A high-frequency artificial nerve based on homogeneously integrated organic electrochemical transistors

Shijie Wang; Yichang Wang; Xinmei Cai; Bingjun Wang; Chao Zhao; Guangjiu Pan; Constantin Harder; Yusuf Bulut; Beichen Zhang; Sen Zhang; Yuxin Kong; Kexin Huang; Bomin Xie; Peter Müller-Buschbaum; Stephan V. Roth; Lin Yang; Yuxiang Li; Yong Han; Gang Bao; Wei Ma

doi:10.1038/s41928-025-01357-7

A high-frequency artificial nerve based on homogeneously integrated organic electrochemical transistors

Shijie Wang
, Yichang Wang
, Xinmei Cai
, Bingjun Wang
, Chao Zhao
, Guangjiu Pan
, Constantin Harder
, Yusuf Bulut
, Beichen Zhang
, Sen Zhang
, Yuxin Kong
, Kexin Huang
, Bomin Xie
, Peter Müller-Buschbaum
, Stephan V. Roth
, Lin Yang
, Yuxiang Li
, Yong Han
, Gang Bao
, Wei Ma

材料科学与工程学院

Xi'an Jiaotong University
The First Affiliated Hospital of Xi’an Jiaotong University
Technical University of Munich
German Electron Synchrotron
Xi'an University of Science and Technology
KTH Royal Institute of Technology
The Second Affiliated Hospital of Xi'an Jiaotong University

科研成果: 期刊稿件 › 文章 › 同行评审

41 引用（Scopus）

摘要

Artificial nerves that are capable of sensing, processing and memory functions at bio-realistic frequencies are of potential use in nerve repair and brain–machine interfaces. n-type organic electrochemical transistors are a possible building block for artificial nerves, as their positive-potential-triggered potentiation behaviour can mimic that of biological cells. However, the devices are limited by weak ionic and electronic transport and storage properties, which leads to poor volatile and non-volatile performance and, in particular, a slow response. We describe a high-frequency artificial nerve based on homogeneously integrated organic electrochemical transistors. We fabricate a vertical n-type organic electrochemical transistor with a gradient-intermixed bicontinuous structure that simultaneously enhances the ionic and electronic transport and the ion storage. The transistor exhibits a volatile response of 27 μs, a 100-kHz non-volatile memory frequency and a long state-retention time. Our integrated artificial nerve, which contains vertical n-type and p-type organic electrochemical transistors, offers sensing, processing and memory functions in the high-frequency domain. We also show that the artificial nerve can be integrated into animal models with compromised neural functions and that it can mimic basic conditioned reflex behaviour.

源语言	英语
文章编号	2868
页（从-至）	254-266
页数	13
期刊	Nature Electronics
卷	8
期	3
DOI	https://doi.org/10.1038/s41928-025-01357-7
出版状态	已出版 - 3月 2025

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Wang, S., Wang, Y., Cai, X., Wang, B., Zhao, C., Pan, G., Harder, C., Bulut, Y., Zhang, B., Zhang, S., Kong, Y., Huang, K., Xie, B., Müller-Buschbaum, P., Roth, S. V., Yang, L., Li, Y., Han, Y., Bao, G., & Ma, W. (2025). A high-frequency artificial nerve based on homogeneously integrated organic electrochemical transistors. Nature Electronics, 8(3), 254-266. 文章 2868. https://doi.org/10.1038/s41928-025-01357-7

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title = "A high-frequency artificial nerve based on homogeneously integrated organic electrochemical transistors",

abstract = "Artificial nerves that are capable of sensing, processing and memory functions at bio-realistic frequencies are of potential use in nerve repair and brain–machine interfaces. n-type organic electrochemical transistors are a possible building block for artificial nerves, as their positive-potential-triggered potentiation behaviour can mimic that of biological cells. However, the devices are limited by weak ionic and electronic transport and storage properties, which leads to poor volatile and non-volatile performance and, in particular, a slow response. We describe a high-frequency artificial nerve based on homogeneously integrated organic electrochemical transistors. We fabricate a vertical n-type organic electrochemical transistor with a gradient-intermixed bicontinuous structure that simultaneously enhances the ionic and electronic transport and the ion storage. The transistor exhibits a volatile response of 27 μs, a 100-kHz non-volatile memory frequency and a long state-retention time. Our integrated artificial nerve, which contains vertical n-type and p-type organic electrochemical transistors, offers sensing, processing and memory functions in the high-frequency domain. We also show that the artificial nerve can be integrated into animal models with compromised neural functions and that it can mimic basic conditioned reflex behaviour.",

author = "Shijie Wang and Yichang Wang and Xinmei Cai and Bingjun Wang and Chao Zhao and Guangjiu Pan and Constantin Harder and Yusuf Bulut and Beichen Zhang and Sen Zhang and Yuxin Kong and Kexin Huang and Bomin Xie and Peter M{\"u}ller-Buschbaum and Roth, \{Stephan V.\} and Lin Yang and Yuxiang Li and Yong Han and Gang Bao and Wei Ma",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive licence to Springer Nature Limited 2025.",

year = "2025",

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doi = "10.1038/s41928-025-01357-7",

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Wang, S, Wang, Y, Cai, X, Wang, B, Zhao, C, Pan, G, Harder, C, Bulut, Y, Zhang, B, Zhang, S, Kong, Y, Huang, K, Xie, B, Müller-Buschbaum, P, Roth, SV, Yang, L, Li, Y, Han, Y, Bao, G & Ma, W 2025, 'A high-frequency artificial nerve based on homogeneously integrated organic electrochemical transistors', Nature Electronics, 卷 8, 号码 3, 2868, 页码 254-266. https://doi.org/10.1038/s41928-025-01357-7

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AU - Wang, Shijie

AU - Wang, Yichang

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AU - Pan, Guangjiu

AU - Harder, Constantin

AU - Bulut, Yusuf

AU - Zhang, Beichen

AU - Zhang, Sen

AU - Kong, Yuxin

AU - Huang, Kexin

AU - Xie, Bomin

AU - Müller-Buschbaum, Peter

AU - Roth, Stephan V.

AU - Yang, Lin

AU - Li, Yuxiang

AU - Han, Yong

AU - Bao, Gang

AU - Ma, Wei

PY - 2025/3

Y1 - 2025/3

N2 - Artificial nerves that are capable of sensing, processing and memory functions at bio-realistic frequencies are of potential use in nerve repair and brain–machine interfaces. n-type organic electrochemical transistors are a possible building block for artificial nerves, as their positive-potential-triggered potentiation behaviour can mimic that of biological cells. However, the devices are limited by weak ionic and electronic transport and storage properties, which leads to poor volatile and non-volatile performance and, in particular, a slow response. We describe a high-frequency artificial nerve based on homogeneously integrated organic electrochemical transistors. We fabricate a vertical n-type organic electrochemical transistor with a gradient-intermixed bicontinuous structure that simultaneously enhances the ionic and electronic transport and the ion storage. The transistor exhibits a volatile response of 27 μs, a 100-kHz non-volatile memory frequency and a long state-retention time. Our integrated artificial nerve, which contains vertical n-type and p-type organic electrochemical transistors, offers sensing, processing and memory functions in the high-frequency domain. We also show that the artificial nerve can be integrated into animal models with compromised neural functions and that it can mimic basic conditioned reflex behaviour.

AB - Artificial nerves that are capable of sensing, processing and memory functions at bio-realistic frequencies are of potential use in nerve repair and brain–machine interfaces. n-type organic electrochemical transistors are a possible building block for artificial nerves, as their positive-potential-triggered potentiation behaviour can mimic that of biological cells. However, the devices are limited by weak ionic and electronic transport and storage properties, which leads to poor volatile and non-volatile performance and, in particular, a slow response. We describe a high-frequency artificial nerve based on homogeneously integrated organic electrochemical transistors. We fabricate a vertical n-type organic electrochemical transistor with a gradient-intermixed bicontinuous structure that simultaneously enhances the ionic and electronic transport and the ion storage. The transistor exhibits a volatile response of 27 μs, a 100-kHz non-volatile memory frequency and a long state-retention time. Our integrated artificial nerve, which contains vertical n-type and p-type organic electrochemical transistors, offers sensing, processing and memory functions in the high-frequency domain. We also show that the artificial nerve can be integrated into animal models with compromised neural functions and that it can mimic basic conditioned reflex behaviour.

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JO - Nature Electronics

JF - Nature Electronics

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A high-frequency artificial nerve based on homogeneously integrated organic electrochemical transistors

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