A Printed Organic Amplification System for Wearable Potentiometric Electrochemical Sensors

Rei Shiwaku; Hiroyuki Matsui; Kuniaki Nagamine; Mayu Uematsu; Taisei Mano; Yuki Maruyama; Ayako Nomura; Kazuhiko Tsuchiya; Kazuma Hayasaka; Yasunori Takeda; Takashi Fukuda; Daisuke Kumaki; Shizuo Tokito

doi:10.1038/s41598-018-22265-1

JOURNAL ARTICLE

A Printed Organic Amplification System for Wearable Potentiometric Electrochemical Sensors

Rei Shiwaku Hiroyuki Matsui Kuniaki Nagamine Mayu Uematsu Taisei Mano Yuki Maruyama Ayako Nomura Kazuhiko Tsuchiya Kazuma Hayasaka Yasunori Takeda Takashi Fukuda Daisuke Kumaki Shizuo Tokito

Year: 2018 Journal: Scientific Reports Vol: 8 (1) Publisher: Nature Portfolio

DOI: 10.1038/s41598-018-22265-1

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Abstract

Abstract Electrochemical sensor systems with integrated amplifier circuits play an important role in measuring physiological signals via in situ human perspiration analysis. Signal processing circuitry based on organic thin-film transistors (OTFTs) have significant potential in realizing wearable sensor devices due to their superior mechanical flexibility and biocompatibility. Here, we demonstrate a novel potentiometric electrochemical sensing system comprised of a potassium ion (K + ) sensor and amplifier circuits employing OTFT-based pseudo-CMOS inverters, which have a highly controllable switching voltage and closed-loop gain. The ion concentration sensitivity of the fabricated K + sensor was 34 mV/dec, which was amplified to 160 mV/dec (by a factor of 4.6) with high linearity. The developed system is expected to help further the realization of ultra-thin and flexible wearable sensor devices for healthcare applications.

Keywords:

Materials science Wearable computer Amplifier Potentiometric titration Electronic circuit Optoelectronics Linearity CMOS Potentiometric sensor Transistor Flexibility (engineering) Operational amplifier Sensitivity (control systems) Voltage Computer science Electrical engineering Electronic engineering Electrode Embedded system Engineering Chemistry

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Advanced Sensor and Energy Harvesting Materials

Physical Sciences → Engineering → Biomedical Engineering

Conducting polymers and applications

Physical Sciences → Materials Science → Polymers and Plastics

Analytical Chemistry and Sensors

Physical Sciences → Chemical Engineering → Bioengineering

A Printed Organic Amplification System for Wearable Potentiometric Electrochemical Sensors

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