High-Density Redox Amplified Coulostatic Discharge-Based Biosensor Array

Overview

Journal IEEE J Solid-State Circuits

Date 2018 Dec 19

PMID 30559530

Citations 6

Authors

Alexander C Sun

Enrique Alvarez-Fontecilla

A G Venkatesh

Eliah Aronoff-Spencer

Drew A Hall

Affiliations

Soon will be listed here.

Abstract

High-density biosensor arrays are essential for many cutting-edge biomedical applications including point-of-care vaccination screening to detect multiple highly-contagious diseases. Typical electrochemical biosensing techniques are based on the measurement of sub-pA currents for micron-sized sensors requiring highly-sensitive readout circuits. Such circuits are often too complex to scale down for high-density arrays. In this paper, a high-density 4,096-pixel electrochemical biosensor array in 180 nm CMOS is presented. It uses a coulostatic discharge sensing technique and interdigitated electrode geometry to reduce both the complexity and size of the readout circuitry. Each biopixel contains an interdigitated microelectrode with a 13 aA low-leakage readout circuit directly underneath. Compared to standard planar electrodes, the implemented interdigitated electrodes achieve a maximum amplification factor of 10.5× from redox cycling. The array's sensor density is comparable to state-of-the-art arrays, all without augmenting the sensors with complex post-processing. The detection of anti-Rubella and anti-Mumps antibodies in human serum is demonstrated.

Citing Articles

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Design and Analysis of a Sample-and-Hold CMOS Electrochemical Sensor for Aptamer-based Therapeutic Drug Monitoring.

Chien J, Baker S, Soh H, Arbabian A IEEE J Solid-State Circuits. 2020; 55(11):2914-2929.

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DNA Biosensor Based on Double-Layer Discharge for the Detection of HPV Type 16.

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