María L. Pedano

Carbon nanotubes for electrochemical biosensing.

The aim of this review is to summarize the most relevant contributions in the development of electrochemical (bio)sensors based on carbon nanotubes in the last years. Since the first application of carbon nanotubes in the preparation of an electrochemical sensor, an increasing number of publications involving carbon nanotubes-based sensors have been reported, demonstrating that the particular structure of carbon nanotubes and their unique properties make them a very attractive material for the design of electrochemical biosensors. The advantages of carbon nanotubes to promote different electron transfer reactions, in special those related to biomolecules; the different strategies for constructing carbon nanotubes-based electrochemical sensors, their analytical performance and future prospects are discussed in this article.

Immobilization of DNA on glassy carbon electrodes for the development of affinity biosensors

The adsorption and electrooxidation of nucleic acids on glassy carbon electrodes are evaluated by using chronopotentiometric stripping analysis. The influence of electrochemical pretreatments, supporting electrolyte, halides and monovalent cations levels as well as the role of the oligonucleotide length and composition, accumulation potential and time on the adsorption and further electrooxidation of oligo(dG)(11) and oligo(dG)(21) are discussed. The adsorption behavior of single and double stranded calf thymus DNA on untreated glassy carbon electrodes is also evaluated. Trace (microg/l) levels of the oligonucleotides and polynucleotides can be readily detected following short accumulation periods with detection limits of 25, 60, 126 and 219 microg/l for oligo(dG)(21), oligo(dG)(11), ss and ds calf thymus DNA, respectively. The confined DNA layers demonstrated to be stable in air, in 0.200 M acetate buffer pH 5.00 and in 0.020 M phosphate buffer pH 7.40+0.50 M NaCl.

Comparative study of the electrochemical behavior and analytical applications of (bio)sensing platforms based on the use of multi-walled carbon nanotubes dispersed in different polymers

This review present a critical comparison of the electrochemical behavior and analytical performance of glassy carbon electrodes (GCE) modified with carbon nanotubes (CNTs) dispersed in different polymers: polyethylenimine (PEI), PEI functionalized with dopamine (PEI-Do), polyhistidine (Polyhis), polylysine (Polylys), glucose oxidase (GOx) and double stranded calf-thymus DNA (dsDNA). The comparison is focused on the analysis of the influence of the sonication time, solvent, polymer/CNT ratio, and nature of the polymer on the efficiency of the dispersions and on the electrochemical behavior of the resulting modified electrodes. The results allow to conclude that an adequate selection of the polymers makes possible not only an efficient dispersion of CNTs but also, and even more important, the building of successful analytical platforms for the detection of different bioanalytes like NADH, glucose, DNA and dopamine.

Electrochemical Biosensors for Sequence‐Specific DNA Detection

Abstract This review summarizes the most relevant work performed in the last years in the field of the DNA-based electrochemical biosensors for sequence-specific DNA detection. The approaches used for preparing the biosensing layer, as well as the schemes developed for the transduction of the hybridization event are also discussed.

Supramolecular architecture based on the self-assembling of multiwall carbon nanotubes dispersed in polyhistidine and glucose oxidase: Characterization and analytical applications for glucose biosensing

We report for the first time the development of a sensitive and selective glucose biosensor based on the self-assembling of multiwall carbon nanotubes (MWCNTs) dispersed in polyhistidine (Polyhis) and glucose oxidase (GOx) on glassy carbon electrodes (GCE). The supramolecular architecture was characterized by SEM, FT-IR and electrochemical techniques. The optimum multistructure was obtained with five (MWCNT-Polyhis/GOx) bilayers and one layer of Nafion as anti-interferent barrier. The sensitivity at 0.700V was (1.94±0.03) mAM(-1) (r=0.9991), with a linear range between 0.25 and 5.00mM, a detection limit of 2.2μM and a quantification limit of 6.7μM with minimum interference from lactose (1.5%), maltose (5.7%), galactose (1.2%), ascorbic acid (1.0%), and uric acid (3.3%). The biocatalytic layer demonstrated to be highly reproducible since the R.S.D. for 10 successive amperometric calibrations using the same surface was 3.6%. The sensitivity of the biosensor after 15 day storage at 4°C remained at 90% of its original value. The combination of the excellent dispersing properties and polycationic nature of polyhistidine, the stability of the MWCNT-Polyhis dispersion, the electrocatalytic properties of MWCNTs, the biocatalytic specificity of GOx, and the permselective properties of Nafion have allowed building up a sensitive, selective, robust, reproducible and stable glucose amperometric biosensor for the quantification of glucose in milk samples.

Dispersion of multi-wall carbon nanotubes in polyhistidine: characterization and analytical applications.

We report for the first time the use of polyhistidine (Polyhis) to efficiently disperse multiwall carbon nanotubes (MWCNTs). The optimum dispersion MWCNT-Polyhis was obtained by sonicating for 30 min 1.0 mg mL(-1) MWCNTs in 0.25 mg mL(-1) Polyhis solution prepared in 75:25 (v/v) ethanol/0.200 M acetate buffer solution pH 5.00. The dispersion was characterized by scanning electron microscopy, and by cyclic voltammetry and amperometry using ascorbic acid as redox marker. The modification of glassy carbon electrodes with MWCNT-Polyhis produces a drastic decrease in the overvoltage for the oxidation of ascorbic acid (580 mV) at variance with the response observed at glassy carbon electrodes modified just with Polyhis, where the charge transfer is more difficult due to the blocking effect of the polymer. The reproducibility for the sensitivities obtained after 10 successive calibration plots using the same surface was 6.3%. The MWCNT-modified glassy carbon electrode demonstrated to be highly stable since after 45 days storage at room temperature the response was 94.0% of the original. The glassy carbon electrode modified with MWCNT-Polyhis dispersion was successfully used to quantify dopamine or uric acid at nanomolar levels, even in the presence of large excess of ascorbic acid. Determinations of uric acid in human blood serum samples demonstrated a very good correlation with the value reported by Wienner laboratory.

Layer-by-layer deposition of chitosan derivatives and DNA on gold surfaces for the development of biorecognition layers

Abstract We describe a new supramolecular architecture obtained by deposition of double‐stranded deoxyribonucleic acid (dsDNA) and chitosan derivatives on a thiolated gold surface. Surface plasmon resonance was used to monitor, in real time, the construction of the supramolecular architecture. Three chitosan derivatives were used, a quaternized N‐substituted by three methyl groups in a 40.0 mol%, and two others N‐substituted with an octyl chain in a 5.0 and 25.0 mol%. The multilayer formation depends on the degree of substitution of chitosan as well as on the nature of the substituents. The adsorption of dsDNA is slower than that of chitosan. The best immobilization of dsDNA is obtained by using a quaternized chitosan and dsDNA prepared in 0.050 M acetate buffer pH 5.00. The system is stable in buffer solution independently of the nature of the chitosan derivative. The effect of the nature of the electrolyte and ionic strength is also discussed.

Amperometric biosensor for the quantification of gentisic acid using polyphenol oxidase modified carbon paste electrode

The affinity of mushroom polyphenol oxidase (PPO) towards gentisic acid (GA), a metabolite of acetyl salicylic acid (ASA), is demonstrated by spectrophotometry and by electrochemical techniques. The enzyme can selectively recognize GA even in the presence of large excess of ASA and its metabolic derivatives (salicylic acid (SA) and salicyluric acid (SUA)). At -0.150 V, the sensitivity is (6.1+/-0.1)x10(4) NAM(-1), the response is linear up to 2.0x10(-4) M and the detection limit is 5.0x10(-5) M. The kinetic parameters, obtained from Eadie-Hofstee plots, are I(max)=51.4 nA and K(m)(app)=6.7x10(-4) M.

Adsorption and Electrooxidation of DNA at Glassy Carbon Paste Electrodes

This work reports the study of the adsorption and electrooxidation of nucleic acids on glassy carbon paste electrodes (GCPE) by using chronopotentiometric stripping analysis. The influence of electrochemical pretreatments, binder content, supporting electrolyte, accumulation potential, and time on the adsorption and further electrooxidation of oligo(dG)21 is discussed. The adsorption behavior of double stranded calf thymus DNA (dsDNA) on GCPE is also evaluated. Trace (ppb) levels of oligo(dG)21 and (ppm) levels of dsDNA can be readily detected following short accumulation periods, with detection limits of 21 ppb and 200 ppb for oligo(dG)21 and dsDNA, respectively. The confined DNA layer demonstrated to be stable in air, in 0.200 M acetate buffer pH 5.00, and in 0.020 M phosphate buffer pH 7.40 + 0.50 M NaCl.