Litcius/Paper detail

Graphene-Based Electrolyte-Gated Field-Effect Transistors for Potentiometrically Sensing Neuropeptide Y in Physiologically Relevant Environments

Ahmad E. Islam, Rhett L. Martineau, Cameron Crasto, Hyunil Kim, Rahul Rao, Benji Maruyama, Steve Kim, Lawrence F. Drummy

2020ACS Applied Nano Materials31 citationsDOI

Abstract

Wearable electronics with real-time biosensing capabilities are very important for future applications in monitoring and augmenting human health and performance. Graphene-based potentiometric sensing offers a route for developing wearable sensors that can selectively sense biomarkers in biofluids such as sweat and saliva. This manuscript studies the sensitivity of potentiometric sensors made with graphene-based electrolyte-gated field-effect transistors (GFETs). Selectivity in the sensor toward a nanoscale biomarker, neuropeptide Y (NPY), was achieved by functionalizing graphene with a peptide-based biorecognition element. The sensors were then characterized extensively by varying concentrations of NPY in a complex medium containing artificial sweat with varying ionic concentrations and pH. This medium, therefore, emulated the response of the sensor to biomarkers in a physiologically relevant condition approaching a real-world scenario. Analysis using Gouy–Chapman–Stern theory for the liquid–solid interface at nanoscale highlighted important features of potentiometric sensing such as log-linear response and charge screening effects in GFET sensors.

Topics & Concepts

Potentiometric titrationGrapheneBiosensorNanotechnologyMaterials sciencePotentiometric sensorElectrolyteWearable computerNanoscopic scaleChemistryComputer scienceElectrodeEmbedded systemPhysical chemistryAnalytical Chemistry and SensorsElectrochemical sensors and biosensorsAdvanced Sensor and Energy Harvesting Materials