Abstract
Significant progress has been made on the development of electrolyte-gated graphene field effect transistor (EGGFET) biosensors over the last decade, yet they are still in the stage of proof-of-concept. In this work, we studied the electrolyte matrix effects, including its composition, pH and ionic strength, and demonstrate that variations in electrolyte matrices have a significant impact on the Fermi level of the graphene channel and the sensitivity of the EGGFET biosensors. This is attributed to the polarization-induced interaction between the electrolyte and the graphene at the interface which can lead to considerable modulation of the Fermi level of the graphene channel. As a result, the response of the EGGFET biosensors is susceptible to the matrix effect which might lead to high uncertainty or even false results. Then, an EGGFET immunoassay is presented which aims to allow good regulation of the matrix effect. The multichannel design allows in-situ calibration with negative control, as well as statistical validation of the measurement results. Its performance is demonstrated by the detection of human immunoglobulin G (IgG) from serum. The detection range is estimated to be around 2–50 nM with a coefficient of variation (CV) of less than 20% and the recovery rate for IgG detection is around 85–95%. Compared with traditional immunoassay techniques, the EGGFET immunoassay is label-free and ready to be integrated with microfluidics sensor platforms, suggesting its great prospect for point-of-care applications.
Highlights
Field effect transistor (FET) biosensors are operated by measuring the conductance changes of a channel induced by the binding of target molecules to it
We studied the impact of the variance in electrolyte matrices on electrolyte-gated graphene field effect transistor (EGGFET) biosensors—known as the matrix effect—by varying the composition, ionic strength and pH of the electrolytes
For the regulation of the matrix effect, we present an immunoassay based on the EGGFET immunosensors
Summary
Field effect transistor (FET) biosensors are operated by measuring the conductance changes of a channel induced by the binding of target molecules to it. Significant progress has been made in the development of electrolyte-gated graphene field effect transistor (EGGFET) biosensors over the last decade [2]. EGGFET biosensors have been applied for electrophysiological measurements due to their high spatial resolution and low noise level, such as the detection of electrical activity of electrogenic cells [11,12]. The rapid development of the preparation techniques of graphene contributes to the maturation of EGGFET biosensors and it outperforms SiNW and CNT in performance and mass producibility [17,18]
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