Ionophoric and aptameric recognition-modulated electroactive polyaniline films for the determination of tetrodotoxin

Fomo, Gertrude

January 2014

Philosophiae Doctor - PhD / Tetrodotoxin (TTX) is a nonpeptidic neurotoxin with a high rate of food poisoning mortality (60%) that has been associated with the consumption of diets from puffer fish and mud snails harbouring TTX-producing bacteria. As this neurotoxin has no known antidote and could not be mitigated by cooking, the only way for safety appears to be the detection of TTX-contaminated fishes at the points of harvest and control. The overall aim of this study was to develop amperometric and impedimetric sensors for TTX based on ionophores and aptamer immobilised on the modified conducting electroactive polyaniline (PANI)/electrode. The undoped polyaniline and poly(4-styrenesulfonic acid) (PSSA) doped electroactive polyanilines were prepared in perchloric acid/acetonitrile and phosphoric acid respectively by electrochemical oxidative polymerisation. Two types of electropolymerisation were applied to prepare the neutral and p-doped PANI−PSSA films composites. The dynamic electroinactivity of TTX was studied which revealed that TTX is not electrochemically active on bare Au, GC, Pt, PG, Ni, Ti and BDD (Boron dopeddiamond) electrodes in acetate buffer pH 4.8. Using ion transfer voltammetry and UV-Vis analysis, the complexation of TTX with two neutral ionophores (sodium ionophore X (NaX) and dibenzo-18-crown6 (B18C6)) was investigated. The cyclic voltammograms (CVs) recorded from ion transfer voltammetry presented no redox peak and no increasing/decreasing current was observed which indicates that no TTX ions transfer from the liquid to the organic phase. In addition, the absorption spectra of the mixture of TTX/NaX and TTX/B18C6 presented the same absorption bands recorded for NaX and B18C6 respectively. Three absorptions bands at 250.4, 278.3, and 370.6 nm for NaX and two at 222.03 and 274.10 nm for B18C6 were observed before and after mixing TTX with NaX and TTX with B18C6 separately. No chemical reaction occurred between the TTX and both ionophores, therefore, sodium ionophore X and dibenzo-18-crown-6 did not form a complex with TTX. Thus, TTX ion sensor cannot be developed based on these two neutral compounds. The electrodynamics of the PANI and PANI−PSSA films electropolymerised on the bare precious metal electrodes were also investigated through various electrochemical techniques. Cyclic voltammetry (CV) and electrochemical impedance spectroscopy (EIS) studies in sodium phosphate (SPB) and acetate (OAc) buffer revealed that both neutral and p-doped films synthesized were thin (thickness L < 5 nm in acetate buffer and L < 10 nm in sodium phosphate buffer) film polymers.

Aptasensor

Tetrodotoxin-aptamer

Tetrodotoxin

Ion transfer voltammetry

Modification électrochimique de l'interface liquide - liquide avec de la silice mésoporeuse / Electrochemical modification of the liquid - liquid interface with mesoporous silica

Poltorak, Lukasz

25 September 2015

Ce travail combine l'électrochimie à l'interface liquide - liquide avec le procédé sol - gel pour la modification interfaciale avec de la silice mésoporeuse. Dans la première partie de ce travail, l’interface liquide – liquide macroscopique a été utilisée pour séparer la solution aqueuse de l'espèce de précurseur de silice hydrolysées (tétraéthoxysilane (TEOS)) de l'agent tensioactif cationique (cethyltrimethylammonium (CTA+) qui a agi comme un template et a été dissous dans le dichloroéthane. Le dépôt de matériau de silice a été déclenchée par le transfert du CTA+ à partir de la phase organique vers la phase aqueuse. CTA+ qui a transféré à la phase aqueuse a catalysé la réaction de condensation de la silice sur l’interface liquide – liquide. Le dépôt de silice à des interfaces liquide – liquide miniaturisées était la deuxième partie de ce travail. Les dépôts stables sur le côté de l'interface ont été synthétisés in situ par voie électrochimique. La stabilité mécanique des dépôts de silice permis un traitement thermique de la silice. Basé sur les techniques d’imagerie (par exemple SEM) il a été constaté que les dépôts forment des hémisphères pour des temps plus long. La réaction interfaciale a également été suivie in situ par spectroscopie Raman confocale. Caractéristiques moléculaires de l'interface ont été modifiées de manière spectaculaire une fois les espèces CTA+ ont été transférés à la phase aqueuse. Les interfaces liquide – liquide miniaturisés et modifiés ont également été évaluée avec le transfert voltampérométrique / This work combines the electrochemistry at the interface between two immiscible electrolyte solutions (ITIES) with the Sol – Gel process of silica leading to an interfacial modification with mesoporous silica using soft template. In the first part of this work the macroscopic liquid – liquid interface was employed to separate the aqueous solution of the hydrolyzed silica precursor species (tetraethoxysilane (TEOS)) from the cationic surfactant (cethyltrimethylammonium (CTA+)) dissolved in the dichloroethane. The silica material deposition was controlled by the electrochemical CTA+ transfer from the organic to the aqueous phase. Template transferred to the aqueous phase catalyzed the condensation reaction and self-assembly resulting in silica deposition at the interface. Silica deposition at the miniaturized ITIES (membranes supporting array of micrometer in diameter pores were used in this regard) was the second part of this work. Silica interfacial synthesis performed in situ resulted in stable deposits growing on the aqueous side of the interface. Mechanical stability of the supported silica deposits allowed further processing – silica material was cured. Based on imaginary techniques (e.g. SEM) it was found that deposits forms hemispheres for longer experimental time scales. Interfacial reaction was also followed with in situ confocal Raman spectroscopy. Molecular characteristics of the interface were changed dramatically once CTA+ species were transferred to the aqueous phase. Array of microITIES modified with silica was also assessed by ion transfer voltammetry

Tetraethoxysilane

Interface liquide – liquide

Ities

Silice mésoporeuse

Procédé Sol – Gel

Cetyltrimethylammonium

Tetraethylammonium

Tetramethylammonium

Tetrabuthylammonium

Voltammétrie cyclique

Spectroscopie Raman confocale

Tamis moléculaire

Modification interfaciale

Dépôt de silice

Voltammétrie de transfert d’ions

4-Octylbenzenesulfonate

Miniaturisation

MicroITIES

Μities

Membrane à base de silicium mésoporeux

Tetraethoxysilane

Liquid – liquid interface

Ities

Mesoporous silica

Sol – Gel process

Soft template

Cetyltrimethylammonium

Worm like structures

Tetraethylammonium

Tetramethylammonium

Tetrabuthylammonium

PAMAM dendrimers

Cyclic voltammetry

Confocal Raman spectroscopy

Molecular sieving

Interfacial modification

Silica deposition

Ion transfer voltammetry

4-Octylbenzenesulfonate

Miniaturization

MicroITIES

Μities

Mesoporous silicon wafers

541.37

660.297