Erika Scavetta scite author profile

An all PEDOT:PSS Organic Electrochemical Transistor (OECT) has been developed and used for the selective detection of dopamine (DA) in the presence of interfering compounds (ascorbic acid, AA and uric acid, UA). The selective response has been implemented using a potentiodynamic approach, by varying the operating gate voltage and the scan rate. The trans-conductance curves allow to obtain a linear calibration plot for AA, UA and DA and to separate the redox waves associated to each compound; for this purpose, the scan rate is an important parameter to achieve a good resolution. The sensitivities and limits of detection obtained with the OECT have been compared with those obtained by potential step amperometric techniques (cyclic voltammetry and differential pulse voltammetry), employing a PEDOT:PSS working electrode: our results prove that the all-PEDOT:PSS OECT sensitivities and limits of detection are comparable or even better than those obtained by DPV, a technique that employs a sophisticate potential wave and read-out system in order to maximize the performance of electrochemical sensors and that can hardly be considered a viable readout method in practical applications.

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Self-assembled gold nanoparticles modified ITO electrodes: The monolayer binder molecule effect

Ballarin

Cassani

Scavetta

et al. 2008

Electrochimica Acta

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A simple all-PEDOT:PSS electrochemical transistor for ascorbic acid sensing

et al. 2015

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An ascorbic acid (AA) sensor was developed by employing an organic electrochemical transistor (OECT) based only on PEDOT:PSS as conductive material. The device was prepared by spin coating using the CLEVIOS TM PH 1000 suspension (PEDOT:PSS) masking the gate and the channel areas with tape. The device was electrically characterized while the doping level of the PEDOT:PSS in the channel was controlled using both the gate electrode and the potentiostat. It was demonstrated that the current that flows in channel (Id) is controlled by the concentration of oxidized sites in the examined potential range. AA reacts with the conductive polymer leading to the extraction of charge carriers from the channel, and thus resulting in a decrease of the absolute value of Id. It was observed that Id linearly depends on the logarithm of AA concentration between 10 -6 and 10 -3 M. The OECT response to AA was studied by varying the gate voltage or the PEDOT:PSS thickness. The performance of the device for optimized conditions shows a limit of detection equal to 10 -8 M and a sensitivity of 4.5 ± 0.1 10 -6 A decade -1 . Symbol AA = Ascorbic Acid SCE = saturated calomel electrode I d = drain current that flows in the channel between source and drain collector I g = gate current that flows is measured between source and gate collector V g = potential applied to the gate electrode V d = potential applied to the drain collector E s = electrochemical potential of the source measured/applied vs SCE E g = electrochemical potential of the gate measured/applied vs SCE E d = electrochemical potential of the drain measured/applied vs SCE Among the materials employed as electrode modifiers, conducting polymers are widely used 19 . Electrochemical sensors offer many advantages with respect to the other

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Stretchable Low Impedance Electrodes for Bioelectronic Recording from Small Peripheral Nerves

Decataldo

Cramer

Martelli

et al. 2019

Sci Rep

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Monitoring of bioelectric signals in peripheral sympathetic nerves of small animal models is crucial to gain understanding of how the autonomic nervous system controls specific body functions related to disease states. Advances in minimally-invasive electrodes for such recordings in chronic conditions rely on electrode materials that show low-impedance ionic/electronic interfaces and elastic mechanical properties compliant with the soft and fragile nerve strands. Here we report a highly stretchable low-impedance electrode realized by microcracked gold films as metallic conductors covered with stretchable conducting polymer composite to facilitate ion-to-electron exchange. The conducting polymer composite based on poly(3,4-ethylenedioxythiophene) polystyrene sulfonate (PEDOT:PSS) obtains its adhesive, low-impedance properties by controlling thickness, plasticizer content and deposition conditions. Atomic Force Microscopy measurements under strain show that the optimized conducting polymer coating is compliant with the micro-crack mechanics of the underlying Au-layer, necessary to absorb the tensile deformation when the electrodes are stretched. We demonstrate functionality of the stretchable electrodes by performing high quality recordings of renal sympathetic nerve activity under chronic conditions in rats.

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Erika Scavetta

Physical and Electrochemical Properties of PEDOT:PSS as a Tool for Controlling Cell Growth

Selective detection of dopamine with an all PEDOT:PSS Organic Electrochemical Transistor

Self-assembled gold nanoparticles modified ITO electrodes: The monolayer binder molecule effect

A simple all-PEDOT:PSS electrochemical transistor for ascorbic acid sensing

Stretchable Low Impedance Electrodes for Bioelectronic Recording from Small Peripheral Nerves

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