Electrodeposition of
silver amalgam particles (AgAPs) on various substrates offers perspective tool
in development of novel electrochemical detection system applicable even in direct
bioelectrochemistry of nucleic acids or proteins. Herein, a double pulse
chronoamperometric deposition of AgAPs on in-house fabricated screen-printed
silver electrodes (SPAgE) has been optimized using voltammetric signal of model
electrochemically reducible organic nitro-compound, 4-nitrophenol, and scanning
electron microscopy with energy dispersive X-ray spectrometer. This compact
sensor including graphite counter and Ag|AgCl pseudo-reference
electrode was design for highly
effective analysis of electrochemically reducible compounds in 96-well plate
with about 150-µl sample volume per well. The SPAgE-AgAP offers detection of 4-NP
down to 5 µmol.l<sup>−1</sup> using cyclic voltammetry in acetate buffer
pH 5.0. Advantageously, differential pulse voltammetry at SPAgE-AgAP allows highly
sensitive detection system of unnatural nucleosides dTPT3 and d5SICS, which
successfully expanded genetic alphabet of recently studied semi-synthetic
organism, with limits of detection 0.1 pg.µl<sup>−1</sup> in 0.05 mol.l<sup>−1</sup>
hydrochloric acid. Moreover, these artificial nucleosides are detectable in the
mixture with natural nucleosides up to weight ratio 1 : 15 000. SPAgE-AgAP
may be potentially utilized in simple, fast and sensitive electrochemical detection
of organic nitro compounds and free or in DNA harbored dTPT3 and/or d5SICS,
what may contribute in successful research and development of semi-synthetic
organism perspective in chemical and synthetic biology.
Electrochemical detection of arsenite with silver electrodes in inorganic electrolyte and natural system mixtures
