Voltammetric Studies of 3-Nitro-tyrosine Electro-oxidation at Solid Electrodes and its Interaction with DNA

The electrochemical oxidation of 3-nitro-tyrosine (3-NO₂-Tyr) was studied in aqueous media at metallic electrodes (platinum and gold), using voltammetric techniques. The interaction between 3-NO₂-Tyr and double helix DNA (dsDNA) in a physiological medium was also investigated. Electro-oxidation of 3-NO₂-Tyr occurs in one single irreversible pH-dependent step with the transfer of one electron and one proton from the phenolic group to the formation of radicals, which preferably dimerize, fouling the electrode surfaces. The differential pulse voltammetry and gel electrophoresis results clearly demonstrated a strong interaction of 3-NO₂-Tyr with the dsDNA for the formation of a stable 3-NO₂-Tyr-dsDNA complex.     

An Electrochemical Sensor Based on Silver Nanoparticles‐Benzalkonium Chloride for the Voltammetric Determination of Antiviral Drug Tenofovir

A simple voltammetric nanosensor was described for the highly sensitive determination of antiviral drug Tenofovir. The benzalkonium chloride and silver nanoparticles were associated to build a nanosensor on glassy carbon electrode. Surface characterictics were achieved using scanning electron microscopic technique. The voltammetric measurements were performed in pH range between 1.0 and 10.0 using cyclic, adsorptive stripping differential pulse and adsorptive stripping square wave voltammetry. The linear dependence of the peak current on the square root of scan rates and the slope value (0.770) demonstrated that the oxidation of tenofovir is a mix diffusion‐adsorption controlled process in pH 5.70 acetate buffer. The linearity range was found to be 6.0×10⁻⁸–1.0×10⁻⁶ M, and nanosensor displayed an excellent detection limit of 2.39×10⁻⁹ M by square wave adsorptive stripping voltammetry. The developed nanosensor was successfully applied for the determination of Tenofovir in pharmaceutical dosage form. Moreover, the voltammetric oxidation pathway of tenofovir was also investigated at bare glassy carbon electrode comparing with some possible model compounds (Adenine and Adefovir).     

Electrochemical Oxidation at a Glassy Carbon Electrode of the Anti‐Arrhythmia Drug Disopyramide

Abstract

A voltammetric study of the oxidation of disopyramide has been carried out using a glassy carbon electrode. The electrochemical oxidation of disopyramide was investigated by cyclic, differential pulse, and square wave voltammetry. The oxidation of disopyramide is an irreversible, diffusion‐controlled process. The diffusion coefficient of disopyramide was calculated in pH 7.0 phosphate buffer to be D _disopyramide=3.8×10^?6 cm² s^?1. The oxidation of disopyramide is also pH dependent and for electrolytes with pH between 4 and 7 occurs with the transfer of one electron and one proton. In alkaline electrolytes, two consecutive charge transfer reactions are observed: both oxidation reactions involve the transfer of two electrons but only the first also involves the transfer of two protons. Two procedures for the analytical determination of disopyramide in pH 7.0 phosphate buffer were developed and compared and a detection limit LOD=1.27 µM was obtained.     

Electroactivated Disposable Pencil Graphite Electrode – New,Cost-effective,and Sensitive Electrochemical Detection of Bioflavonoid Hesperidin

In this paper, for the first time, electroactivated disposable pencil graphite electrode (ePGE) was used for the detection of bioflavonoid hesperidin with cyclic and differential pulse voltammetry. The electroactivation efficiency of the pencil graphite electrode (PGE) was examined employing electrochemical impedance spectroscopy (EIS) and scanning electrochemical microscopy (SECM) and the enhancement of electron transfer kinetics of the PGE after the electroactivation was found. Hesperidin is irreversibly oxidized on the ePGE and its oxidation was the most pronounced at pH=5.0. Two electrode processes were detected, on one hand, a mixed diffusion and adsorption control was observed for the first electrode process. On the other hand, only diffusion control was observed in the second electrode process. Linear dependence between the peak current and the hesperidin concentration was obtained in the concentration range from 5×10⁻⁷ mol dm⁻³ to 1×10⁻⁵ mol dm⁻³ and the determined lower limit of detection (LOD) was 2×10⁻⁷ mol dm⁻³. Moreover, hesperidin in pharmaceutical formulation (containing active substance, hesperidin, and excipients) was quantified using ePGE. A good correlation was obtained between experimentally obtained hesperidin concentration by voltammetric analysis and concentration determined by standard HPLC technique (R²=0.9462).     

Long-term stability of a gold electrode modified with a self-assembled monolayer of octabutylthiophthalocyaninato-cobalt(II) towards l-cysteine detection

In this paper, a gold electrode, modified with octabutylthiophthalocyaninato-cobalt(II) self-assembled monolayer (SAM), was used in the detection of l-cysteine in pH=4 buffer. The SAM showed good electrocatalytic activity and increased the electron transfer rate in such a way that mass-transport became the rate determining step of the overall oxidation reaction of l-cysteine. From these data the diffusion coefficient of l-cysteine was calculated and a value of 4.8±1.1×10⁻⁵ cm² s⁻¹ was obtained. The electrode was found to be stable for l-cysteine detection over a period of one month with a detection limit of 3.1±0.8×10⁻⁷ mol l⁻¹ if the electrode was stored in a pH=4 buffer. Despite these promising results three effects should be taken into account for potential application: first a memory effect limits the frequency of detection to one per 6 min; secondly the electron tunneling effect limits the current density for mass-transport up to 5 μA cm⁻² and finally, the electrode should be activated prior to use for analytical purposes.     

New voltammetric method useful for water insoluble or weakly soluble compounds: application to p<Emphasis Type="Italic">K</Emphasis>a determination of hydroxyl coumarin derivatives

Here, we reveal a different way of doing the voltammetric experiments that considers the electroactive species packaged in the electrodic phase instead of dissolved in solution. In this way, it is possible to obtain voltammograms of insoluble species. In this work, the method is exemplified by obtaining voltammograms for weakly soluble coumarins but it could be extrapolated to other weakly soluble compounds. We have studied a comprehensive series of 3-acetyl-hydroxycoumarins derivatives which are insoluble in aqueous medium but capable of being trapped in a three-dimensional multi-walled carbon nanotubes (MWCNT) network. Consequently, an electrodic phase composed of an MWCNT modified glassy carbon electrode (GCE) containing the coumarin derivative is prepared. The voltammetric experiment is performed with the above electrodic phase and an aqueous medium as the solution phase. All the coumarin derivatives show one anodic peak due to the oxidation of the hydroxyl group in the phenyl ring. The oxidation peaks follow a one-electron, one-proton irreversible, pH-dependent process for all monohydroxylated compounds. The Ep values are closely dependent of the substituent effect being the 7,8-cum derivative more easily oxidized due to both the electron donor effect of neighboring hydroxyls groups and hydrogen bonding interaction between them. On the other hand, the hydroxyl of the 7-cum derivative is the most difficult to oxidize due to the electron-attracting effect of the lactone carbonyl group at position 2 and acetyl carbonyl at position 3 which is conjugated with OH at 7 positions. From the breaks in the graphs Ep versus pH, we estimate the voltammetric pKa values for all the studied coumarin derivatives.     

Adsorptive Stripping Voltammetric Determination of Trace Level Ricin in Castor Seeds Using a Boron‐doped Diamond Electrode

Ricin, (Ricinus communis agglutinin, RCA) is one of the most poisonous of naturally occurring substances and has great potential for bioterrorism because no antidote exists. Fast detection at low concentrations is a challenge, and vital to the development of proper countermeasures. In this study, a square wave adsorptive stripping voltammetric (SWAdSV) method for determining RCA using a cathodically polarized boron‐doped diamond (BDD) electrode is presented. An irreversible electrochemical RCA oxidation peak was identified on the BDD electrode by different voltammetric techniques using both direct and adsorptive stripping modes. An adsorption‐controlled (slope log Ip vs log v of 0.80) pH‐dependent process was observed. For values of 1.0≤pH≤9.0, the numbers of protons and electrons associated with the oxidation reaction were estimated (ca. 1.0) by differential pulse voltammetry. The RCA oxidation step may correspond to the oxidation of tryptophan amino acid residues, and occurs in a complex mechanism. The excellent analytical performance of the cathodically polarized BDD electrode in combination with the stripping mode ramp was verified with RCA by using a short deposition time in an open circuit potential (120 s). Under optimized analysis conditions, a linear response in the range of (3.3–94.0)×10⁻⁹ mol L⁻¹ (r²=0.9944) and a limit of detection of 6.2×10⁻¹⁰ mol L⁻¹ were estimated. This LOD is lower than several methods found in the literature. For example, it is 168 times lower than that obtained by using square wave voltammetric with a glassy carbon electrode. Moreover, an even lower LOD might be achieved by using the SWAdSV method with a higher pre‐concentration time. In addition, trace levels of RCA were successfully determined in different castor seed cultivars with an overall average recovery from 99.2±1.6 % for the three different RCA‐A concentration levels. The high accuracy of the analytical data highlights the use of the proposed method for determining RCA in other samples.     

Electropolymerization rates of polythiophene/polypyrrole composite polymer with some dopant ions

Pyrrole, thiophene, and a mixture of the two monomers were electrochemically polymerized to investigate polymerization rates and the morphology change of the polymer matrix, and to improve the aging and cyclic voltammetric behaviors of the polymers. Thiophene was polymerized on a smooth surface of Pt electrode by two steps. The first step was controlled by electron transfer at the electrical double layer and the other by diffusion of the monomer reacting on the immobilized layer consisting of the precoated thiophene polymer. The electropolymerization rate of the second step was 1.85 × 10⁻⁴ cm³ mol⁻¹ s⁻¹, which is faster by 8.63 × 10² times than the first step. Some supporting electrolytes such as KPF₆, LiClO₄, TBAP, and TBABF₄ were employed in the polymerization reaction to see the effects of dopant anions on the polymerization rate, and KPF₆ was the fastest one at 2.41 × 10⁻⁶ cm s⁻¹. However, owing to its sensitivity to oxygen, LiClO₄ was used for the polymerization that is fairly stable in air and the same rate as KPF₆. For the competitive polymerization reaction of the two monomers the rate of thiophene was found to be about 11 times slower than that of thiophene alone. When the starting concentration of the thiophene monomer was higher than pyrrole by five times, its portion in the composite polymer was found to be only 8–10%. However, this level gave desirable results in terms of redox properties and aging. The resistance against aging was explained by the morphology change, which came from great shrinking of its porosity. © 1997 John Wiley & Sons, Inc.     

Electroanalytical Characteristics of Amisulpride and Voltammetric Determination of the Drug in Pharmaceuticals and Biological Media

The electrochemical oxidation of antipsychotic drug amisulpride (AMS) has been studied in pH range 1.8–11.0 at a stationary glassy carbon electrode by cyclic, differential pulse and square‐wave voltammetry. Two oxidation processes were produced in different supporting electrolyte media. Both of the oxidation processes were irreversible and exhibited diffusion controlled. For analytical purposes, very resolved voltammetric peaks were obtained using differential pulse and square‐wave modes. The linear response was obtained in the range of 4×10^?6 to 6×10^?4 M for the first and second oxidation steps in Britton‐Robinson buffer at pH 7.0 and pH 3.0 (20% methanol v/v), respectively, using both techniques. These methods were used for the determination of AMS in tablets. The first oxidation process was chosen as indicative of the analysis of AMS in biological media. The methods were successfully applied to spiked human serum, urine and simulated gastric fluid samples.     

Linkage between Fluorescence and Electrochemical Properties of Imidazolium Compounds in Acetonitrile Solution

The fluorescence properties of some imidazolium derivatives are relevant in photosensing and therefore, the structural analysis of them is a key point for its rational design, which would be useful to prepare new systems with novel applications. Herein we report a multidisciplinary study of the fluorescence and voltammetric properties of three imidazolium compounds {1,3-bis[(R,R)-1′-chloro-1′-phenylpropan-2′-yl]-imidazolium chloride ( 1 ), 1,3-bis[(Z)-1′-phenylprop-1′-en-2′-yl]imidazolium chloride ( 2 ) 1,3-bis[(R)-1′-chlorobutan-2′-yl]-imidazolium chloride ( 3 )}. Electronic structure calculations and Bader analyses were used to correlate both fluorescence and the capability of the molecules to be reduced through a heterogeneous electron transfer process. Both properties are strongly dependent on the proton in position two of the imidazolium ring, where the electron transfer as well as the excitation of the electrons are carried out. The reactivity in this position is controlled by the N-substituents on the imidazolium ring and is due to single contacts H⋅⋅⋅Cl⁻, tricentric contacts Cl⋅⋅⋅Cl⁻⋅⋅⋅Cl, π-electronic delocalization and π-stacking interactions.     

Electrooxidation of the antiviral drug valacyclovir and its square-wave and differential pulse voltammetric determination in pharmaceuticals and human biological fluids

The electrochemical properties of valacyclovir, an antiviral drug, were investigated in pH range 1.8-12.0 by cyclic, differential pulse and square-wave voltammetry. The drug was irreversibly oxidized at a glassy carbon electrode in one or two oxidation steps, which are pH-dependent. For analytical purposes, a very resolved diffusion controlled voltammetric peak was obtained in Britton-Robinson buffer at pH 10.0 using differential pulse and square-wave modes. Limits of detection were 1.04 × 10⁻⁷ and 4.60 × 10⁻⁸ M for differential pulse and square-wave voltammetry, respectively. The applicability to direct assays of tablets, spiked human serum and simulated gastric fluid, was described.     

Electrochemical Redox Behavior of Omeprazole Using a Glassy Carbon Electrode

The electrochemical redox behavior of omeprazole (OMZ), a gastric acid pump inhibitor, was investigated at a glassy carbon electrode using cyclic, differential pulse and square‐wave voltammetry over a wide pH range. The pH‐dependent oxidation occurs in two irreversible consecutive charge transfer reactions. Adsorption of the nonelectroactive product was also observed. The first oxidation involves removal of one electron, followed by deprotonation and leads to the formation of a hydroxylated species. The second oxidation process is related to the hydroxyl and amino groups in the benzimidazole moiety. The reduction is irreversible, also pH‐dependent, and occurs in a single step at the sulfoxide group in a diffusion‐controlled mechanism. The diffusion coefficient of omeprazole was calculated to be D_OMZ=2.31×10^?6 cm² s^?1.     

Voltammetric Determination of Marbofloxacin at Carbon Paste Sensor Integrated with Copper Oxide Nanoparticles

The present work introduced copper oxide nanoparticles as an efficient electrode modifier for sensitive adsorptive differential pulse voltammetric assaying of marbofloxacin (MRB) in pharmaceutical formulations and surface water samples. In the presence of sodium dodecyl sulphate (SDS) at pH 4.0, the marbofloxacin molecule was irreversibly oxidized at the electrode surface showing an anodic oxidation peak at 0.954 V. The electrode reaction mechanism was assumed as adsorption-reaction controlled accompanied by the transferring of two electrons and proton exchange in agreement with the molecular orbital calculations performed on MRB molecule suggesting the oxidation of the amino group in the piperazinyl ring. At the optimized measuring conditions, the recorded peak heights were linearly correlated with the MRB concentration within the range from 6.67 to 360 ng mL⁻¹, and the estimated LOD value was 2.2 ng mL⁻¹. The integrated sensor showed a prolonged operational lifetime with good reproducibility of measurements. Based on the selectivity and sensitivity of the proposed method, MRB was successfully assayed in pharmaceutical formulations and surface water samples with mean average recoveries agreeable with the official method.     

Electrochemical Oxidation of Metolazone at a Glassy Carbon Electrode

Metolazone is a diuretic agent used in patients with edematous states and/or hypertension. The electrochemical behavior of metolazone on a glassy carbon electrode was investigated using cyclic, differential pulse, and square‐wave voltammetry at different pHs. The pH dependent oxidation of metolazone occurs in two consecutive steps in a diffusion‐controlled mechanism and involves the formation of a main oxidation product. The first oxidation process is reversible, and involves two electrons and two protons corresponding to the oxidation of nitrogen in the sulfonamide moiety. The second oxidation process is irreversible, also occurs in the sulfonamide moiety, involves a one electron‐transfer, and is followed by deprotonation to produce a cation radical, which reacts with water and yields a hydroxylated product. The diffusion coefficient of metolazone was calculated to be 3.43×10^?6 cm² s^?1 in pH 7.0 0.1 M phosphate buffer.     

The reduction of carbonyl compounds at carbon electrodes in acidic water/methanol mixtures

The voltammetry of benzaldehyde in acidic methanol/water mixtures is shown to depend strongly on the cathode material. At pH 1, benzaldehyde always reduces in two le⁻ steps and the first step is always reversible. On the other hand, the potential for the second reduction step varies strongly with cathode material; at vitreous carbon, the second step occurs at much more negative potential than at lead or mercury, giving much better resolution of the two reduction waves. In citrate buffer, pH 4, the first reduction step is shifted negative; as a result, at lead a single 2e⁻ wave is seen but at vitreous carbon, two 1e⁻ steps are still observed. These changes in voltammetry with cathode material are shown to be general for both aldehydes and ketones.     

Electrode/Electrolyte Synergy for Concerted Promotion of Electron and Proton Transfers toward Efficient Neutral Water Oxidation

Neutral water oxidation is a crucial half-reaction for various electrochemical applications requiring pH-benign conditions. However, its sluggish kinetics with limited proton and electron transfer rates greatly impacts the overall energy efficiency. In this work, we created an electrode/electrolyte synergy strategy for simultaneously enhancing the proton and electron transfers at the interface toward highly efficient neutral water oxidation. The charge transfer was accelerated between the iridium oxide and in situ formed nickel oxyhydroxide on the electrode end. The proton transfer was expedited by the compact borate environment that originated from hierarchical fluoride/borate anions on the electrolyte end. These concerted promotions facilitated the proton-coupled electron transfer (PCET) events. Due to the electrode/electrolyte synergy, Ir−O and Ir−OO⁻ intermediates could be directly detected by in situ Raman spectroscopy, and the rate-limiting step of Ir−O oxidation was determined. This synergy strategy can extend the scope of optimizing electrocatalytic activities toward more electrode/electrolyte combinations.     

Voltammetry of a Novel Antimycobacterial Agent 1‐Hydroxy‐N‐(4‐nitrophenyl)naphthalene‐2‐carboxamide in a Single Drop of a Solution

The aim of this study is the development of a miniaturized voltammetric method for the determination of an antimycobacterial agent 1‐hydroxy‐N‐(4‐nitrophenyl)naphthalene‐2‐carboxamide (HNN) in a single drop (20 μL) of a solution by cathodic and anodic voltammetry at a glassy carbon electrode. Cyclic voltammetry was used to investigate its redox properties followed by the optimization of differential pulse voltammetric determination in a regular 10 mL volume. The optimal medium for the analytical application of both cathodic and anodic voltammetry was found to be Britton‐Robinson buffer pH 7.0 and dimethyl sulfoxide (9 : 1, v/v). HNN gave one cathodic peak at around −0.6 V and one anodic peak at around +0.2 V vs. Ag|AgCl (3 mol L⁻¹ KCl) reference electrode. Determination of HNN in a 10 mL volume gave the limit of quantification around 10 nmol L⁻¹ by both adsorptive stripping anodic and cathodic voltammetry. Afterwards, miniaturized voltammetric methods in a single drop of solution (20 μL) were investigated. This approach requested some modifications of the cell design and voltammetric procedures. A novel method of removing dissolved oxygen in a single drop had to be developed and tested. Developed miniaturized voltammetric methods gave parameters comparable to the determination of HNN in 10 mL. The applicability of the miniaturized method was verified by the determination of HNN in a drop of a bacterial growth medium.     

Voltammetric Characterisation of Anticancer Drug Irinotecan

Electrochemical reduction of irinotecan was investigated on a static mercury drop electrode using square‐wave voltammetry. The mechanism of irinotecan electroreduction is a complex, pH‐dependent, quasireversible process and includes the transfer of two electrons and two protons. In acidic medium, the first electron transfer reaction is followed by the chemical reaction, and the product of this chemical reaction undergoes further electrochemical reduction at more negative potentials. Both irinotecan and the product of its reduction adsorb on the mercury electrode surface. Based on the adsorptive character of irinotecan, a new adsorptive stripping square‐wave voltammetric method for its electroanalytical determination has been proposed. The voltammetric response could be used to determine irinotecan in the concentration range from 1×10⁻⁷ mol/L to 1.5×10⁻⁶ mol/L and from 5×10⁻⁹ mol/L to 1.2×10⁻⁷ mol/L, if the accumulation time is 20 s and 300 s, respectively. The calculated limit of detection for irinotecan was found to be 8.7×10⁻⁹ mol/L (if t_acc=300 s).     

Electrochemical Behaviour of Benzofuran Derivatives of Pharmaceutical Interest at Solid Electrodes

Abstract

The electrooxidation of four structually related drugs (amiodarone and benziodarone and their iodinated derivatives), has been studied, using cyclic voltammetry and controlled potential coulometry at carbon paste and platinum electrodes in hydro-organic media. The oxidative mechanisms have been suggested on the basis of a comparative study and by analyzing the i_p, E_p/ pH plots, the number of electrons evolved and the cyclic voltammetric behaviours. The influence of carbon-iodine bonds on the redox pattern of the molecules has been analyzed and a comparison between the oxidation pattern of the phenolic molecules and the corresponding diethylaminoethoxy derivatives has been realized. Quantitative measurements have been obtained at the carbon paste electrode, within the range of concentrations 5. × 10^?6 M - 5 × 10⁵ M. The analytical usefulness in determination of these compounds has been demonstrated.