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P.122 Unbiased whole brain circuit interrogation reveals neurons restoring walking after spinal cord injury

Published online by Cambridge University Press:  24 June 2022

N Cho
Affiliation:
(Toronto)*
J Squair
Affiliation:
(Lausanne)
N James
Affiliation:
(Lausanne)
L Baud
Affiliation:
(Lausanne)
A Leonhartsberger
Affiliation:
(Lausanne)
K Sveistyte
Affiliation:
(Lausanne)
K Galan
Affiliation:
(Lausanne)
Q Barraud
Affiliation:
(Lausanne)
M Goubran
Affiliation:
(Toronto)
L Batti
Affiliation:
(Geneva)
S Pages
Affiliation:
(Geneva)
M Gautier
Affiliation:
(Lausanne)
T Hutson
Affiliation:
(Lausanne)
C Kathe
Affiliation:
(Lausanne)
A Bichat
Affiliation:
(Lausanne)
O Rizzo
Affiliation:
(Lausanne)
M Hodara
Affiliation:
(Lausanne)
J Bloch
Affiliation:
(Lausanne)
G Courtine
Affiliation:
(Lausanne)
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Abstract

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Background: There is presently no cure for locomotor deficits after spinal cord injury (SCI). Very few therapies effectively target the brain due to poor understanding of the brain’s role post-SCI. Newly developed tissue clearing techniques have permitted unbiased three-dimensional circuit analysis, opening new opportunities for SCI-related brain interrogation. Methods: We established a novel brain interrogation pipeline by optimizing mouse brain clearing, imaging, and atlas registration. We leveraged a spontaneous recovery lateral hemisection model to analyze whole brain cell activity and connectivity with the lumbar cord using cFos immunolabelling and virus-mediated projection tracing. We identified a functionally and anatomically dynamic region correlating with recovery and interrogated its locomotor role with optogenetics. We assessed deep brain electrical stimulation (DBS) of this region in a more clinically relevant rat contusion SCI using an established bipedal robotic interface. Results: We unexpectedly uncovered the lateral hypothalamus (LH) to functionally and anatomically correlate with recovery. LHVglut2 optogenetic stimulation significantly augmented locomotor function. LH DBS in rats acutely robustly augmented bipedal locomotion post-SCI. Conclusions: This is the first demonstration of the LH’s role in locomotion post-SCI and is a novel DBS target that robustly augmented locomotor function, dependent on LH glutamatergic cells. LH DBS may be a promising intervention in humans.

Type
Poster Presentations
Copyright
© The Author(s), 2022. Published by Cambridge University Press on behalf of Canadian Neurological Sciences Federation