Giovanna Marrazza

Carbon and gold electrodes as electrochemical transducers for DNA hybridisation sensors

Genosensor technology relying on the use of carbon and gold electrodes is reviewed. The key steps of each analytical procedure, namely DNA-probe immobilisation, hybridisation, labelling and electrochemical investigation of the surface, are discussed in detail with separate sections devoted to label-free and newly emerging magnetic assays. Special emphasis has been given to protocols that have been used with real DNA samples.

Electrochemical and piezoelectric DNA biosensors for hybridisation detection

DNA biosensors (or genosensors) are analytical devices that result from the integration of a sequence-specific probe and a signal transducer. Among other techniques, electrochemical and piezoelectric methods have recently emerged as the most attractive due to their simplicity, low instrumentation costs, possibility for real-time and label-free detection and generally high sensitivity. Focusing on the most recent activity of worldwide researchers, the aim of the present review is to give the readers a critical overview of some important aspects that contribute in creating successful genosensing devices. Advantages and disadvantages of different sensing materials, probe immobilisation chemistries, hybridisation conditions, transducing principles and amplification strategies will be discussed in detail. Dedicated sections will also address the issues of probe design and real samples pre-treatment. Special emphasis will be finally given to those protocols that, being implemented into an array format, are already penetrating the molecular diagnostics market.

Ink-jet printing for the fabrication of amperometric glucose biosensors

Ink-jet printing has been demonstrated as a manufacturing technique that facilitates the rapid, reproducible and economical production of amperometric glucose biosensors. Glucose was chosen as the ...

Electrochemical DNA biosensor as a screening tool for the detection of toxicants in water and wastewater samples.

Applications of a disposable electrochemical DNA biosensor to standard solutions and to real samples are reported. The DNA biosensor is assembled by immobilising the double stranded calf thymus DNA on the surface of a disposable carbon screen-printed electrode. The immobilised ds-DNA interacts with the sample for 2 min; then is washed and immersed in a clean buffer where the analytical signal (the oxidation peak area of the guanine base) is obtained by a square-wave voltammetric scan. The results were compared with some currently used toxicity tests and in particular with a commercial luminescent bacteria test, Toxalert(R)100.

Electrochemical DNA biosensor for analysis of wastewater samples

The application of a disposable electrochemical DNA biosensor to wastewater samples is reported. The DNA biosensor is assembled by immobilising double-stranded calf thymus DNA on the surface of a disposable, carbon screen-printed electrode (SPE). The oxidation signal of the guanine base, obtained by a square wave voltammetric scan, is used as analytical signal. The presence of compounds with affinity for DNA is measured by their effect on the guanine oxidation. The comparison of the results with a toxicity test based on bioluminescent bacteria has confirmed the applicability of the method to real samples.

Disposable electrochemical DNA-array for PCR amplified detection of hazelnut allergens in foodstuffs

An electrochemical low-density DNA-array has been designed and implemented to be used in combination with polymerase chain reaction (PCR) in order to investigate the presence of hazelnut major allergens (Cor a 1.04, Cor a 1.03) in foodstuff. Unmodified PCR products were captured at the sensor interface via sandwich hybridization with surface-tethered probes and biotinylated signalling probes. The resulting biotinylated hybrids were coupled with a streptavidin-alkaline phosphatase conjugate and then exposed to a alpha-naphthyl phosphate solution. Differential pulse voltammetry was finally used to detect the alpha-naphthol signal. The detection limits for Cor a 1.03 and Cor a 1.04 were 0.3 and 0.1 nmol L(-1), respectively (R.S.D. 10%). The optimized conditions were used to test several commercially available foodstuffs, claiming to contain or not the targeted nuts. The results were compared with those obtained with classical ELISA tests.

Microfluidic-based electrochemical genosensor coupled to magnetic beads for hybridization detection

This paper describes the development of a rapid and sensitive enzyme-linked electrochemical genosensor using a novel microfluidic-based platform. In this work, hybridization was performed on streptavidin-coated paramagnetic micro-beads functionalized with a biotinylated capture probe. The complementary sequence was then recognized via sandwich hybridization with a capture probe and a biotinylated signaling probe. After labeling the biotinylated hybrid with a streptavidin-alkaline phosphatase conjugate, the beads were introduced in a disposable cartridge composed of eight parallel microchannels etched in a polyimide substrate. The modified beads were trapped with a magnet addressing each microchannel individually. The presence of microelectrodes in each channel allowed direct electrochemical detection of the enzymatic product within the microchannel. Detection was performed in parallel within the eight microchannels, giving rise to the possibility of performing a multiparameter assay. Quantitative determinations of the analyte concentrations were obtained by following the kinetics of the enzymatic reaction in each channel. The chip was regenerated after each assay by removing the magnet and thus releasing the magnetic beads. The system was applied to the analytical detection of PCR amplified samples with a RSD%=6. A detection limit of 0.2 nM was evaluated.

Electrochemical DNA probes

A report on the status of the electrochemical DNA probes for the detection of a DNA sequence for environmental and clinical studies is presented. The literature on the electrochemistry of DNA in the last ten years is reviewed. Results obtained in this laboratory using an electroactive hybridization indicator for constructing an electrochemical DNA probe are reported.

Electrochemical immunosensors in breast and ovarian cancer.

During the last decades the incidence of cancer increased dramatically especially in developed countries. In spite of the fact that the immunochemical methods allowed the diagnosis in early stages, the biopsies are generally invasive methods that create discomfort to patients. The need for fast, sensitive, easy to use and noninvasive diagnosis tools is actually of great interest for many research groups all over the world. Immunosensors (ISs) are miniaturized measuring devices, which selectively detect their targets by means of antibodies (Abs) and provide concentration-dependent signals. Ab binding leads to a variation in electric charge, mass, heat or optical properties, which can be detected directly or indirectly by a variety of transducers. A great number of proteins could be considered as recognition element. In this review the attention was focused on main cancer biomarkers, currently used by immunological methods (immunohistochemistry, ELISA, flow cytometry, Western blot, immunofluorescence etc) and in the development of electrochemical immunoassays that could be used in cancer diagnosis, prognosis and therapy monitoring.

Enzyme-amplified electrochemical hybridization assay based on PNA, LNA and DNA probe-modified micro-magnetic beads.

In the present study, we investigated the properties of PNA and LNA capture probes in the development of an electrochemical hybridization assay. Streptavidin-coated paramagnetic micro-beads were used as a solid phase to immobilize biotinylated DNA, PNA and LNA capture probes, respectively. The target sequence was then recognized via hybridization with the capture probe. After labeling the biotinylated hybrid with a streptavidin-enzyme conjugate, the electrochemical detection of the enzymatic product was performed onto the surface of a disposable electrode. The assay was applied to the analytical detection of biotinylated DNA as well as RNA sequences. Detection limits, calculated considering the slope of the linear portion of the calibration curve in the range 0-2 nM were found to be 152, 118 and 91 pM, coupled with a reproducibility of the analysis equal to 5, 9 and 6%, calculated as RSD%, for DNA, PNA and LNA probes respectively, using the DNA target. In the case of the RNA target, the detection limits were found to be 51, 60 and 78 pM for DNA, PNA and LNA probes respectively.