Amperometric determination of phosphatidyl choline in serum with use of immobilized phospholipase d and choline oxidase

Phospholipase D (EC 3.1.4.4.) and choline oxidase (EC 1.1.99.1.) are immobilized together on a hydrophobic agarose gel and used to convert the phospholipid to betaine and hydrogen peroxide, which is measured amperometrically at + 0.60 V vs. SCE. The response time of the sensor is 2 min, and the calibration curve for 0–3 g l^-1 of phosphatidyl choline is linear. Different methods of insolubilizing the enzymes are compared.     

Amperometric determination of cholinesterase with use of an immobilized enzyme electrode

A choline-sensitive electrode consisting of an immobilized choline oxidase layer and an oxygen electrode is described. Cholinesterase (0.5–60 I.U. l^-1) is measured by addition of acetylcholine, and detection of the choline produced. The precision is 3%, and the electrode is stable for more than 2 weeks (140 assays).     

Immobilized enzymes in clinical and biochemical analysis : Applications to the Simultaneous Determination of Acetylcholine and Choline and to Determination of Lipids

Uses of immobilized enzyme mini-columns in flow-injection systems are described Simultaneous determination of ? × 10^?5 M choline and acetylcholine is achieved by using acetylcholinesterase and choline oxidase columns. A home-made amperometric detector is used to detec the hydrogen peroxide produced enzymatically. An ion-exchange column is used on-line to remove interferences at the amperometric detector during analysis of blood and brain samples. Immobilization of the lipid enzymes phospholipase-C and -D is described. These enzymes are used for the determination of phospholipids. Total phospholipids (1– mM) are determined with a combination of phospholipase-D, lipase and glycerol-3-phosphate oxidase. All the methods described are simple and reproducible and the immobilized enzymes show good stability.     

Amperometric determination of choline and acetylcholine with enzymes immobilized in a photocross-linkable polymer

Choline and acetylcholine sensors were prepared by using choline oxidase and acetylcholinesterase, entrapped in photocross- linkable poly(vinyl alcohol) bearing styrylpyridinium (PVA-SbQ). The measurements were based on the detection of hydrogen peroxide liberated by an enzyme reaction (choline oxidase) or two sequential enzyme reactions (acetylcholine esterase and choline oxidase). The determination range for choline was 2.5-2-150 αmol 1^-1 and for acetylcholine 20-2-750 αmol 1^-1. The response times were 2-2-4 min. The immobilized enzyme membranes stored in a dry state were very stable and no loss of activity was observed after storage for 60 days.     

Bioelectrochemical response of a choline biosensor fabricated by using polyaniline

On the basis of the isoelectric point of an enzyme and the doping principle of conducting polymers, choline oxidase was doped in a polyaniline film to form a biosensor. The amperometric detection of choline is based on the oxidation of the H₂O₂ enzymatically produced on the choline biosensor. The response current of the biosensor as a function of temperature was determined from 3 to 40°C. An apparent activation energy of 22.8 kJ·mol⁻¹ was obtained. The biosensor had a wide linear response range from 5 × 10⁻⁷ to 1 × 10⁻⁴ M choline with a correlation coefficient of 0.9999 and a detection limit of 0.2 μM, and had a high sensitivity of 61.9 mA·M⁻¹·cm⁻² at 0.50 V and at pH 8.0. The apparent Michaelis constant and the optimum pH for the immobilized enzyme are 1.4 mM choline and 8.4, respectively, which are very close to those of choline oxidase in solution. The effect of selected organic compounds on the response of the choline biosensor was studied.     

Amperometrische Biosensoren zur Bestimmung von Cholin und Acetylcholin

Summary Amperometric biosensors for the determination of choline and acetylcholine were constructed by coupling immobilized choline oxidase or choline oxidase and acetylcholinesterase membrane with an electrode. H₂O₂ which results from the oxidase reaction is anodically monitored. The sensors' response is linear in the concentration range of 1 to 300 mol/l choline and 1 to at least 660 mol/l acetylcholine. The sample frequency is 60 h^–1 with an imprecision of less than 2% for both choline and acetylcholine. The longtime-stability of the sensors was tested to be more than 22 days. The influence of the reversible inhibitor NaF on the bienzyme-electrode response was investigated.     

Electrochemical studies on tetrathiafulvalene-tetracyanoquinodimethane modified acetylcholine/choline sensor

A sensor for acetylcholine/choline is described using a tetrathiafulvalene-tetracyanoquinodimethane (TTF-TCNQ) electrode modified with acetylcholine esterase (AChE) and choline oxidase (ChO) enzymes. DC cyclic voltammetry and impedance measurements of the enzyme-modified TTF-TCNQ electrode that indicate the regeneration of choline oxidase at the electrode surface are reported. Effective electrochemical rate constants for the present enzyme electrode are calculated using the expressions derived by Albery et al. (1), which show the enzyme kinetics as the rate-limiting step. The values of the effective electrochemical rate constants are close to those reported by Hale and Wightman (2). The application of the sensor is described for the determination of fluorode ion and nicotine based on the reversible inhibition of AChE activity. The range of detection of fluoride ion and nicotine is found to be 5×10^-6 to 5×10^-4M.     

Bienzyme Electrode Compatible Behavior for Water-Soluble and-Insoluble Substrates

Abstract

A bienzymatic sensing layer containing two enzymes able to work sequentially, choline oxidase (ChOD) and phospholipase D (PLaseD), was used to design an electrochemical biosensor for the detection of either a water-soluble (choline) or insoluble (phosphatidylcholine) substrate. A photocrosslinkable polymer, poly(vinyl alcohol) bearing styrylpyridinium groups (PVA-SbQ), was used as host-matrix for enzyme immobilization. Controlled amounts of PVA-SbQ and of the two enzymes were directly coated on a platinum disk, then photopolymerized. The compatibility of working conditions for choline and phosphatidylcholine detection in the presence of Triton X-100 and CaCl₂ was investigated. The effect of the activity ratio PLaseD / ChOD on the sensor performance was determined. The sensitivities to choline and to phosphatidylcholine were 18 mA.1mol^?1 and 0.66 mA.1.mol^?1 respectively, the detection limit being 1.5.10^?8 M for choline and 1.5.10^?6 M for phosphatidylcholine. The linear range extended up to ca. 10^?4 M for choline and ca. 2.10^?5 M for phosphatidylcholine and the response time was close to 30 seconds for choline and ca. 2 min for phosphatidylcholine.     

A homogeneous assay principle for universal substrate quantification via hydrogen peroxide producing enzymes

H₂O₂ is a widely occurring molecule which is also a byproduct of a number of enzymatic reactions. It can therefore be used to quantify the corresponding enzymatic substrates. In this study, the time-resolved fluorescence emission of a previously described complex consisting of phthalic acid and terbium (III) ions (PATb) is used for H₂O₂ detection. In detail, glucose oxidase and choline oxidase convert glucose and choline, respectively, to generate H₂O₂ which acts as a quencher for the PATb complex. The response time of the PATb complex toward H₂O₂ is immediate and the assay time only depends on the conversion rate of the enzymes involved. The PATb assay quantifies glucose in a linear range of 0.02–10 mmol L⁻¹, and choline from 1.56 to 100 μmol L⁻¹ with a detection limit of 20 μmol L⁻¹ for glucose and 1.56 μmol L⁻¹ for choline. Both biomolecules glucose and choline could be detected without pretreatment with good precision and reproducibility in human serum samples and infant formula, respectively. Furthermore, it is shown that the detected glucose concentrations by the PATb system agree with the results of a commercially available assay. In principle, the PATb system is a universal and versatile tool for the quantification of any substrate and enzyme reaction where H₂O₂ is involved.     

Biochemical sniffer with choline oxidase for measurement of choline vapour

An enzyme-based gas sensor (bio-sniffer) for choline vapour was fabricated and tested. The bio-sniffer was constructed using a Clark-type dissolved oxygen electrode and an enzyme (choline oxidase) immobilized membrane. This bioelectronic device measures choline concentration by the oxygen consumption induced by an enzyme reaction of choline oxidase. As the assessment of sensor performances, the calibration curves for choline in the liquid and gas phases were investigated, respectively. The responses of the bioelectronic device to choline solutions of various concentrations were related within a range from 5.00 to 700 μmol·L⁻¹ with a correlation coefficient of 0.999. On the other hand, the bio-sniffer for choline vapour was placed into a gas-measuring chamber and calibrated using gas detection tubes. The calibration range was 1.00–30.0 ppm (correlation coefficient: 0.996). The response time for choline vapour was approximately 15% slower than that of biosensor for choline solution. These results indicate that the bio-sniffer is useful to monitor colourless and odourless choline gas released from coating compositions including choline. Correspondence: Kohji Mitsubayashi, Department of Biomedical Devices and Instrumentation, Institute of Biomaterials and Bioengineering, Tokyo Medical and Dental University, 2-3-10 Kanda-Surugadai, Chiyoda-ku, Tokyo 101-0062, Japan     

Inhibition biosensor for determination of nicotine

An amperometric nicotine inhibition biosensor has been substantially simplified and used for determination of nicotine in tobacco sample. Besides the use of single enzyme choline oxidase to replace bienzyme, the use of 1,4-benzoquinone as an electron mediator makes it possible to avoid the use of oxygen or hydrogen peroxide sensor as the internal transducer. Choline oxidase was immobilized on the carbon paste electrode through cross-linking with bovine serum albumin (BSA) by glutaraldehyde. In the presence of choline oxidase and its endogenous cofactor flavin-ademine dinneleotide (FAD), choline was oxidized into betaine while FAD was reduced to FADH₂ which subsequently reduced 1,4-benzoquinone into hydroquinone. The later was finally oxidized at a relatively low potential of +450 mV versus saturated calomel electrode (SCE). Nicotine inhibits the activity of enzyme with an effect of decreasing of oxidation current. The experimental conditions were optimized. The electrode has a linear response to choline within 1.25×10⁻⁴ to 1.25×10⁻³ mol l⁻¹. The nicotine measurements were carried out in 0.067 mol l⁻¹phosphate buffer of pH 7.4 at an applied potential of 450 mV versus SCE. The electrode provided a linear response to nicotine over a concentration range of 2.0×10⁻⁵ to 9.2×10⁻⁴ mol l⁻¹ with a detection limit of 1.0×10⁻⁵ mol l⁻¹. The system was applied to the determination of nicotine in tobacco samples.     

Prussian Blue-Based Thin-Layer Flow-Injection Multibiosensor for Simultaneous Determination of Glucose and Lactate

A planar multibiosensor for the simultaneous determination of glucose and lactate is developed by combining the Prussian Blue-based electrocatalyst and the protocol for immobilization of glucose oxidase and lactate oxidase enzymes from solutions with a high content of an organic solvent. High sensitivity coefficients (>80 mA M^–1 cm^–2 for lactate and >20 mA M ^–1 cm^–2 for glucose) are demonstrated by the multibiosensors operating in the flow-injection mode in a thin-layer measuring cell. The linear range of the analyzed concentration is 1–500 μM for lactate and 5–1000 μM for glucose. A multibiosensor can be used repeatedly (the exhibited operational stability is not less than 100 measurements without the need for recalibration), which allows using it for the analysis of diluted blood samples and blood serum. The electrocatalytic system with a multibiosensor demonstrates performance characteristics that are superior to the commercial analyzers.     

A Highly Sensitive Electrochemiluminescence Choline Biosensor Based on Poly(aniline‐luminol‐hemin) Nanocomposites

Poly(aniline‐luminol‐hemin) nanocomposites are prepared on an electrode surface through electropolymerization, and a highly sensitive electrochemiluminescence (ECL) biosensor for choline is developed based on the poly(aniline‐luminol‐hemin) nanocomposites and an enzyme catalyzed reaction of choline oxidase (CHOD). The obtained nanocomposites are characterized by scanning electron microscopy (SEM), atomic absorption spectrometry (AAS) and ECL. The results indicate that hemin can be incorporated into the poly(aniline‐luminol) nanocomposites using the facile electropolymerization method, and the poly(aniline‐luminol‐hemin) nanocomposites are rod shaped porous nanostructure. Moreover, the poly(aniline‐luminol‐hemin) nanocomposites exhibit higher ECL intensity than poly(aniline‐luminol) nanocomposites in alkaline media due to the catalytic effect of hemin on the ECL of the polymerized luminol and the electron transfer ability of hemin in the nanocomposites. CHOD is immobilized on the surface of the poly(aniline‐luminol‐hemin) nanocomposites modified electrode with glutaraldehyde, and the ECL biosensor based on poly(aniline‐luminol‐hemin)/CHOD exhibits a wider linear range for the choline detection. The enhanced ECL signals are linear with the logarithm of concentration of choline over the range of 1.0×10^?11～1.0×10^?7 mol L^?1 with a low detection limit of 1.2×10^?12 mol L^?1. Moreover, the proposed biosensor is successfully applied to the detection of choline in milk.     

Simple determination of betaine,l‐carnitine and choline in human urine using self‐packed column and column‐switching ion chromatography with nonsuppressed conductivity detection

A sequential online extraction, clean‐up and separation system for the determination of betaine, l ‐carnitine and choline in human urine using column‐switching ion chromatography with nonsuppressed conductivity detection was developed in this work. A self‐packed pretreatment column (50 × 4.6 mm, i.d.) was used for the extraction and clean‐up of betaine, l ‐carnitine and choline. The separation was achieved using self‐packed cationic exchange column (150 × 4.6 mm, i.d.), followed by nonsuppressed conductivity detection. Under optimized experimental conditions, the developed method presented good analytical performance, with excellent linearity in the range of 0.60–100 μg mL⁻¹ for betaine, 0.75–100 μg mL⁻¹ for l ‐carnitine and 0.50–100 μg mL⁻¹ for choline, with all correlation coefficients (R²) >0.99 in urine. The limits of detection were 0.15 μg mL⁻¹ for betaine, 0.20 μg mL⁻¹ for l ‐carnitine and 0.09 μg mL⁻¹ for choline. The intra‐ and inter‐day accuracy and precision for all quality controls were within ±10.32 and ±9.05%, respectively. Satisfactory recovery was observed between 92.8 and 102.0%. The validated method was successfully applied to the detection of urinary samples from 10 healthy people. The values detected in human urine using the proposed method showed good agreement with the measurement reported previously.     

Amperometric Choline Sensor with Enzyme Immobilized by Gamma-Irradiation in a Biocompatible Membrane

Abstract

An amperometric choline biosensor was constructed using choline oxidase immobilized on poly(2-hydroxyethylmethacrylate) membranes obtained by gamma radiation-induced polymerization at low temperature. The measurements were carried out by Clark-type oxygen or hydrogen peroxide electrodes. Calibration curves were linear in the 10-200 umol · 1^?1 range for the oxygen probe and 5-250 umol · 1^?1 for the H₂O₂-based probe. Temperature and pH effects on the activity of immobilized enzyme are described and the response characteristics of the sensor are summarized. The immobilized enzyme membranes stored in glycine buffer or in a dry state were very stable and no significant decrease in the electrode response was observed after three months. The biosensor was employed also to analyse a choline-containing pharmaceutical product and the results were compared to those obtained by enzymatic-spectrophotometric detection.     

Accelerating the electron transfer of choline oxidase using ionic-liquid/NH2-MWCNTs nano-composite

A nano-composite consisting of amine functionalized multi-walled carbon nanotubes and a room temperature ionic liquid (1-butyl-3-methylimidazolium tetrafluoroborate) was prepared and used for modification of glassy carbon electrode. By immobilizing choline oxidase (ChOx) on the modified electrode, the enzyme direct electron transfer has been achieved. The modified electrode exhibited a pair of well-defined cyclic voltammetric peaks at a formal potential of ?0.395?V versus Ag/AgCl in 0.2?M phosphate buffer solution at pH 7.0. This peak was characteristic of ChOx-FAD/FADH₂ redox couple. The electrochemical parameters such as charge transfer coefficient (??) and apparent heterogeneous electron transfer rate constant (k _s) were estimated to be 0.36 and 2.74?s^?1, respectively. When the enzyme electrode was examined for the detection of choline, a relatively high sensitivity (2.59???A?mM^?1) was obtained. Under the optimized experimental conditions, choline was detected in the concentration range from 6.9?×?10^?3 to 6.7?×?10^?1?mM with a detection limit of 2.7???M. The peak currents of ChOx were reasonably stable and retained 90% of its initial current after a period of 2?months.     

Sensitive biosensor for choline and acetylcholine involving fast immobilization of a bienzyme system on a disposable membrane

A biosensor was prepared for the determination of choline or acetylcholine by co-immobilizing choline oxidase and cholinesterase on a chemically preactivated membrane ready for use. This rapid procedure allows the coupling to be performed in a few minutes. The determination is based on the electrochemical detection of enzymatically generated hydrogen peroxide. This sensor has a detection limit of 5 × 10^?8 M. The response was obtained in 2 min and was linear up to 2 × 10^?5 M.     

A Complete Electroenzymatic Choline Microprobe Based on Nanostructured Platinum Microelectrodes and an IrOx On‐probe Reference Electrode

A microelectrode array microprobe with a choline sensing site and an on‐probe reference electrode was constructed by depositing permselective polymer films and choline oxidase (ChOx) on one microelectrode, and iridium oxide (IrOx) on another, both of which were coated previously with a nanostructured Pt deposit. Scanning electron microscopy (SEM) of the nanostructured Pt layer revealed a unique pillar‐like, “nanograss” structure. Polyphenylenediamine (PPD) and Nafion were coated sequentially on the working (i. e. sensing) electrode surface to serve as the permselective polymer films. The microsensor exhibited high sensitivity to choline (123±13 μA mM^?1 cm^?2), low detection limit (3.2±0.8 μM), and fast response time (3–5 s). The choline sensor also was tested at physiological concentrations of electroactive interfering species common to brain extracellular fluid (i. e. ascorbic acid, dopamine, DOPA, and DOPAC) and showed excellent selectivity. Selectivity likely was aided by the relatively low potential of 0.35 V vs. IrOx that was made possible by the enhanced H₂O₂ electrooxidation activity of the underlying nanostructured Pt‐coated working electrode. Thus, Pt “nanograss” appears to be an excellent electrode surface modification for creation of high performance electroenzymatic biosensors.     

Amperometric choline biosensors prepared by layer-by-layer deposition of choline oxidase on the Prussian blue-modified platinum electrode

An amperometric choline biosensor was developed by immobilizing choline oxidase (ChOx) in a layer-by-layer (LBL) multilayer film on a platinum (Pt) electrode modified with Prussian blue (PB). 6-O-Ethoxytrimethylammoniochitosan chloride (EACC) was used to prepare the ChOx LBL films. The choline biosensor was used at 0.0 V versus Ag/AgCl to detect choline and exhibited good characteristics such as relative low detection limit (5 × 10⁻⁷ M), short response time (within 10 s), high sensitivity (88.6 μA mM⁻¹ cm⁻²) and a good selectivity. The results were explained based on the ultrathin nature of the LBL films and the low operating potential that could be due to the efficient catalytic reduction of H₂O₂ by PB. In addition, the effects of pH, temperature and applied potential on the amperometric response of choline biosensor were evaluated. The apparent Michaelis-Menten constant was found to be (0.083 ± 0.001) ×10⁻³ M. The biosensor showed excellent long-term storage stability, which originates from a strong adsorption of ChOx in the EACC multilayer film. When the present choline biosensor was applied to the analysis of phosphatidylcholine in serum samples, the measurement values agreed satisfactorily with those by a hospital method.     

Highly sensitive choline biosensor based on carbon nanotube-modified Pt electrode combined with sol-gel immobilization

A novel amperometric choline biosensor has been fabricated with choline oxidase (ChOx) immobilized by the sol-gel method on the surface of multi-walled carbon nanotubes (MWCNT) modified platinum electrode to improve the sensitivity and the anti-interferential property of the sensor. By analyzing the electrocatalytic activity of the modified electrode by MWCNT, it was found that MWCNT could not only improve the current response to H₂O₂ but also decrease the electrocatalytic potential. The effects of experimental variables such as the buffer solutions, pH and the amount of loading enzyme were investigated for the optimum analytical performance. This sensor shows sensitive determination of choline with a linear range from 5.0 × 10⁻⁶ to 1.0 × 10⁻⁴ mol/L when the operating pH and potential are 7.2 and 0.15 V, respectively. The detection limit of choline was 5.0 × 10⁻⁷ mol/L. Selectivity for choline was 9.48 μA·(mmol/L)⁻¹. The biosensor exhibits excellent anti-interferential property and good stability, retaining 85% of its original current value even after a month. It has been applied to the determination of choline in human serum. Translated from Chinese Journal of Analytical Chemistry, 2006, 34(7): 910–914 (in Chinese)