Challenges and Opportunities of Implantable Neural Interfaces: From Material, Electrochemical and Biological Perspectives

The desirable implantable neural interfaces can accurately record bioelectrical signals from neurons and regulate neural activities with high spatial/time resolution, facilitating the understanding of neuronal functions and dynamics. However, the electrochemical performance (impedance, charge storag...

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Bibliographic Details
Published in:Advanced functional materials 2023-08, Vol.33 (32), p.n/a
Main Authors: Zeng, Qi, Huang, Zhaoling
Format: Article
Language:English
Subjects:
Bioelectricity
bioelectronics
Conducting polymers
Design optimization
durability
electrochemical
Electrochemical analysis
Electrochemistry
Electrodes
Hydrogels
implantable neural interfaces
Inflammatory response
Materials science
Nanomaterials
neural microelectrodes
Soft tissues
Two dimensional materials
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Summary:The desirable implantable neural interfaces can accurately record bioelectrical signals from neurons and regulate neural activities with high spatial/time resolution, facilitating the understanding of neuronal functions and dynamics. However, the electrochemical performance (impedance, charge storage/injection capacity) is limited with the miniaturization and integration of neural electrodes. The “crosstalk” caused by the uneven distribution of elctric field leads to lower electrical stimulation/recording efficiency. The mismatch between stiff electrodes and soft tissues exacerbates the inflammatory responses, thus weakening the transmission of signals. Though remarkable breakthroughs have been made through the incorporation of optimizing electrode design and functionalized nanomaterials, the chronic stability, and long‐term activity in vivo of the neural electrodes still need further development. In this review, the neural interface challenges mainly on electrochemistry and biology are discussed, followed by summarizing typical electrode optimization technologies and exploring recent advances in the application of nanomaterials, based on traditional metallic materials, emerging 2D materials, conducting polymer hydrogels, etc., for enhancing neural interfaces. The strategies for improving the durability including enhanced adhesion and minimized inflammatory response, are also summarized. The promising directions are finally presented to provide enlightenment for high‐performance neural interfaces in future, which will promote profound progress in neuroscience research. The desirable implantable neural interfaces can accurately record bioelectrical signals from neurons and regulate neural activities with high spatial/time resolution and desirable biosafety. From material, electrochemical and biological perspectives, this review highlights the challenges, typical electrode optimization technologies, material modification, and improving durability strategies for improving neural interfaces. The promising directions are finally presented to provide enlightenment for high‐performance neural interfaces.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.202301223