M. del Valle

Use of nanomaterials for impedimetric DNA sensors: a review.

This review presents the state of the art of DNA sensors (or genosensors) that utilize electrochemical impedance spectroscopy as the transduction technique. As issue of current interest, it is centered on the use of nanomaterials to develop or to improve performance of these specific biosensors. It will describe the different principles that may be employed in the measuring step and the different formats adopted for detection of a DNA sequence or confirmation or amplification of the finally obtained signal. The use of nanomaterials for the above listed aspects, viz. the use of carbon nanotubes or other nanoscopic elements in the construction of the electrodes, or the use of nanoparticles, mainly gold or quantum dots, for signal enhancement will be fully revised.

Automated resolution of dichlorvos and methylparaoxon pesticide mixtures employing a Flow Injection system with an inhibition electronic tongue

An amperometric biosensor array has been developed to resolve pesticide mixtures of dichlorvos and methylparaoxon. The biosensor array has been used in a Flow Injection system, in order to operate automatically the inhibition procedure. The sensors used were three screen-printed amperometric biosensors that incorporated three different acetylcholinesterase enzymes: the wild type from Electric eel and two different genetically modified enzymes, B1 and B394 mutants, from Drosophila melanogaster. The inhibition response triplet was modelled using an Artificial Neural Network which was trained with mixture solutions that contain dichlorvos from 10(-4) to 0.1 microM and methylparaoxon from 0.001 to 2.5 microM. This system can be considered an inhibition electronic tongue.

A review of the use of the potentiometric electronic tongue in the monitoring of environmental systems

This paper introduces electronic tongue systems for remote environmental monitoring applications. This new approach in the chemical sensor field consists of the use of an array of non-specific sensors coupled with a multivariate calibration tool which may form a node of a sensor network. In our work, the proposed arrays were made up of potentiometric sensors based on polymeric membranes, and the subsequent cross-response processing was based on a multilayer artificial neural network model. Two cases are described: the environmental monitoring of ammonium pollutant plus alkaline ions at different measuring sites in the states of Mexico and Hidalgo (Mexico), and the monitoring of heavy metals (Cu^2^+, Pb^2^+, Zn^2^+ and Cd^2^+) in open air waste streams and rivers heading down the Gulf of Mexico.

Sequential injection system with higher dimensional electrochemical sensor signals: Part 1. Voltammetric e-tongue for the determination of oxidizable compounds

A sequential injection analysis (SIA) system was developed with the aim of obtaining an automatic and versatile way to prepare standards needed in the study of systems with higher dimensional sensor signals. To illustrate this, different analytical techniques were used in determinations of several analytes. Automated potentiometric calibrations of different potentiometric sensors, with and without interference, were carried out. Useful determinations of selectivity coefficients with two degrees of freedom were obtained. Simultaneous voltammetric determinations have also been done. Firstly, simultaneous determinations of lead and cadmium, using epoxy-graphite composite as the working electrode, have enabled a separate calibration for each metal to be obtained. Next, a voltammetric electronic tongue was designed and applied to the determination of oxidizable species. The use of artificial neural networks has solved the overlapped signal of ascorbic acid, 4-aminophenol and 4-acetamidophenol (paracetamol). A set of 63 data points was prepared automatically and has facilitated the training of an electronic tongue for these three analytes. Accurate predictions of test solutions, in the range of 12-410muM for ascorbic acid, 17-530muM for 4-aminophenol and 10-420muM for paracetamol, have been achieved with RMSEs lower than 0.10muM.

Impedimetric genosensors employing COOH-modified carbon nanotube screen-printed electrodes.

Screen-printed electrodes modified with carboxyl functionalised multi-walled carbon nanotubes were used as platforms for impedimetric genosensing of oligonucleotide sequences specific for transgenic insect resistant Bt maize. After covalent immobilization of aminated DNA probe using carbodiimide chemistry, the impedance measurement was performed in a solution containing the redox marker ferrocyanide/ferricyanide. A complementary oligomer (target) was then added, its hybridization was promoted and the measurement performed as before. The change of interfacial charge transfer resistance between the solution and the electrode surface, experimented by the redox marker at the applied potential, was recorded to confirm the hybrid formation. Non-complementary DNA sequences containing a different number of base mismatches were also employed in the experiments in order to test specificity. A signal amplification protocol was then performed, using a biotinylated complementary target to capture streptavidin modified gold nanoparticles, thus increasing the final impedimetric signal (LOD improved from 72 to 22 fmol, maintaining a good reproducibility, in fact RSD<12.8% in all examined cases). In order to visualize the presence and distribution of gold nanoparticles, a silver enhancement treatment was applied to electrodes already modified with DNA-nanoparticles conjugate, allowing direct observation by scanning electron microscopy.

Determination of Anionic Surfactants Employing Potentiometric Sensors—A Review

Abstract This article describes the ongoing evolution of potentiometric sensors as employed in the field of anionic surfactants, beginning with the first reports published in the 1960s. Although the 1970s saw an increased use of such devices due to the adoption of PVC matrices, it is only relatively recently that commercial electrodes for these species have been available to industry. The latest developments, particularly the study of new polymer formulations and their application to other transducing devices, are also discussed.

Sensitive stripping voltammetry of heavy metals by using a composite sensor based on a built-in bismuth precursor

A new graphite-epoxy composite electrode (GECE) containing Bi(NO(3))(3) as a built-in bismuth precursor for simultaneous and individual anodic stripping analysis of heavy trace metals like lead and cadmium is reported. The developed Bi(NO(3))(3)-GECE is compatible with bismuth film electrodes reported previously including the composite electrodes (Bi-GECE) recently reported by our group. Bi(NO(3))(3)-GECE displays the ability for the detection of both individual and simultaneous determination of heavy trace metals and exhibits well defined, reproducible and sharp stripping signals. The sensitive response is combined with the minimal toxicity of Bi(NO(3))(3). This novel sensor would be an appropriate alternative tool to sensors using bismuth in solution during their utilization in environmental quality monitoring as well as other applications.

Sandwich Techniques in flow injection analysis : Part 1. Continuous recalibration techniques for process control

Abstract Flow injection methodology based on sample insertion between two different standard solutions used as carrier streams is described. This approach provides a simple system for continuous recalibration in process control; spectrophotometric and ion-selective electrode procedures are outlined.

Electrochemical immunosensor for the diagnosis of celiac disease

A novel electrochemical immunosensing strategy for the detection of antibodies to tissue transglutaminase (tTG) in human serum is presented. The proposed immunosensor consists of the immobilization by physical adsorption of tTG from guinea pig liver on graphite-epoxy composite (GEC) electrodes. After the reaction with the human serum (containing the specific antibodies in the case of celiac disease), the electrode was incubated with different kinds of secondary labeled antibodies, namely, horseradish peroxidase (HRP)-conjugated goat antibodies to human whole immunoglobulins (Igs), to human IgG, and finally to human IgA. Among the different classes of antibodies in human serum toward tTG, the best results were achieved when anti-tTG IgA antibodies were investigated. In total, 10 positive and 10 negative serum samples were processed, obtaining a sensitivity of 70% and a specificity of 100% compared with the commercial enzyme-linked immunosorbent assay (ELISA) method performed in a hospital laboratory. This strategy offers great promise for a simple, cost-effective, and user-friendly analytical method that allows point-of-care diagnosis of celiac disease.

Flow-through tubular ion-selective electrodes responsive to anionic surfactants for flow-injection analysis

Abstract A flow-injection system based on potentiometric detection and designed for the monitoring of anionic surfactant content of printing plates washing solutions is described. Two new PVC membrane ion-selective electrodes, constructed with an all-solid-state tubular flow-through design, are used. The sample, with high ionic strength and extremely alkaline pH, is conditioned in a two-channel flow-injection system, allowing for surfactant determination in the 1 × 10 −4 to 1 × 10 −3 M range, with NaOH contents up to 0.3 M.