Injectable 2D Material‐Based Sensor Array for Minimally Invasive Neural Implants

Injectable 2D Material‐Based Sensor Array for Minimally Invasive Neural Implants

Intracranial implants for diagnosis and treatment of brain diseases have been developed over the past few decades. However, the platform of conventional implantable devices still relies on invasive probes and bulky sensors in conjunction with large‐area craniotomy and provides only limited biometric...

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Veröffentlicht in:Advanced materials (Weinheim) 2024-08, Vol.36 (32), p.e2400261-n/a
Hauptverfasser: Kim, Jejung, Hong, Juyeong, Park, Kyungtai, Lee, Sangwon, Hoang, Anh Tuan, Pak, Sojeong, Zhao, Huilin, Ji, Seunghyeon, Yang, Sungchil, Chung, Chun Kee, Yang, Sunggu, Ahn, Jong‐Hyun
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Sprache:eng
Schlagworte:
2D materials
Contact pressure
Elastic limit
Electric contacts
Graphene
Monitoring
MoS2
Neural prostheses
neural recording
Pressure head
Sensor arrays
Sensors
Stimulation
Surgical mesh
Two dimensional materials
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container_issue 32
container_start_page e2400261
container_title Advanced materials (Weinheim)
container_volume 36
creator Kim, Jejung
Hong, Juyeong
Park, Kyungtai
Lee, Sangwon
Hoang, Anh Tuan
Pak, Sojeong
Zhao, Huilin
Ji, Seunghyeon
Yang, Sungchil
Chung, Chun Kee
Yang, Sunggu
Ahn, Jong‐Hyun
description Intracranial implants for diagnosis and treatment of brain diseases have been developed over the past few decades. However, the platform of conventional implantable devices still relies on invasive probes and bulky sensors in conjunction with large‐area craniotomy and provides only limited biometric information. Here, an implantable multi‐modal sensor array that can be injected through a small hole in the skull and inherently spread out for conformal contact with the cortical surface is reported. The injectable sensor array, composed of graphene multi‐channel electrodes for neural recording and electrical stimulation and MoS2‐based sensors for monitoring intracranial temperature and pressure, is designed based on a mesh structure whose elastic restoring force enables the contracted device to spread out. It is demonstrated that the sensor array injected into a rabbit's head can detect epileptic discharges on the surface of the cortex and mitigate it by electrical stimulation while monitoring both intracranial temperature and pressure. This method provides good potential for implanting a variety of functional devices via minimally invasive surgery. A graphene and MoS2‐based implantable multi‐modal sensor array is developed, presenting a minimally invasive implantation process for neural monitoring apparatus. The sensor array is injected via syringe and air pressure through a small hole in the skull and spreads out to conformally cover the cortical surface. The sensors detect epileptic discharges and monitor intracranial temperature and pressure.
doi_str_mv 10.1002/adma.202400261
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source Wiley Online Library Journals Frontfile Complete
subjects 2D materials
Contact pressure
Elastic limit
Electric contacts
Graphene
Monitoring
MoS2
Neural prostheses
neural recording
Pressure head
Sensor arrays
Sensors
Stimulation
Surgical mesh
Two dimensional materials
title Injectable 2D Material‐Based Sensor Array for Minimally Invasive Neural Implants
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