Litcius/Paper detail

Distortion‐Free Sensing of Neural Activity Using Graphene Transistors

Ramon Garcia‐Cortadella, Eduard Masvidal‐Codina, Jose M. De la Cruz, Nathan Schäfer, Gerrit Schwesig, Christoph Jeschke, Javier Martínez-Aguilar, María V. Sánchez-Vives, Rosa Villa, Xavi Illa, Anton Sirota, Anton Guimerà‐Brunet, José A. Garrido

2020Small32 citationsDOIOpen Access PDF

Abstract

Graphene solution-gated field-effect transistors (g-SGFETs) are promising sensing devices to transduce electrochemical potential signals in an electrolyte bath. However, distortion mechanisms in g-SGFET, which can affect signals of large amplitude or high frequency, have not been evaluated. Here, a detailed characterization and modeling of the harmonic distortion and non-ideal frequency response in g-SGFETs is presented. This accurate description of the input-output relation of the g-SGFETs allows to define the voltage- and frequency-dependent transfer functions, which can be used to correct distortions in the transduced signals. The effect of signal distortion and its subsequent calibration are shown for different types of electrophysiological signals, spanning from large amplitude and low frequency cortical spreading depression events to low amplitude and high frequency action potentials. The thorough description of the distortion mechanisms presented in this article demonstrates that g-SGFETs can be used as distortion-free signal transducers not only for neural sensing, but also for a broader range of applications in which g-SGFET sensors are used.

Topics & Concepts

Distortion (music)Total harmonic distortionSIGNAL (programming language)GrapheneTransistorMaterials scienceAmplitude distortionAmplitudeOptoelectronicsVoltagePhysicsBiological systemComputer scienceNonlinear distortionOpticsNanotechnologyQuantum mechanicsCMOSAmplifierProgramming languageBiologyNeuroscience and Neural EngineeringAdvanced Memory and Neural ComputingAnalytical Chemistry and Sensors