Oxygen-stabilized enzyme electrode for d-glucose analysis in fermentation broths

A new principle for the construction of oxygen-dependent enzyme electrodes is presented. The enzyme electrode is based on a galvanic oxygen electrode which is furnished with an electrolysis anode covered by immobilized enzyme and placed close to the oxygen-sensing surface. An ordinary oxygen electrode is used as a reference electrode. The enzymatic consumption of oxygen in the enzyme electrode generates a potential difference between the electrodes which is utilized to control electrolytic generation of oxygen from water in such a way that zero differential potential is maintained. Thus, the enzyme electrode operates under ambient oxygen tension and does not suffer from oxygen limitation. The electrolytic current in this system gives a measure of the concentration of substrate surrounding the enzyme electrode. The electrode has been applied for continuous d-glucose analysis in situ during batch cultures of Candida utilis.     

Real-Time Dynamic Adsorption Processes of Cytochrome c on an Electrode Observed through Electrochemical High-Speed Atomic Force Microscopy

An understanding of dynamic processes of proteins on the electrode surface could enhance the efficiency of bioelectronics development and therefore it is crucial to gain information regarding both physical adsorption of proteins onto the electrode and its electrochemical property in real-time. We combined high-speed atomic force microscopy (HS-AFM) with electrochemical device for simultaneous observation of the surface topography and electron transfer of redox proteins on an electrode. Direct electron transfer of cytochrome c (cyt c) adsorbed on a self-assembled monolayers (SAMs) formed electrode is very attractive subject in bioelectrochemistry. This paper reports a real-time visualization of cyt c adsorption processes on an 11-mercaptoundecanoic acid-modified Au electrode together with simultaneous electrochemical measurements. Adsorbing cyt c molecules were observed on a subsecond time resolution simultaneously with increasing redox currents from cyt c using EC-HS-AFM. The root mean square roughness (R_RMS) from the AFM images and the number of the electrochemically active cyt c molecules adsorbed onto the electrode (Γ) simultaneously increased in positive cooperativity. Cyt c molecules were fully adsorbed on the electrode in the AFM images when the peak currents were steady. This use of electrochemical HS-AFM significantly facilitates understanding of dynamic behavior of biomolecules on the electrode interface and contributes to the further development of bioelectronics.     

Nanowire-Based Electrode for Acute In Vivo Neural Recordings in the Brain

We present an electrode, based on structurally controlled nanowires, as a first step towards developing a useful nanostructured device for neurophysiological measurements in vivo. The sensing part of the electrode is made of a metal film deposited on top of an array of epitaxially grown gallium phosphide nanowires. We achieved the first functional testing of the nanowire-based electrode by performing acute in vivo recordings in the rat cerebral cortex and withstanding multiple brain implantations. Due to the controllable geometry of the nanowires, this type of electrode can be used as a model system for further analysis of the functional properties of nanostructured neuronal interfaces in vivo.     

Electrode System for the Determination of Microbial Populations

Determinations of microbial populations were carried out by using a new electrode system composed of two electrodes. Each electrode was constructed from a platinum anode and a silver peroxide cathode. The anode of the reference electrode was covered with cellulose dialysis membrane. The response time of the electrode system was 15 min in culture broth, and current differences between the two electrodes were proportional to populations of microbial cells in cultures of Saccharomyces cerevisiae and Lactobacillus fermentum. Current differences were reproducible; the average relative error was 5%. Furthermore, cell populations of S. cerevisiae in a fermentor could be continuously estimated by using this electrochemical method.     

Characteristics of a Pulse-Periodic Corona Discharge in Atmospheric Air

Pulse-periodic corona discharge in atmospheric air excited by applying a voltage pulse with a subnanosecond or microsecond rise time to a point electrode is studied experimentally. It is shown that, at a voltage rise rate of dU/dt ~10¹⁴ V/s, positive and negative ball-shaped streamers with a front velocity of ≥2 mm/ns form near the point electrode. As dU/dt is reduced to 10¹⁰?10¹¹ V/s, the streamer shape changes and becomes close to cylindrical. The propagation velocity of cylindrical streamers is found to be ~0.1 mm/ns at dU/dt ~ 2 × 10¹⁰ V/s. It is shown that the propagation direction of a cylindrical streamer can be changed by tilting the point electrode, on the axis of which the electric field strength reaches its maximum value. It is established that, for the negative polarity of the point electrode and a microsecond rise time of the voltage pulse, a higher voltage is required to form a cylindrical streamer than for the positive polarity of the point electrode.     

An international comparability study on quantification of total methyl cytosine content

A novel biocomposite film (MWCNTs-PNDGAChi), which contains multiwalled carbon nanotubes (MWCNTs) along with the incorporation of poly(nordihydroguaiaretic acid) and chitosan copolymer (PNDGAChi), has been synthesized on gold electrode by potentiostatic methods. The presence of MWCNTs in the biocomposite film enhances PNDGAChi’s surface coverage concentration (Γ) on the electrode and decreases degradation of PNDGAChi during cycling. The biocomposite film also exhibits promising enhanced electrocatalytic activity toward the oxidation of biochemical compounds such as epinephrine (EP) and norepinephrine (NEP). Cyclic voltammetry was used for the measurement of electroanalytical properties of analytes by means of MWCNTs-PNDGAChi biocomposite film modified gold electrode. The sensitivity values of MWCNTs-PNDGAChi biocomposite film modified gold electrode are higher than the values obtained for PNDGAChi film modified gold electrode. Electrochemical quartz crystal microbalance studies reveal the enhancements in the functional properties of MWCNTs and PNDGAChi present in MWCNTs-PNDGAChi biocomposite film. Surface morphology of the biocomposite films was studied using scanning electron microscopy, atomic force microscopy, and scanning tunneling microscopy. The surface morphology results reveal that PNDGAChi incorporated on MWCNTs. Finally, flow injection analysis was used for the amperometric detection of EP and NEP at MWCNTs-PNDGAChi film modified screen printed carbon electrode.     

Non-contacting electrode system for the measurement of strain generated potentials in bone

Current methods employing contact electrodes for the measurement of the electromechanical properties of bone produce errors in the measurement due to the effects of polarization at the bone-electrode interface, and the flow of electric charges in the bone measuring circuit. In addition, signal artefacts may result from the movement of an electrode in contact with a specimen undergoing mechanical deformation. The principles for a non-contacting method, based on charge induction on a conductive plate placed in the field of a charged body (bone), and the resulting non-contacting electrode system are presented in this paper. The new electrode enabled measurement of strain generated potentials (SGP) in bone with minimal effect from the measuring circuit and provided new results previously masked by contacting measurement methods. Furthermore, the new electrode is a potential tool for further investigation of the in vitro electromechanical behaviour of bone, particularly in partially hydrated specimens and in vivo, thereby avoiding invasive methods or use of ionizing radiation.     

Evidence for Involvement of an Electron Shuttle in Electricity Generation by Geothrix fermentans

In experiments performed using graphite electrodes poised by a potentiostat (+200 mV versus Ag/AgCl) or in a microbial fuel cell (with oxygen as the electron acceptor), the Fe(III)-reducing organism Geothrix fermentans conserved energy to support growth by coupling the complete oxidation of acetate to reduction of a graphite electrode. Other organic compounds, such as lactate, malate, propionate, and succinate as well as components of peptone and yeast extract, were utilized for electricity production. However, electrical characteristics and the results of shuttling assays indicated that unlike previously described electrode-reducing microorganisms, G. fermentans produced a compound that promoted electrode reduction. This is the first report of complete oxidation of organic compounds linked to electrode reduction by an isolate outside of the Proteobacteria.     

Construction and analytical applications of liquid membrane electrode for trinitrobenzenesulfonic acid (TNBS)

A new liquid membrane electrode which responds to trinitrobenzenesulfonate (TNBS^?) ion is described. The electrode exhibits very good experimental characteristics: (i) The working pH range is 2.0–12.5; (ii) its response is consistent with the Nernst equation in the range 1.10^?1–5.10^?5m; (iii) its response time is 5 s; and (iv) its selectivity for TNBS^? against 14 tested ions is very high. Ions such as $\text{ClO}{}_4{}^{\mathrm{?}}$, $\text{IO}{}_4{}^{\mathrm{?}}$, I^?, and biphthalates interfere with potentiometric selectivity coefficients in the range 1.0 × 10^?2–9.0 × 10^?2. The electrode is suitable for direct potentiometry, potentiometric titrations, and kinetic potentiometric methods. Instructions for the application of the electrode for the potentiometric assay of aminoacids are given. The application of the electrode in the potentiometric precipitation titration of methylene blue with TNBS, and its use in the kinetic potentiometric determination of aminoacids is also described. The electrode has very good slope stability (60 mV/decade change of activity) for a period ofat least 2 months.     

Monoamine oxidase electrode in freshness testing of meat

Monoamine oxidase (monoamine: oxygen oxidoreductase, EC 1.4.3.4 from Aspergillus niger and beef plasma) was immobilized in a collagen membrane. An enzyme electrode consisting of a monoamine oxidase - collagen membrane (10 units) and an oxygen electrode was prepared for the determination of monoamines. Monoamines were oxidized to aldehydes by the immobilized enzyme and oxygen consumption was monitored amperometrically by the oxygen electrode. The response time of the electrode was 4 min. The optimum conditions for the enzyme electrode were pH 7.4 and 30°C. A linear relationship was observed between the amine (tyramine) concentration in the range 50–200 μm and the difference in current. No decrease in the output current was observed over an observation period of one week. The difference in current was reproducible with an average relative error of 8%. Monoamines in meat extracts were determined by the enzyme electrode.     

A refined technique to apply electrical currents to callus cultures

A simple, inexpensive technique is described which can be used to pass small electrical currents of a few microamperes through callus cultures under sterile conditions without contaminating the tissue or the medium with electrode products. Application of 1 or 2 microamperes currents of either polarity stimulated growth as well as shoot regeneration in tobacco (Nicotiana tabacum var. virginica) callus cultures, indicating that these effects are due to the electrical fields set up by the exogenous currents, rather than by electrode products.     

Compensation for measuring error produced by finite response time in determination of rates of oxygen consumption with a Clark-type polarographic electrode

In the determination of the rates of oxygen consumption with a Clark-type oxygen electrode, and experimental error is caused by finite response time of the oxygen electrode for a rapid oxidation reaction. A theoretical equation between the observed pseudo first-order rate constant (k_obs) and the true rate constant (k)

$\text{1}\text{k}{}_{\mathrm{obs}}\text{=}\text{1}\text{k}\text{+T}$

where T is a time constant for a first-order response of the oxygen electrode, was derived and found to hold up to k = 23 min^?1 in oxidation of hydroquinone at pH 7.60–8.63.     

The electrochemistry of a surface modified, cationic, tetra-(N-methyl)pyridiniumporphyrazinocopper electrode

The surface electrochemistry of a graphite electrode surface modified with cationic, tetra-(N-methyl)pyridiniumporphyrazinocopper is reported. The surface deposited species is spontaneously reduced by one electron by the electron rich graphite surface. Several concerted two-electron processes are recorded. A Pourbaix diagram is used to display the various species that can be identified on the surface with change of electrode polarization and pH of the electrolyte.     

Calculation of optical signal using three-dimensional bidomain/diffusion model reveals distortion of the transmembrane potential

Optical mapping experiments allow investigators to view the effects of electrical currents on the transmembrane potential, V_m, as a shock is applied to the heart. One important consideration is whether the optical signal accurately represents V_m. We have combined the bidomain equations along with the photon diffusion equation to study the excitation and emission of photons during optical mapping of cardiac tissue. Our results show that this bidomain/diffusion model predicts an optical signal that is much smaller than V_m near a stimulating electrode, a result consistent with experimental observations. Yet, this model, which incorporates the effect of lateral averaging, also reveals an optical signal that overestimates V_m at distances >1 mm away from the electrode. Although V_m falls off with distance r from the electrode as exp(−r/λ)/r, the optical signal decays as a simple exponential, exp(−r/λ). Moreover, regions of hyperpolarization adjacent to a cathode are emphasized in the optical signal compared to the region of depolarization under the cathode. Imaging methods utilizing optical mapping techniques will need to account for these distortions to accurately reconstruct V_m.     

Electrochemical measurement of intraprotein and interprotein electron transfer

Intramolecular and intermolecular direct (unmediated) electron transfer was studied by electrochemical techniques in a flavohemoprotein cytochrome P450 BM3 (CYP102A1 from Bacillius megaterium) and between cytochromes b ₅ and c. P450 BM3 was immobilized on a screen printed graphite electrode modified with a biocompatible nanocomposite material based on didodecyldimethylammonium bromide (DDAB) and gold nanoparticles. Analytical characteristics of SPG/DDAB/Au/P450 BM3 electrodes were studied with cyclic voltammetry and square wave voltammetry. The electron transport chain in P450 BM3 immobilized on the nanostructured electrode is: electrode → FAD → FMN → heme; i.e., electron transfer takes place inside the cytochrome, in evidence of functional interaction between its diflavin and heme domains. The effects of substrate (lauric acid) or inhibitor (metyrapone or imidazole) binding on the electro-chemical parameters of P450 BM3 were assessed. Electrochemical analysis has also demonstrated intermolecular electron transfer between electrode-immobilized and soluble cytochromes properly differing in redox potentials.     

Microbore high-performance liquid chromatographic method for measuring acetylcholine in microdialysis samples: optimizing performance of platinum electrodes

A microbore high-performance liquid chromatographic method with electrochemical detection was applied to the measurement of acetylcholine in microdialysis samples. There was an excellent linear relationship (r=0.99998) between the concentration of acetylcholine injected onto the column and the peak height (0.05–10 pmol/5 μl). During the validation of this method, we noticed that the peak height for acetylcholine decreased over time, coupled with the appearance of a brown coating on the surface of the platinum electrode. Repeated measurement of acetylcholine standards which had been stored at 4°C and −20°C before and after cleaning the platinum electrode with ethanol or methanol indicated that the decrease in the peak height of acetylcholine is caused by a decrease in sensitivity of the electrode itself. Results with a second microbore high-performance liquid chromatographic system confirmed these findings. On the basis of these results, we recommend that the platinum electrode is cleaned periodically with ethanol or methanol, and that quantitation is regularly calibrated with external acetylcholine.     

A PVC-based electrode sensitive to DDA+ as a device for monitoring the membrane potential in biological systems

A polyvinyl chloride (PVC)-based membrane electrode sensitive to dibenzyldimethyl ammonium cation (DDA⁺) was constructed, and operational parameters such as the selectivity coefficients, the detection limit, and the response time were obtained. In comparison with the selectivity coefficients obtained with the previous liquid-membrane electrode, significant improvement was not obtained, but the response time became pronouncedly shorter. Furthermore, the electrode lifetime was remarkably prolonged. With the electrode developed, the change in the membrane potential of liposomes containing dibutyl ferrocene which separated oxidizing and reducing agent solutions was measured. The DDA⁺ uptake, U, and the membrane potential estimated from U changed in accordance with the redox potential in the medium when the concentration of internal ferricyanide was kept constant. The membrane potential collapsed when the uncoupler of oxidative phosphorylation was added. The ANS fluorescence measurement indicated that negative charges appeared on energization with oxidizing-reducing agent. The change in membrane potential of mitochondria during energization was also measured. It was found that the liposome described above is a good model for the generation of membrane potentials in mitochondria.     

Intracellular pH electrode : Experiments on the giant squid axon

A new, easy method to produce and calibrate a 1-μm tip intracellular pH electrode is described. This antimony electrode and a micro-calomel electrode were inserted into the giant axon of Loligo pealii. The potential obtained when the axon was bathed in seawater corresponded to a pH of 7.0 ± 0.2. It was found that acidification of the external perfusate induced a drop in axoplasmatic pH leading to changes in the membrane electrical properties. Changes of resting or action potentials did not influence intracellular pH.     

A simple and continuous assay for decarboxylase activity using a carbon dioxide-selective electrode

A carbon dioxide electrode has been used for kinetic studies of decarboxylase activity. The methodology used requires only a sensitive pH meter operating in the millivolt mode with the electrode. The CO₂ release may be followed continuously. Compared to other assay procedures the method outlined offers the advantages of rapidity, continuity, specificity, and sufficient precision. Techniques for the calibration of the electrode response are discussed. The applicability of this assay was appraised by determining the K_m of lysine decarboxylase. The value obtained showed good agreement with that reported in literature. The procedure might be useful for the study of enzyme-inhibitor interactions.