Voltammetric Sensor for Direct Insulin Detection

AbstractThis work covers an area of planar electrochemical sensors for fast and reliable detection of species in environment under field conditions or in vitro/vivo biodetection. In this work, there were fabricated several planar carbon working electrodes using standard thick film technology which were modified with multiwalled carbon nanotubes (MWCNTs) to promote the electrochemical oxidation of insulin. These standalone planar working electrodes were successfully used for direct detection of insulin using cyclic voltammetry in electrochemical cell against conventional Ag/AgCl reference electrode and platinum auxiliary electrode

Carbon composite micro- and nano-tubes-based electrodes for detection of nucleic acids

The first aim of this study was to fabricate vertically aligned multiwalled carbon nanotubes (MWCNTs). MWCNTs were successfully prepared by using plasma enhanced chemical vapour deposition. Further, three carbon composite electrodes with different content of carbon particles with various shapes and sizes were prepared and tested on measuring of nucleic acids. The dependences of adenine peak height on the concentration of nucleic acid sample were measured. Carbon composite electrode prepared from a mixture of glassy and spherical carbon powder and MWCNTs had the highest sensitivity to nucleic acids. Other interesting result is the fact that we were able to distinguish signals for all bases using this electrode

Carbon composite micro- and nano-tubes-based electrodes for detection of nucleic acids

Abstract The first aim of this study was to fabricate vertically aligned multiwalled carbon nanotubes (MWCNTs). MWCNTs were successfully prepared by using plasma enhanced chemical vapour deposition. Further, three carbon composite electrodes with different content of carbon particles with various shapes and sizes were prepared and tested on measuring of nucleic acids. The dependences of adenine peak height on the concentration of nucleic acid sample were measured. Carbon composite electrode prepared from a mixture of glassy and spherical carbon powder and MWCNTs had the highest sensitivity to nucleic acids. Other interesting result is the fact that we were able to distinguish signals for all bases using this electrode.</p

Chování komplexů zinku a nanočástic a nanočástic sulfidu zinečnáteho s použitím tištěných elektrod a spektrometrie

In this study, we focused on microfluidic electrochemical analysis of zinc complexes (Zn(phen)(his)Cl-2, Zn(his)Cl-2) and ZnS quantum dots (QDs) using printed electrodes. This method was chosen due to the simple (easy to use) instrumentation and variable setting of flows. Reduction signals of zinc under the strictly defined and controlled conditions (pH, temperature, flow rate, accumulation time and applied potential) were studied. We showed that the increasing concentration of the complexes (Zn(phen)(his)Cl-2, Zn(his)Cl-2) led to a decrease in the electrochemical signal and a significant shift of the potential to more positive values. The most likely explanation of this result is that zinc is strongly bound in the complex and its distribution on the electrode is very limited. Changing the pH from 3.5 to 5.5 resulted in a significant intensification of the Zn(II) reduction signal. The complexes were also characterized by UV/VIS spectrophotometry, chromatography, and ESI-QTOF mass spectrometry.V této studii jsme se zaměřili na mikrofluidní elektrochemickou analýzu komplexů zinku (Zn (fenyl) (jeho) Cl-2, Zn (jeho) Cl-2) a ZnS kvantové tečky (QDS) za použití tištěných elektrod. Tato metoda byla zvolena z důvodu jednoduchému (snadné použití přístrojového vybavení) a variabilnímu nastavení toků. Byly studovány signály Redukční zinku v rámci přísně definovaných a kontrolovaných podmínek (pH, teplota, průtok, doba akumulace a aplikované potenciál). Ukázali jsme, že zvyšující se koncentrace komplexů (Zn (phen) (jeho) Cl-2, Zn (jeho) Cl-2) vede ke snížení elektrochemického signálu a významný posun potenciálu na více pozitivních hodnot. Nejpravděpodobnějším vysvětlením tohoto výsledku je, že zinek je silně vázána v komplexu a jeho rozložení na elektrodě je velmi omezený. Změna pH 3,5-5,5 vedlo k významnému zesílení Zn (II) signálu snížení. Komplexy byly také charakterizovány pomocí UV spektrofotometrie / VIS, chromatografie a ESI-QTOF hmotnostní spektrometrií. (Přeloženo strojově