Antileishmanial Drug Miltefosine‐dsDNA Interaction in situ Evaluation with a DNA‐Electrochemical Biosensor

Leishmaniasis is one of the most important parasitic neglected disease. The electrochemical evaluation of the antileishmanial drug miltefosine‐dsDNA interaction was investigated in incubated solutions and using dsDNA‐electrochemical biosensors, following the changes in the oxidation peaks of guanosine and adenosine residues, and the occurrence of the free guanine residues, electrochemical signal. The electrochemical behaviour of miltefosine was also investigated, at a glassy carbon electrode, using cyclic, differential pulse and square wave voltammetry and no electrochemical redox processes were observed. The interaction mechanism of miltefosine‐dsDNA occurs in two ways: independent of the dsDNA sequence, and leading to the condensation/aggregation of DNA strands, producing a rigid miltefosine‐dsDNA complex structure, and a preferential interaction between the guanine hydrogen atoms in the C−G base pair and miltefosine, causing the release of guanine residues detected on the electrode surface. Miltefosine did not induce oxidative damage to DNA in the experimental conditions used.     

Determination of Electrochemical Interaction between 2‐(1H‐benzimidazol‐2‐yl) Phenol and DNA Sequences

A benzimidazole derivate, 2‐(1H‐benzimidazol‐2‐yl) phenol (2‐Bip) and its interaction mechanism with sequence specific DNA was examined with Differential Pulse Voltammetry (DPV). We, for the first time, investigated the effect of 2‐Bip on sequence specific DNA with electrochemical methods by evaluating both guanine and 2‐Bip oxidation signal changes. In the study, probe sequences were immobilized to the surface of the electrodes and then hybridization was achieved by sending the complementary target onto the probe modified electrodes. Following the hybridization, 2‐Bip solution was interacted with probe and hybrid sequences to see the effect of 2‐Bip on different DNA sequences. The binding constant (K), toxicity (S%) and thermodynamic parameters, i. e., Gibbs free energy (ΔG°) of 2‐Bip‐DNA complexes were evaluated. K was calculated as 5×10⁵ and the change in the ΔG° was found as ?32.50 kJ mol^?1, which are consistent well with the literature. Furthermore, S% showed that 2‐Bip is moderately toxic to single stranded DNA (ssDNA) and toxic to double stranded DNA (dsDNA). From our experimental data, we made four conclusions (i) 2‐Bip affects both ssDNA and dsDNA, (ii) 2‐Bip interaction mode with DNA could be non‐covalent interactions, (iii) 2‐Bip could be used as new DNA hybridization indicator due to its distinct effects on ssDNA and dsDNA, (iv) 2‐Bip could be used as a drug molecule for its DNA effect.     

In situ electrochemical evaluation of anticancer drug temozolomide and its metabolites–DNA interaction

Temozolomide (TMZ) is an antineoplastic alkylating agent with activity against serious and aggressive types of brain tumours. It has been postulated that TMZ exerts its antitumor activity via its spontaneous degradation at physiological pH. The in vitro evaluation of the interaction of TMZ and its final metabolites, 5-aminoimidazole-4-carboxamide (AIC) and methyldiazonium ion, with double-stranded DNA (dsDNA) was studied using differential pulse voltammetry at a glassy carbon electrode. The DNA damage was electrochemically detected following the changes in the oxidation peaks of guanosine and adenosine residues. The results obtained revealed the decrease of the dsDNA oxidation peaks with incubation time, showing that TMZ and AIC/methyldiazonium ion interact with dsDNA causing its condensation. Furthermore, the experiments of the in situ TMZ and AIC/methyldiazonium ion–dsDNA interaction using the multilayer dsDNA-electrochemical biosensor confirmed the condensation of dsDNA caused by these species and showed evidence for a specific interaction between the guanosine residues and TMZ metabolites, since free guanine oxidation peak was detected. The oxidative damage caused to DNA bases by TMZ metabolites was also detected electrochemically by monitoring the appearance of the 8-oxoguanine/2,8-dyhydroxyadenine oxidation peaks. Nondenaturing agarose gel electrophoresis of AIC/methyldiazonium ion–dsDNA samples confirmed the occurrence of dsDNA condensation and oxidative damage observed in the electrochemical results. The importance of the dsDNA-electrochemical biosensor in the in situ evaluation of TMZ–dsDNA interactions is clearly demonstrated.     

In situ evaluation of chromium–DNA damage using a DNA-electrochemical biosensor

The in situ evaluation of the direct interaction of chromium species with double-stranded DNA (dsDNA) was studied using differential pulse voltammetry at a glassy carbon electrode. The DNA damage was electrochemically detected following the changes in the oxidation peaks of guanosine and adenosine bases. The results obtained revealed the interaction with dsDNA of the Cr(IV) and Cr(V) reactive intermediates of Cr(III) oxidation by O₂ dissolved in the solution bound to dsDNA. This interaction leads to different modifications and causes oxidative damage in the B-DNA structure. Using polyhomonucleotides of guanine and adenine, it was shown that the interaction between reactive intermediates Cr(IV) and Cr(V)–DNA causes oxidative damage and preferentially takes place at guanine-rich segments, leading to the formation of 8-oxoguanine, the oxidation product of guanine residues and a biomarker of DNA oxidative damage. The interaction of Cr(VI) with dsDNA causes breaking of hydrogen bonds, conformational changes, and unfolding of the double helix, which enables easier access of other oxidative agents to interact with DNA, and the occurrence of oxidative damage to DNA.     

Sensitive Nucleic Acid Detection at NH2‐MWCNTs Modified Glassy Carbon Electrode and its Application for Monitoring of Gemcitabine‐DNA Interaction

An electrochemical dsDNA nanobiosensor was fabricated using amino‐functionalized multi walled carbon nanotubes modified glassy carbon electrode (NH₂fMWCNTs/GCE) for the sensitive detection of DNA bases and electrochemical monitoring of drug‐DNA interaction. The influence of functional groups on MWCNT was studied by MWCNT functionalized with NH₂ (NH₂fMWCNTs) and COOH (COOHfMWCNT) groups based on the signal of DNA bases. The modified electrodes were characterized by scanning electron microscopy. One layer of calf thymus double stranded deoxyribonucleic acid (ct‐dsDNA) was immobilized onto the NH₂fMWCNTs/GCE (dsDNA/NH₂fMWCNTs/GCE). The dsDNA/NH₂fMWCNTs/GCE were used to investigate the interaction between the dsDNA and the anticancer drug gemcitabine by differential pulse voltammetry in acetate buffer of pH 4.70. For the confirmation of interaction, the lowering in intensity of the current signals of guanine and adenine was considered as an indicator. Electrochemical impedance spectroscopy studies were performed for the comparison of the modified surfaces. In order to define and visualize the interaction mechanism between gemcitabine and dsDNA/NH₂fMWCNTs/GCE at the molecular level, in silico methods including docking and molecular dynamics simulations were employed.     

Determination of DNA Hypermethylation Using Anti‐cancer Drug‐Temozolomide

An electrochemical drug‐DNA biosensor was developed for the detection of interaction between the anti‐cancer drug, Temozolomide (TMZ), and DNA sequences by using Differential Pulse Voltammetry at the graphite electrode surfaces. TMZ is a pro‐drug and an alkylating agent that crosses the blood‐brain barrier, so it is mainly used for brain cancers treatment. In this study, we aim to develop a‐proof‐of‐concept study to investigate the effect of TMZ on formerly methylated DNA sequences since TMZ shows its anti‐cancer activity by methylating the DNA. Interaction between TMZ and DNA causes localized distortion of DNA away from an idealized B‐form, resulting in a wider major groove and greater steric accessibility of functional groups in the base of the groove. According to the results, TMZ behaves as a ‘hybridization indicator’ because of its different electrochemical behavior to different strands of DNA. After interaction with TMZ, hybrid (double stranded DNA‐dsDNA) signals decreased dramatically whereas probe (single stranded DNA‐ssDNA) and control signals remain almost unchanged. The signal differences enabled us to distinguish ssDNA and dsDNA without using a label or tag. It is the first study to demonstrate the interaction between the TMZ and dsDNA created from probe and target. We use specific oligonucleotides sequences instead of using long dsDNA sequences.     

Electrochemical Characteristics of a Novel Pyridinium Salt as a Candidate Drug Molecule and Its Interaction with DNA

In this article, for the first time, the electrochemical properties of a novel pyridine derivative, 4‐(2‐(2‐hydroxybenzylidene) hydrazinyl)‐1‐(3‐phenylpropyl) pyridinium bromide (abbreviated as 4‐Pyri), and its interaction with double stranded DNA (dsDNA) was investigated. The interaction between candidate drug molecule (4‐Pyri) and dsDNA was analyzed by examining 4‐Pyri (+0.6 V and +0.8 V) and guanine (+1.0 V) oxidation signal changes with Differential Pulse Voltammetry (DPV) and Cyclic Voltammetry (CV). Electrochemical Impedance Spectroscopy (EIS) was used to show the resistance changes before and after the interaction between 4‐Pyri and dsDNA. We showed that after the interaction with 4‐Pyri, the oxidation currents of guanine decreased dramatically, whereas the intrinsic oxidation currents of 4‐Pyri dramatically increased. 4‐Pyri oxidation current differences before and after the interaction with dsDNA enabled us to determine such interaction separately from guanine oxidation signals. In addition, resistance differences were observed at before and after the interaction with each other that confirmed the possible interaction. In addition, toxicity effect (S%) value, which is an important parameter for electrochemical studies indicated 4‐Pyri's toxicity to dsDNA. Our results demonstrated that 4‐Pyri interacts with dsDNA, and could be used as a potential candidate drug molecule due to its remarkable impact on dsDNA.     

Chitosan/Ionic Liquid Composite Electrode for Electrochemical Monitoring of the Surface‐Confined Interaction Between Mitomycin C and DNA

In the present study a chitosan/ionic liquid modified pencil graphite electrode (CHIT‐IL‐PGEs) was developed for the first time for enhanced electrochemical monitoring of nucleic acid, and the interaction of the anticancer drug Mitomycin C (MC) and calf thymus double stranded DNA (dsDNA) by measuring the oxidation signals of MC and guanine in the same voltammetric scale. Differential pulse voltammetry, cyclic voltammetry and electrochemical impedance spectroscopy techniques were used to evaluate the performance of the CHIT‐IL based biosensor on electrochemical monitoring of DNA, and drug‐DNA interaction. The experimental parameters, IL, dsDNA and MC concentration and the interaction time were then optimized.     

Electrochemical Biosensor for the Detection of Interaction Between Arsenic Trioxide and DNA Based on Guanine Signal

The interaction of arsenic trioxide (As₂O₃) with calf thymus double‐stranded DNA (dsDNA), calf thymus single‐stranded DNA (ssDNA) and also 17‐mer short oligonucleotide (Probe A) was studied electrochemically by using differential pulse voltammetry (DPV) with carbon paste electrode (CPE) at the surface and also in solution. Potentiometric stripping analysis (PSA) was employed to monitor the interaction of As₂O₃ with dsDNA in solution phase by using a renewable pencil graphite electrode (PGE). The changes in the experimental parameters such as the concentration of As₂O₃, and the accumulation time of As₂O₃ were studied by using DPV; in addition, the reproducibility data for the interaction between DNA and As₂O₃ was determined by using both electrochemical techniques. After the interaction of As₂O₃ with dsDNA, the DPV signal of guanine was found to be decreasing when the accumulation time and the concentration of As₂O₃ were increased. Similar DPV results were also found with ssDNA and oligonucleotide. PSA results observed at a low DNA concentration such as 1 ppm and a different working electrode such as PGE showed that there could be damage to guanine bases. The partition coefficients of As₂O₃ after interaction with dsDNA and ssDNA in solution by using CPE were calculated. Similarly, the partition coefficients (PC) of As₂O₃ after interaction with dsDNA in solution was also calculated by PSA at PGE. The features of this proposed method for the detection of DNA damage by As₂O₃ are discussed and compared with those methods previously reported for the other type of DNA targeted agents in the literature.     

An evaluation of the CYP2D6 and CYP3A4 inhibition potential of metoprolol metabolites and their contribution to drug–drug and drug–herb interaction by LC‐ESI/MS/MS

The aim of the present study was to evaluate the contribution of metabolites to drug–drug interaction and drug–herb interaction using the inhibition of CYP2D6 and CYP3A4 by metoprolol (MET) and its metabolites. The peak concentrations of unbound plasma concentration of MET, α‐hydroxy metoprolol (HM), O‐desmethyl metoprolol (ODM) and N‐desisopropyl metoprolol (DIM) were 90.37 ± 2.69, 33.32 ± 1.92, 16.93 ± 1.70 and 7.96 ± 0.94 ng/mL, respectively. The metabolites identified, HM and ODM, had a ratio of metabolic area under the concentration–time curve (AUC) to parent AUC of ≥0.25 when either total or unbound concentration of metabolite was considered. In vitro CYP2D6 and CYP3A4 inhibition by MET, HM and ODM study revealed that MET, HM and ODM were not inhibitors of CYP3A4‐catalyzed midazolam metabolism and CYP2D6‐catalyzed dextromethorphan metabolism. However, DIM only met the criteria of >10% of the total drug related material and <25% of the parent using unbound concentrations. If CYP inhibition testing is solely based on metabolite exposure, DIM metabolite would probably not be considered. However, the present study has demonstrated that DIM contributes significantly to in vitro drug–drug interaction. Copyright © 2016 John Wiley & Sons, Ltd.     

Electrochemical Nucleic Acid Biosensors for the Detection of Interaction Between Peroxynitrite and DNA

We studied the reactivity of peroxynitrite and different nucleic acid molecules using DNA electrochemical biosensors. SIN‐1 (3‐morpholinosydnonimine) has been used for the simultaneous generation of NO?and superoxide, i.e., as a peroxynitrite (ONOO^?) donor. Double strand DNA (dsDNA), single strand DNA (ssDNA) and 15 guanine bases oligonucleotide (Oligo(dG)₁₅) were immobilized on a carbon paste electrode to generate the biosensor and DPV was selected as the electroanalytical technique. Results showed that electrochemical biosensors were very sensitive for detecting interaction between ONOO^? and DNA. A down/up effect was observed, i.e., at low ONOO^? concentrations the guanine oxidation signal decreased while at high ONOO^? concentrations the guanine oxidation current increased. Oligo(dG)₁₅ exhibited greater interaction at low ONOO^? concentrations than the other DNA molecules. The reactivity between ONOO^? and DNA was also evaluated in solution phase, showing the same down/up effect. Finally, the capacity of DNA to hybridize was prevented after interaction with ONOO^?.     

In situ evaluation of heavy metal-DNA interactions using an electrochemical DNA biosensor

Heavy metal ions, lead, cadmium and nickel, are well known carcinogens with natural different origins and their direct mode of action is still not fully understood. A dsDNA-electrochemical biosensor, employing differential pulse voltammetry, was used for the in situ evaluation of Pb2+, Cd2+ and Ni2+ interaction with dsDNA. The results confirm that Pb2+, Cd2+ and Ni2+ bind to dsDNA, and that this interaction leads to different modifications in the dsDNA structure. These modifications were electrochemically recognized as changes in the oxidation peaks of guanosine and adenosine bases. Using homopolynucleotides of guanine and adenine it has been proved that the interaction between Pb2+ and DNA causes oxidative damage and preferentially takes place at adenine-containing segments, with the formation of 2,8-dihydroxyadenine, the oxidation product of adenine residues and a biomarker of DNA oxidative damage. The Pb2+ bound to dsDNA can still undergo oxidation. The interaction of Cd2+ and Ni2+ causes conformational changes, destabilizing the double helix, which can enable the action of other oxidative agents on DNA.     

BisPNA‐assisted Detection of Double‐stranded DNA via Electrochemical Impedance Spectroscopy

A highly effective strategy for quantification of plasmid which was a special dsDNA based on bisPNA by electrochemical impedance spectroscopy was presented in this work. Firstly, through Au?S bond, thiol‐terminated bisPNA probes were immobilized onto the gold electrode surface. Then bisPNA probes directly hybridized with target plasmid DNA pBR322 based on the PNA.DNA‐PNA invasion triplex without denaturation. In the presence of redox electroactive ions [Fe(CN)₆]^3?/4? as hybridization indicator, the charge transfer resistance (R_ct) was produced, and R_ct was measured via electrochemical impedance spectroscopy. Under optimal conditions, this strategy showed a good linear relationship between the ΔR_ct which was the difference of R_ct obtained before and after bisPNA hybridized with plasmid pBR322, and logarithm of the concentration of plasmid pBR322 within the range from 1 nM to 100 nM (R²=0.993), with a limit of detection (LOD) of 0.1 nM. Furthermore, this bisPNA‐assisted biosensor showed good stability and satisfactory analytical reliability. In addition, this novel bisPNA‐assisted biosensor also exhibited excellent analytical results in human serum.     

Electrochemical DNA biosensor for polycyclic aromatic hydrocarbon detection

Four DNA electrochemical biosensors using four types of DNA (calf thymus ssDNA, calf thymus dsDNA, salmon testis ssDNA and salmon testis dsDNA) were constructed using graphite screen printed electrodes. These biosensors were exploited as analytical tool to detect polycyclic aromatic hydrocarbons-DNA interactions using benzo(a)anthracene and phenantrene as model analytes, the guanine oxidation peak variation being the signal revealing the interaction between PAHs and immobilized DNA. The salmon testis ssDNA biosensor resulted as the most promising device and was further evaluated for benzo(a)anthracene, fluorene, indeno(1,2,3-cd)pyrene, anthracene, and phenanthrene in 5–40 ng mL^?1 solutions, and for benzo(a)pyrene (5–50 ng mL^?1). A concentration dependent variation of the DNA guanine oxidation peak was observed for all compounds. The effect of benzo(a)pyrene ultraviolet (UV) activation on the benzo(a)pyrene (BaP)-DNA interaction was evaluated at concentration levels of 20 and 50 ng mL^?1, and a 3.5- and 2.7-fold increases of the guanine oxidation peak was measured respectively. The salmon testis ssDNA biosensor was examined with PAHs contaminated samples of Mytilus galloprovincialis. Upon UV irradiation of three sample extracts exceeding the BaP maximum level, a positive variation of the DNA guanine oxidation was obtained. An average 2.4-fold increase of the guanine oxidation peak was detected demonstrating that the sensor can be used to detect toxic degradation products of PAHs.     

New Electroactive Hybridization Indicators 2‐Phthalimido‐N‐Substitutedphenylethanesulfonamide Derivatives for Biosensor Applications: Ring Substituent Effect on Interaction between Compound and DNA

In this work, an electrochemical DNA‐based sensor was developed for the detection of the interaction between the anticonvulsant compounds 2‐phthalimido‐N‐substituted phenylethanesulfonamides (PMPES‐derivatives) and 24‐mer short DNA sequences by using differential pulse voltammetry (DPV) based on both compound and guanine oxidation signals at the renewable carbon graphite electrode (CGE) surface. The influence of compounds on DNA showed differences depending on the nature and position of the substituent on the N‐phenyl ring. Compounds bearing 3‐methoxy, 4‐chloro and 2,6‐dimethyl substituents bind to single stranded probe DNA more strongly than the other derivatives of PMPES. Thus, these compounds were evaluated for use as an electrochemical hybridization label (indicator).     

Voltammetric DNA Biosensor Based on a Microcrystalline Natural Graphite–Polystyrene Composite Transducer

New voltammetric DNA biosensor based on a microcrystalline natural graphite–polystyrene composite film in the role of a transducer was used for the investigation of the interaction between model carcinogenic substance (2-aminofluorene; one of the most extensively studied examples of the aromatic amine class of carcinogens) and calf thymus double-stranded DNA (dsDNA). The layer of dsDNA immobilized at the electrode surface was utilized as a biocomponent responsive interface. The biosensor was characterized regarding the detection of DNA damage (induced by direct interaction with 2-aminofluorene) using square wave voltammetric responses of the guanine and adenine moieties and cyclic voltammetric responses of the anionic redox indicator [Fe(CN)₆]^4–/3– present in the solution.     

Development and validation of a reversed‐phase HPLC method for CYP1A2 phenotyping by use of a caffeine metabolite ratio in saliva

CYP1A2 is important for metabolizing various clinically used drugs. Phenotyping of CYP1A2 may prove helpful for drug individualization therapy. Several HPLC methods have been developed for quantification of caffeine metabolites in plasma and urine. Aim of the present study was to develop a valid and simple HPLC method for evaluating CYP1A2 activity during exposure in xenobiotics by the use of human saliva. Caffeine and paraxanthine were isolated from saliva by liquid‐liquid extraction (chlorophorm/isopropanol 85/15v/v). Extracts were analyzed by reversed‐phase HPLC on a C₁₈ column with mobile phase 0.1% acetic acid/methanol/acetonitrile (80/20/2 v/v) and detected at 273nm. Caffeine and paraxanthine elution times were <13min with no interferences from impurities or caffeine metabolites. Detector response was linear (0.10–8.00µg/ml, R²>0.99), recovery was >93% and bias <4.47%. Intra‐ and inter‐day precision was <5.14% (n=6). The limit of quantitation was 0.10µg/ml and the limit of detection was 0.018±0.002µg/mL for paraxanthine and 0.032±0.002µg/ml for caffeine. Paraxanthine/caffeine ratio of 34 healthy volunteers was significantly higher in smokers (p<0.001). Saliva paraxanthine/caffeine ratios and urine metabolite ratios were highly correlated (r=0.85, p<0.001). The method can be used for the monitoring of CYP1A2 activity in clinical practice and in studies relevant to exposure to environmental and pharmacological xenobiotics. Copyright © 2015 John Wiley & Sons, Ltd.     

Electrochemical Study on DNA Damage Based on the Direct Oxidation of 8‐Hydroxydeoxyguanosine at an Electrochemically Modified Glassy Carbon Electrode

The study of DNA damage induced by Fenton reaction (Fe²⁺/H₂O₂) in vitro was performed based on the direct electrochemical oxidation of 8‐hydroxydeoxyguanosine (8‐OH‐dG), the biomarker of DNA oxidative damage, at an electrochemically modified glassy carbon electrode (GCE). The effects of antioxidants, such as ascorbic acid, and hydroxyl‐radical scavenger (mannitol) on the DNA damage were also investigated. 8‐OH‐dG, the oxidation product of guanine residues in DNA, has shown significantly oxidative peak on the electrochemically modified GCE. The oxidative peak current of 8‐OH‐dG was linear with the damaged DNA concentration in the range of 10–200 mg/L. The experimental results demonstrate that ascorbic acid has ambivalent effect on DNA oxidative stress. It can promote DNA oxidative damage when ascorbic acid concentration is below 1.5 mM and protect DNA from damage in the range of 1.5–2.5 mM. As a hydroxyl‐radical scavenger, mannitol inhibits significantly DNA oxidative damage. The influence of Fe²⁺, as reactant, and EDTA as iron chelator in the system were also studied. The proposed electrochemical method can be used for the estimation of DNA oxidative damage from new point of view.     

Real time monitoring of drug metabolic enzyme response inside human hepatoma GS‐3A4‐HepG2 cells by means of electrochemical impedance measurement

Cytochrome P‐450s (CYPs) are important biopolymers for the maintenance of cellular function. If metabolic activity of the CYP in the cells can be estimated, so can the function of metabolism, which is closer to the organism. In this research, the method of measuring the drug metabolic activity inside the cell by making use of an electrochemical technique was examined. Human hepatoma GS‐3A4‐HepG2 cells of which the cytochrome P‐4503A4 (CYP3A4) drug metabolic activity is found to be the same as that of primary hepatocytes were used in the experiment. The GS‐3A4‐HepG2 cells were cultured on an indium‐tin oxide (ITO) electrode until they became confluent. Substrate testosterone and inhibitor ketoconazole of CYP3A4 were exposed to cells cultured on an ITO electrode, and the reaction was observed by noting the electrochemical impedance measurement. Impedance was decomposed into the resistance component and the reactance component, and each was examined in detail. As a result, according to testosterone concentration change, there was a remarkable time change in the reactance component. A similar impedance measurement was done by using human hepatoma HepG2 cells in which the drug metabolic activity had extremely decreased. Nevertheless, no time change in the reactance component that was noticed in GS‐3A4‐HepG2 cells was observed. Next, the amount of metabolite in the solution after impedance measurement was measured by means of liquid chromatography‐tandem mass spectroscopy (LC‐MS/MS). In the experiment with GS‐3A4‐HepG2 cells, a testosterone concentration‐dependent correlation was observed between the reactance component change and the amount of metabolite. But, in the impedance measurement by ketoconazole, the change in reactance components was not observed in either the GS‐3A4‐HepG2 cells or the HepG2 cells. Ketoconazole and the heme iron in CYP3A4 effect the coordination bond, but ketoconazole was not metabolized by CYP3A4. It was confirmed that the time change in the reactance component which was caused by the testosterone was detected neither in the cells that take up the substrate, nor in the coordination bond between the CYP enzyme and the drug. Therefore, the time change in the remarkable reactance component observed by this electrochemical impedance measurement is dependent on drug metabolic activity. An electrochemical drug metabolic activity measuring method with the human hepatoma GS‐3A4‐HepG2 cells was able to be established. Copyright © 2004 John Wiley & Sons, Ltd.     

The Comparison of Electrochemical Assay and Agarose Gel Electrophoresis for the Determination of DNA Damage Induced by Kainic Acid

A possible DNA damage after interaction of kainic acid (KA) with calf thymus double stranded DNA and genomic DNA was herein determined in in vitro and in vivo conditions using; electrochemical assay and agarose gel electrophoresis. The changes in guanine signal were detected as an indicator of DNA damage in genomic DNA samples isolated from 1 or 10 mg/kg KA‐treated animals. The decreased levels of guanine signal were found as 29% and 33% by 1 and 10 mg/kg KA treatment when compared to controls, respectively. The results of gel electrophoresis confirmed DNA damage obtained in identical samples by electrochemical method.