Investigations in bioanalytical chemistry part VIII: Derivative adsorption chronopotentiometry of the Cu<sup>II</sup> complex with adenine, adenosine and adenosine monophosphate

Zhao, Xin; Jin, Wenrui; Tang, Jian

doi:10.1002/elan.1140080413

Cited by 5 publications

(2 citation statements)

References 16 publications

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“…[13][14][15] There is no literature data concerning the behaviour of adenine in solutions at pH 3 and 4, which encourages the studying of the adsorption of this compound. The selection of these pH values results from the fact that information concerning adenine adsorption will be used to study the kinetics of specific non-organic depolarisers, e. g. Zn(II), Cd(II) or Pb(II) ions in the presence of this organic compound.…”

Section: Introductionmentioning

confidence: 99%

The Effect of Adenine Adsorption on Zn (II) Electroreduction in Acetate Buffer

Gugała-Fekner

2018

ACSi

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The paper presents the thermodynamic analysis of adenine adsorption on a mercury electrode in an acetate buffer at pH 3 and pH 4. Adsorption energy and constants were determined using the Frumkin isotherm and the virial isotherm. Stronger adsorption in the buffer at pH 3 was observed in comparison to the buffer at pH 4. Using cyclic voltammetry and Faraday impedance measurement, an inhibitory effect of adenine on the kinetics of Zn (II) ion electro-reduction was observed.

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Section: Introductionmentioning

confidence: 99%

The Effect of Adenine Adsorption on Zn (II) Electroreduction in Acetate Buffer

Gugała-Fekner

2018

ACSi

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“…2). Based on formation of Cu(II) complex with adenine, the determination of adenine has been accomplished using derivative adsorption chronopotentiometry [25]. On the other hand sparingly soluble complex of copper(I) with adenine can be accumulated on the electrode surface by reduction of Cu(II) ions [26 ± 29].…”

Section: Methodsmentioning

confidence: 99%

Determination of Copper by Adsorptive Stripping Voltammetry of Its Complex with Adenine

et al. 2002

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Electrochemical Analysis of Nucleic Acids

Paleček

Fojta

Jelen

et al. 2002

Encyclopedia of Electrochemistry

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The sections in this article are Introduction History Nucleic Acid Samples Electrochemical Behavior of NA Components Adsorption/Desorption Behavior Mercury Electrodes Solid Electrodes Reduction and Oxidation Microanalysis of Nucleic Acid Components by Stripping Techniques Principles Reactions of Pyrimidine and Purine Bases with the Electrode Mercury Unusual Bases and Nucleosides Sparingly Soluble Compounds of Nucleic Acid Components with Copper Adsorption/Desorption Behavior of NAs Mercury Dropping Electrode Adsorption of Double‐stranded (Native) DNA Adsorption of Single‐stranded (Denatured) DNA Adsorption Kinetics at Mercury Dropping and Hanging Electrodes Electrochemical Impedance Spectroscopy ( EIS ) Other Techniques Adsorption of NAs on Other Electrodes DNA Adsorption to Charged Lipid Membranes Reduction and Oxidation of NAs on Different Electrodes Mercury Electrodes Reduction of Adenine and Cytosine Residues Anodic Signal of Guanine Residues Carbon Electrodes Other Solid Electrodes Analysis of NAs by Different Electrochemical Techniques Relations Between Structures and Electrochemical Responses of DNA DNA Structure on Electrode Surfaces Dependence of the ds DNA Signals at the HMDE on Potential Scanning Direction Opening of the DNA Double Helix Around −1.2 V (Region U ) Opening of ds DNA at Acid p Hs in a Wider Potential Range T Interactions of NAs with Small Molecules Reversible (Noncovalent) Interactions Inorganic Cations and Simple Metal Complexes Organic Metal Chelates Other Noncovalent DNA Binders Covalent Interactions Electroactive Markers of NAs Other Nucleic Acid Modifications DNA Conductivity Application of Electrodes in DNA Conductivity Studies Analytical Applications Sensors for DNA Hybridization Immobilization of DNA on the Electrode Detection of the Hybridization Event Redox Indicators Covalently Bound to DNA Indicator‐free Detection Systems. Intrinsic Electroactivity of DNA Changes in Interfacial Properties and DNA Conductivity Blocking and Interfacing the Transducer Electrocatalytic Reactions Detection of Point Mutations Sensors for DNA Damage Detection of DNA Strand Breaks Damage to DNA Bases Detection of Damaging Agents Specifically Interacting with DNA DNA Cleavage Controlled by Electrochemical Reactions Other Determinations Determination of ss DNA in an Excess of ds DNA Determination of RNA Traces in DNA Solutions Determination of Proteins Conclusion Addendum Acknowledgment

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Investigations in bioanalytical chemistry part VIII: Derivative adsorption chronopotentiometry of the Cu^II complex with adenine, adenosine and adenosine monophosphate

Cited by 5 publications

References 16 publications

The Effect of Adenine Adsorption on Zn (II) Electroreduction in Acetate Buffer

The Effect of Adenine Adsorption on Zn (II) Electroreduction in Acetate Buffer

Determination of Copper by Adsorptive Stripping Voltammetry of Its Complex with Adenine

Electrochemical Analysis of Nucleic Acids

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Investigations in bioanalytical chemistry part VIII: Derivative adsorption chronopotentiometry of the CuII complex with adenine, adenosine and adenosine monophosphate

Cited by 5 publications

References 16 publications

The Effect of Adenine Adsorption on Zn (II) Electroreduction in Acetate Buffer

The Effect of Adenine Adsorption on Zn (II) Electroreduction in Acetate Buffer

Determination of Copper by Adsorptive Stripping Voltammetry of Its Complex with Adenine

Electrochemical Analysis of Nucleic Acids

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Product

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Investigations in bioanalytical chemistry part VIII: Derivative adsorption chronopotentiometry of the Cu^II complex with adenine, adenosine and adenosine monophosphate