Understanding the Mechanobiology of Gliosis May Be the Key to Unlocking Sustained Chronic Performance of Bioelectronic Neural Interfaces

In an effort to develop the next generation of neural implants, current research has focused on solving the challenges associated with the foreign body reaction and promoting long‐term device performance in vivo. Although the cutting edge of research in this field appears to be moving away from trad...

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Bibliographic Details
Published in:Advanced NanoBiomed Research (Online) 2022-03, Vol.2 (3), p.n/a
Main Authors: Vallejo-Giraldo, Catalina, Krukiewicz, Katarzyna, Biggs, Manus Jonathan Paul
Format: Article
Language:English
Subjects:
Bioelectricity
biomaterials
Biomedical materials
Brain research
cell sensing
Chronic illnesses
Computer applications
Conflicts of interest
Cutting equipment
Electrodes
extracellular matrix (ECM)
Foreign bodies
Gliosis
Implantation
Implants
Interfaces
Kinases
material design
Mechanical properties
mechanobiology
mechanosensors
Mechanotransduction
Medical equipment
Nervous system
Neural prostheses
Semiconductor materials
Spinal cord
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Summary:In an effort to develop the next generation of neural implants, current research has focused on solving the challenges associated with the foreign body reaction and promoting long‐term device performance in vivo. Although the cutting edge of research in this field appears to be moving away from traditional metallic and semiconductor materials, the complex tissue dynamics which occur at the electrode–neural interface following device implantation are yet to be resolved. In particular, understanding the molecular processes of gliosis and the onset and persistence of scar formation is key in developing stable and specific neural recording/stimulation devices. Critically, it is recognized that neural device implantation leads to a significant disruption of tissue integrity at the peri‐electrode site. Accordingly, an in‐depth understanding of mechanotransduction in neuronal cell populations at the peri‐implant region is required to better inform neural interface design. This perspective highlights the need for a comprehensive mechanobiological understanding of gliosis to enhance the development of neural implants with improved chronic functionality. An in‐depth understanding of mechanotransduction in neuronal cell populations at the peri‐implant region is required to better inform neural interface design. Thus, this perspective highlights “the need” for a comprehensive mechanobiological understanding of gliosis from the role of extracellular matrix (ECM) to the mechanoresponsive ion channels to enhance the development of neural implants with improved chronic functionality.
ISSN:2699-9307
2699-9307
DOI:10.1002/anbr.202100098