by stepwise modification of functional multi-walled carbon nanotubes, cobalt hexacyanoferrate nanoparticles and a thin imprinted sol-gel film. The fabrication of a homogeneous porous poly (sodium 4-styrenesulfonate-co-acrylic acid)-grafted multi-walled carbon nanotubes/SiO(2)-chitosan nanocomposite film was conducted by controllable electrodeposition technology. The surface morphologies of the modified electrodes were characterized by scanning electron microscope. The performance of the imprinted sensor was investigated by cyclic voltammetry, square wave voltammetry and electrochemical impedance spectroscopy in detail. The imprinted sensor displayed high sensitivity and selectivity towards oleanic acid. A linear relationship between the sensor response signal and the logarithm of oleanic acid concentrations ranging from 1.0×10(-8) to 1.0×10(-3) mol L(-1) was obtained with a detection limit of 2.0×10(-9) mol L(-1). It was applied to the determination of oleanic acid in real capsule samples successfully.     

Immobilization of horseradish peroxidase on chitosan/silica sol-gel hybrid membranes for the preparation of hydrogen peroxide biosensor

A simple and effective strategy for fabrication of hydrogen peroxide (H₂O₂) biosensor has been developed by entrapping horseradish peroxidase (HRP) in chitosan/silica sol–gel hybrid membranes (CSHMs) doped with potassium ferricyanide (K₃Fe(CN)₆) and gold nanoparticles (GNPs) on platinum electrode surface. The hybrid membranes are prepared by cross-linking chitosan (CS) with 3-aminopropyltriethoxysilane (APTES), while the presence of GNPs improved the conductivity of CSHMs, and the Fe(CN)₆^3−/4− was used as a mediator to transfer electrons between the electrode and HRP due to its excellent electrochemistry activity. UV–Vis absorption spectroscopy was employed to characterize the different components in the CSHMs and their interaction. The parameters influencing the performance of the resulting biosensor were optimized and the characteristic of the resulting biosensor was characterized by cyclic voltammetry and chronoamperometry. Linear calibration for hydrogen peroxide was obtained in the range of 3.5 × 10^− 6 to 1.4 × 10^− 3 M under the optimized conditions with the detection limit (S/N = 3) of 8.0 × 10^− 7 M. The apparent Michaelis–Menten constant of the enzyme electrode was 0.93 mM. The enzyme electrode retained about 78% of its response sensitivity after 30 days. The system was applied for the determination of the samples, and the results obtained were satisfactory.     

Miniaturized multi-enzyme biosensors integrated with pH sensors on flexible polymer carriers for in vivo applications

An electrochemical glucose sensor has been integrated, together with a pH sensor, on a flexible polyimide substrate for in vivo applications. The glucose sensor is based on the measurement of H₂O₂ produced by the membrane-entrapped enzyme glucose oxidase (GOD). To minimize electrochemical interference, an electrode configuration was designed to perform differential measurements. The solid-state pH sensor employs a PVC-based neutral carrier membrane. The enzymes GOD and catalase were immobilized into two layers of photolithographically patterned hydrogels. The intended use of this device is the short-term monitoring of glucose and pH in intensive care units and operating theatres, especially for neurosurgical applications. The developed immobilization technique can also be used to create integrated multi-sensor chips for clinical analysers. The glucose and pH sensor exhibited excellent performance during tests in buffer solutions, serum and whole blood.     

Development of electrochemical biosensor based on tyrosinase immobilized in composite biopolymeric film

An electrochemical enzyme electrode for dopa and dopamine was developed via an easy and effective immobilization method. The enzyme tyrosinase was extracted from a plant source Amorphophallus companulatus and immobilized in a novel composite of two biopolymers: agarose and guar gum. This composite matrix-containing enzyme forms a self-adhering layer on the active surface of glassy carbon electrode, making it a selective and sensitive phenol sensor. Dopa and dopamine were determined by the direct reduction of biocatalytically liberated quinone species at -0.18V versus Ag/AgCl (3M KCl). The analytical characteristics of this sensor, including linear range, lower detection limit, pH, and storage stability, are described. It has reusability up to 15 cycles and a shelf life of more than 2 months.     

Long-term in vivo experience of an electrochemical sensor using the potential step technique for measurement of mixed venous oxygen pressure

An implantable amperometric blood oxygen sensor was developed to improve rate adaptation of heart pacemakers. Two different working electrode materials in direct contact with the blood were tested, smooth glassy carbon and gold. Reference electrodes of Ag/AgCl and porous pyrolytic carbon were evaluated. A counter electrode being the titanium housing of the pulse generator was partly coated with carbon. An implantable pacemaker system with chronocoulometric oxygen detection was developed. Heart synchronous potential steps were periodically applied to the 7.5 mm² working electrode in the atrium. Both single and double potential step techniques were evaluated. The oxygen diffusion limited current was used to calculate the stimulation rate. Bench tests and studies on 31 animals were performed to evaluate long-term stability and biocompatibility. In five dogs, the AV node was destroyed by RF ablation to create a realistic animal model of a pacemaker patient. Sensor stability and response to exercise was followed up to a maximum implantation time of 4 years. Post-mortem examinations of the electrode surfaces and tissue response were performed. The results show that a gold electrode is more stable than glassy carbon. The Ag/AgCl reference was found not to be biocompatible, but activated carbon was stable enough for use as reference for the potentiostat. Double potential steps stabilize the sensor response in comparison to single steps. Blood protein adsorption on the gold surface decreased the oxygen transport but not the reaction efficacy. No adverse tissue reactions were observed.     

Development of a dimethyl ether (DME) sensor using platinum nanoparticles and thick-film printing

A portable and cost-effective technique to measure the dimethyl ether (DME) concentrations has been developed. It is based on an electrochemical principle measuring the oxidation current of DME at an applied potential of +0.2V versus a Ag/AgCl reference electrode. Thick-film printing technique is used for the fabrication of this DME sensor, and platinum nanoparticles in the crystallite size of 5.5 nm are used for the modification of the working electrode surface. This modification enhances the sensor performance significantly leading to a higher sensitivity of the sensor comparing to bare platinum electrode. Evaluation and characterization of this sensor are carried out over the DME concentration range of 0-7% (v/v), and a linear relationship between sensor outputs and the DME concentrations with an average R(2) of 0.996 exists. The reproducibility of the sensor is also very good. This electrochemically based DME sensor fabricated by thick-film screen printing technique and using the platinum nanoparticles to enhance its performance will be valuable and practical for the estimation of the airway mucosal blood flow.     

Voltammetric detection of trimethylamine using immobilized trimethylamine dehydrogenase on an electrodeposited goldnanoparticle electrode

A voltammetric enzyme electrode was developed based on nicotinamide-independent trimethylamine dehydrogenase (TMADH, EC 1.5.99.7), which catalyses the oxidation of trimethylamine (TMA) to dimethylamine and formaldehyde. A quaternized osmium hydrogel polymer, poly(vinylimidazole-[Os(4,4′-dimethyl-2,2′-bipyridine)₂Cl]^+/2+) with ethylamine (PVI-Os-EA), was prepared as a potential redox mediator in an electrochemical biosensor. TMA was detected using TMADH that was co-immobilized with an osmium hydrogel polymer on electrodeposited gold nanoparticles (Au-NPs) on screen-printed carbon electrodes (SPCEs). The Au-NPs deposited onto SPCEs provided about a three times higher electrochemical response compared to that of a planar gold electrode. As TMA was catalyzed by wired TMADH, the electrical signal was monitored at 0.3 V versus Ag/AgCl by cyclic voltammetry and chronoamperometry. The anode currents increased linearly in proportion to the TMA concentration over the 0 ∼ 2.5 mM range with a detection limit of 1 μM (R = 0.9972).     

Highly selective amperometric glucose microdevice derived from diffusion layer gap electrode

Although most of enzyme catalytic reactions are specific, the amperometric detection of the enzymatic reaction products is largely nonselective. How to improve the detection selectivity of the enzyme-based electrochemical biosensors has to be considered in the sensor fabrication procedures. Herein, a highly selective amperometric glucose biosensor based on the concept of diffusion layer gap electrode pair which we previously proposed was designed. In this biosensor, a gold tube coated with a conductive layer of glucose oxidase/Nafion/graphite was used to create an interference-free region in its diffusion layer by electrochemically oxidizing the interfering electroactive species at proper potentials. A Pt probe electrode was located in this diffusion layer of the tube electrode to selectively detect hydrogen peroxide generated from the enzyme catalytic oxidation of glucose in the presence of oxygen in the solution. In practical performance of the microdevice, parameters influencing the interference-removing efficiency, including the tip-tube opening distance, the tube electrode potential and the electrolyzing time had been investigated systematically. Results showed that glucose detection free from interferents could be achieved at the electrolyzing time of 30s, the tip-tube opening distance of 3mm and the tube electrode potential of 0.4V. The electrochemical response showed linear dependence on the concentration of glucose in the range of 1 x 10(-5) to 4 x 10(-3) M (the correlation coefficient: 0.9936, without interferents; 0.9995, with interferents). In addition, the effectiveness of this device was confirmed by numerical simulation using a model system of a solution containing interferents. The simulated results showed good agreement with the experimental data.     

Mediatorless electrocatalytic reduction of hydrogen peroxide at graphite electrodes chemically modified with peroxidases

The electrocatalytic reduction of H₂O₂ was studied for carbonaceous electrodes modified with horse-radish peroxidase (HRP), microperoxidase (MP), and lactoperoxidase (LP). The carbonaceous electrodes were of three different graphites, carbon and glassy carbon. The peroxidase modified electrode was inserted as the working electrode in a flow through amperometric cell of the wall jet type and connected to a flow injection system. The effect of different pretreatments of the electrode surface prior to adsorption of the enzyme was investigated. Heating the electrodes in a muffle furnace at 700°C for 1.5 min was found to yield the highest currents. The electrocatalytic current for HRP-modified electrodes starts at about +600 mV vs. Ag/AgCl (pH 7.0) and reaches a maximum value at about −200 mV. For MP- and LP-modified electrodes the currents start at a lower potential (≈ 300 mV). For the best electrode material for HRP, straight calibration curves were obtained between 1 and 500 μM H₂O₂ at 0 mV. The mechanism for the electron transfer from the electrode to the adsorbed peroxidase is discussed. Deliberate modification of the electrode surface with quinoid type electroactive species was found to mediate the reaction. It is proposed that spontaneously occurring electrochemically active surface groups mediate the electron transfer to the adsorbed enzyme. However, a contribution to the observed current from a direct electron transfer cannot be ruled out.