Pulsed amperometric detection of sulfur-containing pesticides in reversed-phase liquid chromatography

Pulsed amperometric detection at a gold electrode is demonstrated for the separation of eight sulphur-containing pesticides on a C-18 reversed-phase column with 50% (v/v) acetonitrile in acetate buffer (pH 5.0) as the mobile phase. Detection was based on a two-step potential waveform with adsorption of the analyte during cathodic polarization and subsequent amperometric detection catalyzed by oxide formation following anodic polarization. The mechanism of the anodic detection involves prior adsorption of the sulfur compounds. Hence, the shape of the calibration curve is strongly influenced by the adsorption isotherm of the analyte and, therefore, deviates from linearity at high concentrations. Detection limits below 100 ng ml^?1 in 20-μl samples (e.g., 0.8 ng of dimethoate) were obtained by using preconcentration from a larger sample onto a C-18 fore column prior to injection into the separation column.     

The Direct Electrochemical Detection of Amino Acids at a Platinum Electrode in an Alkaline Chromatographic Effluent

Abstract

It is the general experience that most organic compounds including amino acids do not produce reversible or even quasi-reversible anodic waves at a Pt electrode under conditions of conventional cyclic voltammetry. Furthermore, amperometric detection of these compounds at a constant electrode potential is not successful because of the accumulation of adsorbed reaction products and/or an oxide film at the electrode surface. However, it is observed that a Pt electrode surface is cleaned quite effectively of adsorbed organic molecles and radicals simultanaeously with the anodic formation of the oxide layer. This oxidation of adsorbed organic species is concluded to be electrocatalyzed by PtOH formed as the first step in the production of the oxide layer (PtO). A pulsed-potential waveform applied at a frequency of ca. 1 Hz is demonstrated to provide direct amperometric detection of adsorbed amino acids at a Pt electrode. Satisfactory analytical precision (i.e., < 3% rel. std. dev.) results because the waveform reproducibly generates the catalytically active surface state at the Pt electrode. Both primary and secondary amino acids are determined with satisfactory detection limits: e.g., ca. 13 ng for glycine, 7 ng for phenylamine and 23 ng for hydroxyproline in 50-μL samples. Analytical response is concluded to depend on the adsorption isotherm of the amino acid being detected. Hence, the calibration plot of I/I_peak vs. 1/C^D is linear for low surface coverages. Results are shown for amperometric detection of a synthetic mixture of amino acids by anion-exchange chromatography using NaOH as the eluent and supporting electrolyte.     

Theory of electrode reactions of redox couples confined to electrode surfaces at monolayer levels: Part II. Cyclic voltammetry and ac impedance measurements

The expression of the current-potential relationship derived in Part I for simple one-step surface redox-electrode reactions of the species confined to electrode surfaces is applied to cyclic voltammetry and the method of faradaic impedance measurements. A method to obtain cyclic voltammograms is presented for a quasi-reversible or general case and equations for reversible and irreversible cyclic voltammograms are derived. The effect of the interaction parameters, W/RT and ΔW^≠/RT, kinetic parameters, Λ and α, and coordination number z on the waveform of the cyclic voltammograms is discussed. An interesting feature in the voltammograms, i.e. the appearance of two peaks, is predicted when W/RT < −2.19 for z = 6 in spite of the simple one-step redox process. Furthermore, equations for the faradaic resistance and capacitance are derived and it is shown that the faradaic impedance is independent of the frequency of ac perturbation.     

An electrochemical and optical study of the rupture and restoration of the passivating HgO multilayer on a dropping mercury electrode in aqueous 1 M NaOH solution at anodic potentials

It is shown that the passivating layer on the surface of a dropping mercury electrode in 1 M NaOH at anodic potentials due to drop growth continuously is being mechanically ruptured and electrochemically repaired. This phenomenon is studied by means of microscopy, reflectometry and polarography. The latter technique allows current spikes to be measured. The relation between faradaic current during such a spike and time is discussed.     

Integrated pulsed amperometry for the analysis of organic compounds

Integrated pulsed amperometric detection (IPAD) was applied for the detection of organic compounds for flow injection analysis. The pulse waveform used in the integrated pulsed amperometry consisted of three steps: detection potential, oxidation potential, and adsorption potential. The pulse waveform was applied to the working electrode as the analyte flowed through the electrochemical cell. Unlike ordinary pulsed amperometry, a faradaic current was integrated over the duration period of the detection potential in the IPAD. Therefore, the total charge was measured by integrating the current after the detection potential was applied. The current for the initial 10 ms, after applying the detection potential, was excluded from the integration due to a large charging current at the initial period. Compared with pulsed amperometry, integrated pulsed amperometry provides a better signal-to-noise ratio and a lower detection limit. This method was applied to the quantitative analysis of thiourea as a representative analyte of organosulfur compounds in a flow injection analysis.     

Bioaccumulation and determination of lead using treated-Pennisetum-modified carbon paste electrode

The present work describes the development and application of a carbon paste electrode modified by treated-Pennisetum setosum for the determination of lead(II) by anodic stripping differential pulse voltammetry. Most experiments were performed using the preconcentration/voltammetry/regeneration scheme. The resulting modified electrode offers a preferential uptake of lead(II) from solutions. Operational conditions, such as percentage treated-Pennisetum loading in the carbon paste, pH of electrolyte solution, ionic strength, preconcentration time, voltammetric waveform and interference are characterized and optimized to allow quantitative determination of lead. The electrode surface can be regenerated by immersing the modified electrode in 0.05 mol l⁻¹ hydrochloric acid for 2 min. For the measurement step, the optimum conditions were acetate buffer pH 5.0 and 0.60 ionic strength with the preconcentration time of 5 min. The modified electrode contained 10% (w/w) treated-Pennisetum. The detection limit (3σ) was 0.01 mg l⁻¹ Pb(II). For 16 preconcentration/measurement/renewal cycles, the responses could be reproduced with a 5.39% relative standard deviation. This method has been be successfully applied to the determination of lead(II) in natural water samples using standard addition method.     

Electrosorptive detection based on double-layer capacitance for selective anion monitoring in ion chromatography : Part 1. Mercury Electrodes

A novel scheme is presented for the detection of selected anions in ion chromatography, based on changes in differential double-layer capacitance, ΔC_d, for a metal electrode at a suitable electrode potential induced by specific anion adsorption. The detector in this liquid chromatography/double-layer capacitance (LC/DLC) arrangement is a hanging or dropping mercury electrode in a large-volume wall-jet configuration. The anions observed to be detected readily by this approach include chloride, bromide, iodide, azide, thiocyanate, and thiosulfate. The relationship between ΔC_d and the analyte concentration can be arranged to be approximately linear at least over the range 1–100 mg l^?1. An attractive feature of the technique is its insensitivity to ionic concentration gradients in the flowing stream. Another virtue of LC/DLC is its selectivity, although it is less sensitive for the detection of complexing anions than amperometric detection based on mercury oxidation. Dual detection schemes are also devised, involving monitoring double-layer capacitance at two potentials or combined with amperometric detection.     

Pulsed amperometric detection of carbohydrates, amines and sulfur species in ion chromatography —the current state of research

A review is given of so-called pulsed amperometric detection at Au and Pt electrodes. Of greatest interest is the application of pulsed amperometric detection for polar aliphatic compounds not easily detected by conventional photometric or fluorometric techniques. The anodic detection mechanisms are electrocatalytic in nature under the control of potential-dependent surface states. Oxidations of carbohydrates at Au electrodes in alkaline media occur in a potential region where a submonolayer of adsorbed hydroxyl radicals (·OH_ads) is formed and speculation is offered on the role of this species in the anodic mechanisms. Very little anodic signal is obtained at Au electrodes for low-molecular-mass n-alcohols; however, a large response is obtained from oxidation of the alcohol moiety of n-alkanolamines. This is attributed to the beneficial effect of adsorption via the amine moiety with the result that the residence time of the molecules at the electrode surface is increased to give a high probability for ultimate oxidation. Amines and sulfur compounds with non-bonded electrons on the N and S atom, respectively, are adsorbed at Au electrodes and are oxidatively desorbed concomitantly with formation of inert surface oxide (AuO). The simultaneous formation of surface oxide produces a large background signal in pulsed amperometric detection. Hence, a modification of the pulsed waveform is described whose application is called integrated pulsed amperometric detection. Applications are shown for pulsed amperometric detection and integrated pulsed amperometric detection in ion chromatography to illustrate strengths of these combined technologies.     

Anodic behaviour of the (222) macrobicyclic ligand on mercury electrode in propylenecarbonate

The anodic behaviour of the free macrobicyclic ligand (222) was examined by various electrochemical techniques on mercury and on platinum electrodes. From results on platinum electrode using cyclic voltammetry it appears that the anodic oxidation of (222) proceeds irreversibly at potentials more positive than +0.7 V (aq. SCE), however, its mechanism could not be determined because the anodic signal was not well developed. Under polarographic conditions a reversible anodic diffusion controlled wave at E_1/2=+0.08 V (aq. SCE) was observed, corresponding to a complex formation of the ligand (222) with the ions of mercury formed by anodic polarization of mercury electrode. In excess of mercuric cations a cathodic wave at slightly more positive potentals was found.     

Anodic‐Stripping Voltammetric Immunoassay for Ultrasensitive Detection of Low‐Abundance Proteins Using Quantum Dot Aggregated Hollow Microspheres

A new anodic‐stripping voltammetric immunoassay protocol for detection of IgG1, as a model protein, was designed by using CdS quantum dot (QD) layer‐by‐layer assembled hollow microspheres (QDHMS) as molecular tags. Initially, monoclonal anti‐human IgG1 specific antibodies were anchored on amorphous magnetic beads preferably selective to capture F_ab of IgG1 analyte from the sample. For detection, monoclonal anti‐human IgG1 (F_c‐specific) antibodies were covalently coupled to the synthesized QDHMS. In a sandwich‐type immunoassay format, subsequent anodic‐stripping voltammetric detection of cadmium released under acidic conditions from the coupled QDs was conducted at an in situ prepared mercury film electrode. The immunoassay combines highly efficient magnetic separation with signal amplification by the multilayered QD labels. The dynamic concentration range spanned from 1.0 fg mL^?1 to 1.0 μg mL^?1 of IgG1 with a detection limit of 0.1 fg mL^?1. The electrochemical immunoassay showed good reproducibility, selectivity, and stability. The analysis of clinical serum specimens revealed good accordance with the results obtained by an enzyme‐linked immunosorbent assay method. The new immunoassay is promising for enzyme‐free, and cost‐effective analysis of low‐abundance biomarkers.     

Third Generation ATP Sensor with Enzymatic Analyte Recycling

For the first time the direct electron transfer of an enzyme ‐ cellobiose dehydrogenase, CDH ‐ has been coupled with the hexokinase catalyzed competition for glucose in a sensor for ATP. To enhance the signal output for ATP, pyruvate kinase was coimmobilized to recycle ADP by the phosphoenolpyruvate driven reaction. The new sensor overcomes the limit of 1 : 1 stoichiometry of the sequential or competitive conversion of ATP by effective enzymatic recycling of the analyte. The anodic oxidation of the glucose converting CDH proceeds at electrode potentials below 0 mV vs. Ag|AgCl thus potentially interfering substances like ascorbic acid or catecholamines do not influence the measuring signal. The combination of direct electron transfer of CDH with the enzymatic recycling results in an interference‐free and oxygen‐independent measurement of ATP in the lower µmolar concentration range with a lower limit of detection of 63.3 nM (S/N=3).     

Determination of the anticancer drug 5-fluorouracil added to blood serum by liquid chromatography with anodic amperometric detection

Liquid chromatography with on-line anodic amperometric detection is used after a liquid/solid extraction step for the determination of the anticancer drug 5-fluorouracil added to blood serum. A detection limit of 15 ng ml^?1 can be achieved. The anodic electrochemical behaviour of the drug at a mercury electrode, which is the basis of the detection principle, is also described. Anodic amperometric detection at a mercury electrode is compared with detection at a glassy carbon electrode in terms of sensitivity, linearity and selectivity.     

Thiol‐Functionalized Silica Thin Film Modified Electrode in Determination of Mercury Ions in Natural Water

The use of a thin thiol‐functionalized silica film modified glassy carbon electrode in the determination of Hg(II) ions in a natural water sample is described. A typical measurement involves two successive steps: a glassy carbon electrode coated with a thin mesoporous silica film containing 10% of mercaptopropyl groups, according to the MPTMS/TEOS ratio in the starting sol‐gel, was first immersed into the accumulation medium for 15 min, then removed, and finally transferred into a detection solution containing KCl 1.0 mol L^?1 where detection was performed by anodic stripping voltammetry. In this medium the previously accumulated Hg²⁺ species complexed by the thiol groups in an open circuit preconcentration step is then directly reduced at ?0.6 V during 60 s prior to be quantified by a differential pulse anodic scan from ?0.6 to 0.3 V (vs. Ag/AgCl). A stripping peak appeared at about ?0.01 V, which is directly proportional to the quantity of the analyte previously accumulated into the film. The best results were obtained under the following conditions: 100 mV pulse amplitude and 10 mV s^?1 scan rate in 1.0 mol L^?1 KCl solution pH 2.0. Using such parameters a linear dynamic range from 1.00 to 10.0×10^?8 mol L^?1 Hg(II) was observed with a limit of detection of 4.3 nmol L^?1 for an accumulation time of 15 min. Hg(II) spiked in a natural water sample was determined between 97.0 and 101.4% mean recovery at 10^?8 mol L^?1 level. The results indicate that this electrode is sensitive and selective for the Hg(II)determination.     

Pulsed amperometric detection of sulfur compounds: Part I. Initial studies of platinum electrodes in alkaline solutions

Conventional voltammetric and amperometric techniques at Pt or Au electrodes have not been considered applicable for quantitative detection of most sulfur compounds. This is the result of the observed loss of electrode activity caused by accumulation of sulfurous adsorbates and surface oxides. Pulsed Amperometric Detection (PAD) at Pt and Au is highly sensitive for the anodic detection of sulfur compounds, organic and inorganic, which adsorb on the electrode surface. The detection of thiourea by PAD at Pt is described here, and is concluded to correspond to the surface-oxide catalyzed oxidation of the sulfur moiety of adsorbed thiourea to sulfate. Results reported here for detection in a flow-injection system (FI/PAD) produce linear calibration plots of I_p vs. c^b at low concentration and linear plots of 1/I_p vs 1/c^b at high concentrations. The detection limit for thiourea is 0.38 ppm (i.e., ca 17 ng/45 μl sample) for the FI system used.     

Application of convolution procedures to chronopotentiometry

Convolution procedures are used to extract the faradaic information from chronopotentiometric data, in conditions where significant distortion by double layer charging occurs. The faradaic component of the imposed current is obtained, after measurement of the double layer capacitance, by differentiation of the initial chronopotentiogram. Convolution of this current with the function (πt)^?1/2 leads to a potential-convoluted current relationship freed from the effect of double layer charging. The kinetic characterization of the system using a combined analysis of this relationship and that relating the faradaic current to the electrode potential is discussed for the various types of reaction mechanism. The efficiency of the proposed procedure is tested on the galvanostatic reduction of fluorenone in DMF.     

Catalytic Adsorptive Stripping Voltammetry at a Carbon Paste Electrode for the Determination of Amiodarone

Voltammetry using solid electrodes usually suffers from the contamination due to the deposition of the redox products of analytes on the electrode surface. The contamination has resulted in poor reproducibility and overelaborate operation procedures. The use of the chemical catalysis of oxidant on the reduction product of analyte not only can eliminate the contamination of analyte to solid electrodes but also can improve the faradaic response of analyte. This work introduced both the catalysis of oxidant K2S2O8 and the enhancement of surfactant Triton X-100 on the faraday response of amiodarone into an adsorptive stripping voltammetry at a carbon paste electrode for the determination of amiodarone. The method exhibits high sensitivity, good reproducibility and simple operation procedure. In 0.2 mol·L^-1 HOAc-NaOAc buffer （pH=5.3） containing 2.2×10^-2 mol·L^-1 K2S2O8 and 0.002% Triton X-100, the 2.5th-order derivative stripping peak current of the catalytic wave at 0.3 V （vs. Ag/AgCl） is rectilinear to amiodarone concentration in the range of 2.0×10^-10-2.3×10^-8 mol·L^-1 with a detection limit of 1.5×10^-10 mol·L^-1 after accumulation at 0 V for 30 s.     

An electrochemical immunosensor based on enzyme-encapsulated liposomes and biocatalytic metal deposition

A novel electrochemical immunosensor based on double signal amplification of enzyme-encapsulated liposomes and biocatalytic metal deposition was developed for the detection of human prostate specific antigen (PSA). Alkaline phosphatase (ALP)-encapsulated and detection antibody-functionalized liposomes were first prepared and used as the detection reagent. In the sandwich immunoassay, the model analyte PSA was first captured by anti-PSA capture antibody immobilized on the electrode and then sandwiched with the functionalized liposomes. The bound liposomes were then lysed with surfactant to release the encapsulated ALP, which served as secondary signal amplification means. ALP on the electrode surface initiated the hydrolysis of ascorbic acid 2-phosphate (AA-p) to produce ascorbic acid. The latter, in turn, reduced silver ions on the electrode surface, leading to deposition of the metal silver on the electrode surface. Linear sweep voltammetry (LSV) was chosen to detect the amount of the deposited silver. The results showed that the anodic stripping peak current was linearly dependent on the PSA concentration in the range of 0.01-100 ng mL⁻¹, and a detection limit as low as 0.007 ng mL⁻¹ can be obtained. Since the cut-off value of human PSA is 4 ng mL⁻¹, the proposed electrochemical immunosensor would be expected to gain widespread applications for the detection of PSA in clinical diagnosis.     

Use of adsorptive square-wave anodic stripping voltammetry at carbon paste electrode for the determination of amlodipine besylate in pharmaceutical preparations

The antihypertensive drug amlodipine has been characterized voltammetrically in a carbon paste electrode by means of anodic stripping voltammetry. An adsorptive stripping method in a carbon paste electrode for trace determination of amlodipine has been described. Cyclic voltammetric studies indicated the oxidation of amlodipine besylate at the electrode surface through a single two-electron irreversible step fundamentally controlled by adsorption. A study of the variation in the peak current with solution variables such as pH, ionic strength, concentration of amlodipine, possible interference, and instrumental variables, such as preconcentration time and accumulation potential, has resulted in the optimization of the oxidation signal for analytical purposes. By anodic adsorptive anodic stripping voltammetry, the calibration plot was linear in the range 9.9 × 10^?9 ? 1.4 × 10^?7 M with a detection limit of 2 × 10^?10 M in a carbon paste electrode at pH 11.0. The procedure was successfully applied to the assay of amlodipine besylate in some commercial products in the market (Amlopres®, Amlodipine, and Norvasc®). The percentage recoveries were in agreement with those obtained by the reference method.     

Interpretation of the impedance comprising negative capacitance and constant phase elements on iron electrode in weakly acidic media

The negative low-frequency capacitance that appears in interpretations of impedance of the iron electrode in weakly acidic solutions is shown to arise in the case of interaction of two consecutive nonequilibrium flows that constitute a two-stage anodic faradaic process of intermediate adsorption in the prepassivation potential range. The low-frequency capacitance is negative throughout a potential range where the logarithm of rate constant vs. potential (logk vs. E) dependence has the higher slope for the limiting stage. The low-frequency capacitance becomes positive at higher anodic potentials and for the other limiting stage.     

A Graphite‐Polyurethane Composite Electrode for the Analysis of Furosemide

A graphite‐polyurethane composite electrode has been used for the determination of furosemide, a antihypertensive drug, in pharmaceutical samples by anodic oxidation. Cyclic voltammetry and electrochemical impedance spectroscopy were used to characterize the electrooxidation process at +1.0 V vs. SCE over a wide pH range, with the result that no adsorption of analyte or products occurs, unlike at other carbon‐based electrode materials. Quantification was carried out using cyclic voltammetry, differential pulse voltammetry, and square‐wave voltammetry. Linear ranges were determined (up to 21 μmol L^?1 with cyclic voltammetry) as well as limits of detection (0.15 μmol L^?1 by differential pulse voltammetry). Four different types of commercial samples were successfully analyzed. Recovery tests were performed which agreed with those obtained by spectrophotometric evaluation. The advantages of this electrode material for repetitive analyzes, due to the fact that no electrode surface renewal is needed owing to the lack of adsorption, are highlighted.