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Complementary integration of organic electrochemical transistors for front-end amplifier circuits of flexible neural implants.


ABSTRACT: The ability to amplify, translate, and process small ionic potential fluctuations of neural processes directly at the recording site is essential to improve the performance of neural implants. Organic front-end analog electronics are ideal for this application, allowing for minimally invasive amplifiers owing to their tissue-like mechanical properties. Here, we demonstrate fully organic complementary circuits by pairing depletion- and enhancement-mode p- and n-type organic electrochemical transistors (OECTs). With precise geometry tuning and a vertical device architecture, we achieve overlapping output characteristics and integrate them into amplifiers with single neuronal dimensions (20 micrometers). Amplifiers with combined p- and n-OECTs result in voltage-to-voltage amplification with a gain of >30 decibels. We also leverage depletion and enhancement-mode p-OECTs with matching characteristics to demonstrate a differential recording capability with high common mode rejection rate (>60 decibels). Integrating OECT-based front-end amplifiers into a flexible shank form factor enables single-neuron recording in the mouse cortex with on-site filtering and amplification.

SUBMITTER: Uguz I 

PROVIDER: S-EPMC10959418 | biostudies-literature | 2024 Mar

REPOSITORIES: biostudies-literature

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Complementary integration of organic electrochemical transistors for front-end amplifier circuits of flexible neural implants.

Uguz Ilke I   Ohayon David D   Yilmaz Sinan S   Griggs Sophie S   Sheelamanthula Rajendar R   Fabbri Jason D JD   McCulloch Iain I   Inal Sahika S   Shepard Kenneth L KL  

Science advances 20240322 12


The ability to amplify, translate, and process small ionic potential fluctuations of neural processes directly at the recording site is essential to improve the performance of neural implants. Organic front-end analog electronics are ideal for this application, allowing for minimally invasive amplifiers owing to their tissue-like mechanical properties. Here, we demonstrate fully organic complementary circuits by pairing depletion- and enhancement-mode p- and n-type organic electrochemical transi  ...[more]

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