Breaking the barrier to biomolecule limit-of-detection via 3D printed multi-length-scale graphene-coated electrodes

Md Azahar Ali,Rahul Panat,Andrew J Gellman,Mohammad S Saleh,Sanjida Jahan,Bin Yuan,Chunshan Hu,Zhitao Guo

doi:10.1038/s41467-021-27361-x

Md Azahar Ali, Rahul Panat + Show 6 more

Open Access

https://doi.org/10.1038/s41467-021-27361-x

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Journal: Nature Communications	Publication Date: Dec 1, 2021
Citations: 35	License type: open-access

Affiliation: Carnegie Mellon University

Abstract

Sensing of clinically relevant biomolecules such as neurotransmitters at low concentrations can enable an early detection and treatment of a range of diseases. Several nanostructures are being explored by researchers to detect biomolecules at sensitivities beyond the picomolar range. It is recognized, however, that nanostructuring of surfaces alone is not sufficient to enhance sensor sensitivities down to the femtomolar level. In this paper, we break this barrier/limit by introducing a sensing platform that uses a multi-length-scale electrode architecture consisting of 3D printed silver micropillars decorated with graphene nanoflakes and use it to demonstrate the detection of dopamine at a limit-of-detection of 500 attomoles. The graphene provides a high surface area at nanoscale, while micropillar array accelerates the interaction of diffusing analyte molecules with the electrode at low concentrations. The hierarchical electrode architecture introduced in this work opens the possibility of detecting biomolecules at ultralow concentrations.

Highlights

Sensing of clinically relevant biomolecules such as neurotransmitters at low concentrations can enable an early detection and treatment of a range of diseases
As pointed out in the seminal works by Sheehan and Whitman[1] and others[7,14,15,16], the nanostructures are typically grown on two-dimensional (2D) surfaces, making it challenging for relevant analyte molecules to ‘collide’ with them at practically relevant time scales
We first describe the Aerosol Jet (AJ) nanoparticle printing method used to fabricate the multi-length-scale biosensing platform developed in this work

Summary

Introduction

Sensing of clinically relevant biomolecules such as neurotransmitters at low concentrations can enable an early detection and treatment of a range of diseases. This significant enhancement of current with the 3D configured sensor is due to the enhancement in the surface area of the electrode, and to the multi-length scale architecture that leads to spherical diffusion of analyte molecules as shown in the COMSOL simulations.

Results

Conclusion