TY - JOUR
T1 - Endocisternal interfaces for minimally invasive neural stimulation and recording of the brain and spinal cord
AU - Chen, Joshua C.
AU - Dhuliyawalla, Abdeali
AU - Garcia, Robert
AU - Robledo, Ariadna
AU - Woods, Joshua E.
AU - Alrashdan, Fatima
AU - O’Leary, Sean
AU - Husain, Adam
AU - Price, Anthony
AU - Crosby, Scott
AU - Felicella, Michelle M.
AU - Wakhloo, Ajay K.
AU - Karas, Patrick
AU - Provenza, Nicole
AU - Goodman, Wayne
AU - Sheth, Sameer A.
AU - Sheth, Sunil A.
AU - Robinson, Jacob T.
AU - Kan, Peter
N1 - Publisher Copyright:
© The Author(s), under exclusive licence to Springer Nature Limited 2024.
PY - 2024
Y1 - 2024
N2 - Minimally invasive neural interfaces can be used to diagnose, manage and treat many disorders, with reduced risks of surgical complications. However, endovascular probes lack access to key cortical, subcortical and spinal targets, and are not typically explantable after endothelialization. Here we report the development and testing, in sheep, of endocisternal neural interfaces that approach brain and spinal cord targets through inner and outer spaces filled with cerebrospinal fluid. Thus, the interfaces gain access to the entire brain convexity, to deep brain structures within the ventricles and to the spinal cord from the spinal subarachnoid space. We combined an endocisternal neural interface with wireless miniature magnetoelectrically powered bioelectronics so that it can be freely navigated percutaneously from the spinal space to the cranial subarachnoid space, and from the cranial subarachnoid space to the ventricles. In sheep, we show recording and stimulation functions, as well as repositioning of the flexible electrodes and explantation of the interface after chronic implantation. Minimally invasive endocisternal bioelectronics may enable chronic and transient therapies, particularly for stroke rehabilitation and epilepsy monitoring.
AB - Minimally invasive neural interfaces can be used to diagnose, manage and treat many disorders, with reduced risks of surgical complications. However, endovascular probes lack access to key cortical, subcortical and spinal targets, and are not typically explantable after endothelialization. Here we report the development and testing, in sheep, of endocisternal neural interfaces that approach brain and spinal cord targets through inner and outer spaces filled with cerebrospinal fluid. Thus, the interfaces gain access to the entire brain convexity, to deep brain structures within the ventricles and to the spinal cord from the spinal subarachnoid space. We combined an endocisternal neural interface with wireless miniature magnetoelectrically powered bioelectronics so that it can be freely navigated percutaneously from the spinal space to the cranial subarachnoid space, and from the cranial subarachnoid space to the ventricles. In sheep, we show recording and stimulation functions, as well as repositioning of the flexible electrodes and explantation of the interface after chronic implantation. Minimally invasive endocisternal bioelectronics may enable chronic and transient therapies, particularly for stroke rehabilitation and epilepsy monitoring.
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U2 - 10.1038/s41551-024-01281-9
DO - 10.1038/s41551-024-01281-9
M3 - Article
AN - SCOPUS:85208966339
SN - 2157-846X
JO - Nature Biomedical Engineering
JF - Nature Biomedical Engineering
ER -