Design and Development of OECT Logic Circuits for Electrical Stimulation Applications

Miloš Kostić; Vladimir Kojić; Savo Ičagić; Peter Andersson Ersman; Mohammad Yusuf Mulla; Jan Strandberg; Lars Herlogsson; Thierry Keller; Matija Štrbac

doi:10.3390/app12083985

Applied Sciences (Apr 2022)

Design and Development of OECT Logic Circuits for Electrical Stimulation Applications

Miloš Kostić,
Vladimir Kojić,
Savo Ičagić,
Peter Andersson Ersman,
Mohammad Yusuf Mulla,
Jan Strandberg,
Lars Herlogsson,
Thierry Keller,
Matija Štrbac

Affiliations

Miloš Kostić: Tecnalia Serbia Ltd., 11000 Belgrade, Serbia
Vladimir Kojić: Soultronic International Ltd., 11000 Belgrade, Serbia
Savo Ičagić: Tecnalia Serbia Ltd., 11000 Belgrade, Serbia
Peter Andersson Ersman: Bio and Organic Electronics Unit, Department of Smart Hardware, Digital Systems Division, RISE Research Institutes of Sweden AB, 60221 Norrköping, Sweden
Mohammad Yusuf Mulla: Bio and Organic Electronics Unit, Department of Smart Hardware, Digital Systems Division, RISE Research Institutes of Sweden AB, 60221 Norrköping, Sweden
Jan Strandberg: Bio and Organic Electronics Unit, Department of Smart Hardware, Digital Systems Division, RISE Research Institutes of Sweden AB, 60221 Norrköping, Sweden
Lars Herlogsson: Bio and Organic Electronics Unit, Department of Smart Hardware, Digital Systems Division, RISE Research Institutes of Sweden AB, 60221 Norrköping, Sweden
Thierry Keller: TECNALIA, Basque Research and Technology Alliance (BRTA), 20009 San Sebastian, Spain
Matija Štrbac: Tecnalia Serbia Ltd., 11000 Belgrade, Serbia

DOI: https://doi.org/10.3390/app12083985
Journal volume & issue: Vol. 12, no. 8
p. 3985

Abstract

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This paper presents the first successful implementation of fully printed electronics for flexible and wearable smart multi-pad stimulation electrodes intended for use in medical, sports and lifestyle applications. The smart multi-pad electrodes with the electronic circuits based on organic electrochemical transistor (OECT)-based electronic circuits comprising the 3–8 decoder for active pad selection and high current throughput transistors for switching were produced by multi-layer screen printing. Devices with different architectures of switching transistors were tested in relevant conditions for electrical stimulation applications. An automated testbed with a configurable stimulation source and an adjustable human model equivalent circuit was developed for this purpose. Three of the proposed architectures successfully routed electrical currents of up to 15 mA at an output voltage of 30 V, while one was reliably performing even at 40 V. The presented results demonstrate feasibility of the concept in a range of conditions relevant to several applications of electrical stimulation.

Published in Applied Sciences

ISSN: 2076-3417 (Online)
Publisher: MDPI AG
Country of publisher: Switzerland
LCC subjects: Technology: Engineering (General). Civil engineering (General); Science: Biology (General); Science: Physics; Science: Chemistry
Website: http://www.mdpi.com/journal/applsci

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