Current strategies for electrochemical detection of DNA with solid electrodes

An electrochemical method for the citotoxic prodrug cladribine determination is proposed. Graphite electrodes modified with cladribine showed a redox process with a formal potential of 0.173 V at pH 6, after the oxidation of the adenine moiety of the drug, whose current can be employed as analytical signal with a detection limit of 75 nM by square-wave voltammetry. As these oxidation products exhibit great electrocatalytic activity toward the electrooxidation of NADH at low potentials, the analytical response can further be amplified. As a result, the detection limit was improved up to 1 nM using differential pulse voltammetry. The method was applied to the determination of cladribine in serum and urine samples after solid-phase extraction. No electroactive interferences were found in both fluids. The method allows the selective detection of the drug in the presence of the main metabolite, 2-chloroadenosine, which is not able to electrocatalize the NADH oxidation.

supporting

confidence: 71%

Catalytic Voltammetric Determination of Cladribine in Biological Samples

de‐los‐Santos‐Álvarez

Lobo-Castañón

Miranda‐Ordieres

et al. 2003

“…Although it is possible to carry out the selection of the aptamer (SELEX) using labeled oligonucleotides libraries to ensure the perfect binding of the aptamer selected to the analyte [92], label-free methods are highly desirable and are experiencing an important development with improved sensitivity [62].…”

Section: Label-free Methodsmentioning

confidence: 99%

“…Since then, an exponential number of electrochemical devices have appeared. The discussion will be focused on the latest improvements that have not been covered in previous reviews [61,62,65].…”

Section: Aptamer-based Sensorsmentioning

confidence: 99%

Structured Nucleic Acid Probes for Electrochemical Devices

Miranda‐Castro¹,

de‐los‐Santos‐Álvarez²,

Lobo-Castañón³

et al. 2009

The use of nucleic acid with a specific sequence and a highly ordered secondary structure such as hairpins, quadruplexes and pseudoknots as biological recognition elements and switches in biosensors is rapidly increasing because of their improved features (e.g. selectivity) when compared with the traditional linear probes. Owing to the novelty, a critical outlook of their characteristics and a compilation of the latest advances are lacking. This article describes the potential of those nucleic acids probes whose molecular recognition ability relies on a conformational change (e.g. folding/unfolding mechanism) in electrochemical sensing. It provides an overview of the toolbox of assays using these probes for genosensors and aptasensors, highlighting its performance characteristics and the prospects and challenges for biosensor design.

“…This catalytic activity was attributed to the 2,8-dioxoadenine derivative with quinoneimine structure, generated after the electrochemical oxidation of the adenine moiety in the molecule. This structure is stabilized from nucleophilic attack by the bulk substituent in N9 position of the adenine [2].…”

Section: Introductionmentioning

confidence: 97%

Electrochemical and Catalytic Properties of the Adenine Coenzymes FAD and Coenzyme A on Pyrolytic Graphite Electrodes

de‐los‐Santos‐Álvarez

Lobo-Castañón

Miranda‐Ordieres

et al. 2005

Redox properties of two coenzymes, flavin adenine dinucleotide (FAD) and coenzyme A (CoA) are studied on pyrolytic graphite electrodes. Both of them exhibit an oxidation process at about 1.2 V in pH 9, associated with the oxidation of their adenine moiety. The resulting adsorbed oxidation products have a common structure, an electroactive quinone-imine that acts as efficient catalyst of the oxidation of NADH at low potentials. The influence of the structure on their electrochemical features in comparison with other adenine derivatives is studied. Finally, a modified electrode prepared with the oxidation product of CoA was used to determine NADH in a wide linear range (1 Â 10 À8 -2.43 Â 10 À5 M) with a detection limit of 3 nM.