Hybrid fabrication of multimodal intracranial implants for electrophysiology and local drug delivery

Johannes Gurke; Tobias E. Naegele; Sam Hilton; Roberto Pezone; Vincenzo F. Curto; Damiano G. Barone; Emil J.W. List-Kratochvil; Alejandro Carnicer-Lombarte; George G. Malliaras

doi:10.1039/d1mh01855h

Hybrid fabrication of multimodal intracranial implants for electrophysiology and local drug delivery

Johannes Gurke, Tobias E. Naegele, Sam Hilton, Roberto Pezone, Vincenzo F. Curto, Damiano G. Barone, Emil J.W. List-Kratochvil, Alejandro Carnicer-Lombarte, George G. Malliaras

Houston Methodist

Research output: Contribution to journal › Article › peer-review

17 Scopus citations

Abstract

New fabrication approaches for mechanically flexible implants hold the key to advancing the applications of neuroengineering in fundamental neuroscience and clinic. By combining the high precision of thin film microfabrication with the versatility of additive manufacturing, we demonstrate a straight-forward approach for the prototyping of intracranial implants with electrode arrays and microfluidic channels. We show that the implant can modulate neuronal activity in the hippocampus through localized drug delivery, while simultaneously recording brain activity by its electrodes. Moreover, good implant stability and minimal tissue response are seen one-week post-implantation. Our work shows the potential of hybrid fabrication combining different manufacturing techniques in neurotechnology and paves the way for a new approach to the development of multimodal implants.

Original language	English (US)
Pages (from-to)	1727-1734
Number of pages	8
Journal	Materials Horizons
Volume	9
Issue number	6
DOIs	https://doi.org/10.1039/d1mh01855h
State	Published - Apr 21 2022

ASJC Scopus subject areas

General Materials Science
Mechanics of Materials
Process Chemistry and Technology
Electrical and Electronic Engineering

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Cite this

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title = "Hybrid fabrication of multimodal intracranial implants for electrophysiology and local drug delivery",

abstract = "New fabrication approaches for mechanically flexible implants hold the key to advancing the applications of neuroengineering in fundamental neuroscience and clinic. By combining the high precision of thin film microfabrication with the versatility of additive manufacturing, we demonstrate a straight-forward approach for the prototyping of intracranial implants with electrode arrays and microfluidic channels. We show that the implant can modulate neuronal activity in the hippocampus through localized drug delivery, while simultaneously recording brain activity by its electrodes. Moreover, good implant stability and minimal tissue response are seen one-week post-implantation. Our work shows the potential of hybrid fabrication combining different manufacturing techniques in neurotechnology and paves the way for a new approach to the development of multimodal implants.",

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AU - Gurke, Johannes

AU - Naegele, Tobias E.

AU - Hilton, Sam

AU - Pezone, Roberto

AU - Curto, Vincenzo F.

AU - Barone, Damiano G.

AU - List-Kratochvil, Emil J.W.

AU - Carnicer-Lombarte, Alejandro

AU - Malliaras, George G.

PY - 2022/4/21

Y1 - 2022/4/21

N2 - New fabrication approaches for mechanically flexible implants hold the key to advancing the applications of neuroengineering in fundamental neuroscience and clinic. By combining the high precision of thin film microfabrication with the versatility of additive manufacturing, we demonstrate a straight-forward approach for the prototyping of intracranial implants with electrode arrays and microfluidic channels. We show that the implant can modulate neuronal activity in the hippocampus through localized drug delivery, while simultaneously recording brain activity by its electrodes. Moreover, good implant stability and minimal tissue response are seen one-week post-implantation. Our work shows the potential of hybrid fabrication combining different manufacturing techniques in neurotechnology and paves the way for a new approach to the development of multimodal implants.

AB - New fabrication approaches for mechanically flexible implants hold the key to advancing the applications of neuroengineering in fundamental neuroscience and clinic. By combining the high precision of thin film microfabrication with the versatility of additive manufacturing, we demonstrate a straight-forward approach for the prototyping of intracranial implants with electrode arrays and microfluidic channels. We show that the implant can modulate neuronal activity in the hippocampus through localized drug delivery, while simultaneously recording brain activity by its electrodes. Moreover, good implant stability and minimal tissue response are seen one-week post-implantation. Our work shows the potential of hybrid fabrication combining different manufacturing techniques in neurotechnology and paves the way for a new approach to the development of multimodal implants.

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Hybrid fabrication of multimodal intracranial implants for electrophysiology and local drug delivery

Abstract

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