Entwicklung eines impedimetrischen Biosensors für den Nachweis von Antigliadin Autoantikörpern

In der vorliegenden Arbeit wurde ein Biosensor für den Nachweis von Antikörpern gegen Gliadin entwickelt. Gliadine sind Bestandteile der Getreideglutene und verantwortlich für die Manifestation der Zöliakie (Gluten-Unverträglichkeit). Der Biosensor basiert auf der Immobilisierung von Gliadin auf Goldelektroden, die zuvor mit Polystyrensulfonsäure beschichtet worden waren. Die erfolgreiche Immobilisierung wurde mit Hilfe der Quarzmikrowaage dokumentiert. Die Antigen-Antikörper-Bindung konnte durch die Inkubation mit einem Peroxidase-markierten Zweitantikörper und der enzymatischen Oxidation von 3-Amino-9- Ethylcarbazol (AEC) verstärkt werden. Die Zunahme in der Elektrodenisolierung durch die Bindungs- und Ablagerungsreaktion konnte durch elektrochemische Impedanzspektroskopie (EIS) in Anwesenheit des Hexacyanoferrat- Redoxsystems gemessen werden. Die Spektren wurden mit Hilfe eines Randles-Ersatzschaltbildes ausgewertet. Hierbei konnte eine Zunahme im Ladungstransferwiderstand festgestellt werden, die pro portional zur Antigliadin-Antikörperkonzentration, im Bereich von 10-8 M bis 10-6 M, war. Mit Hilfe dieses Sensors wurden schließlich humane Seren hinsichtlich ihrer Konzentration an Gliadinantikörpern, sowohl für Immunglobuline vom Typ IgG als auch IgA, untersucht.In this study an immunosensor was developed for the analysis of anti-gliadin antibodies. These antibodies can serve as an early diagnostic marker for celiac disease. The sensor is based on polystyrenesulfonic acid modifi ed gold electrodes on which gliadin was immobilized. The anti-gliadin antibody recognition was amplifi ed by a second binding step with a peroxidase- labeled antibody and subsequent peroxidase-catalyzed oxidation of 3-amino-9-ethylcarbazole (AEC) resulting in a precipitate formation on the electrode. The change of the electrode surface properties was followed by impedance spectroscopy in the presence of ferri-/ferrocyanide. By evaluating the impedance spectra the charge transfer resistance was found to be a suitable sensor parameter. A calibration curve for the detection of anti-gliadin antibodies was established for antibody concentrations between 10-8 M and 10-6 M and the sensor was also applied for the analysis of serum samples

Oxygen-reducing electrodes based on layer-by-layer assemblies of cytochrome c and laccasse

Electroactive multilayer assemblies combining the redox protein cytochrome c and the enzyme laccase were fabricated by the layer-by-layer adsorption technique on gold electrodes and were shown to be capable of direct oxygen reduction. Laccase from trametes versicolor was electrostatically immobilized on multilayer films consisting of cytochrome c and the polyelectrolyte polyanilinesulfonic acid. The layer formation was monitored by quartz crystal microbalance. The electrochemical behavior of the electrodes was investigated by cyclic voltammetry. The resulting assembly exhibited a catalytic oxygen reduction current. This indicates a multi-step electron transport chain from the electrode via the cytochrome c layers towards laccase, and finally, to molecular oxygen. The catalytic efficiency of the electrodes was examined in the pH range from 4.5 to 7.0, showing highest enzymatic oxygen reduction at pH 4.5. Furthermore, the catalytic current was found to correlate linearly with the oxygen content of the solution. This suggests that the overall current is limited by the catalytic reduction of oxygen by the laccase rather than by the preceding electron transfer steps. Keywords: Laccase, Direct electron transfer (DET), Cytochrome c (cyt.c), Oxygen reduction, Layer-by-layer technique (LBL), Gold electrod

Natural products to drugs: Natural product derived compounds in clinical trials

Natural product and natural product-derived compounds that are being evaluated in clinical trials or in registration ( current 31 December 2004) have been reviewed. Natural product derived drugs launched in the United States of America, Europe and Japan since 1998 and new natural product templates discovered since 1990 are discussed

The combinatorial synthesis of bicyclic privileged structures or privileged substructures

Privileged substructures are of potentially great importance in medicinal chemistry. These scaffolds are characterized by their ability to promiscuously bind to a multitude of receptors through a variety of favorable characteristics. This may include presentation of their substituents in a spatially defined manner and perhaps also the ability to directly bind to the receptor itself, as well as exhibiting promising characteristics to aid bioavailability of the overall molecule. It is believed that some privileged substructures achieve this through the mimicry of common protein surface elements that are responsible for binding, such as β- and gamma;-turns. As a result, these structures represent a promising means by which new lead compounds may be identified