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Restoring Voluntary Control of Locomotion After Paralyzing Spinal Cord Injury

Overview
Journal Science
Specialty Science
Date 2012 Jun 2
PMID 22654062
Citations 326
Authors
Rubia van den Brand
Janine Heutschi
Quentin Barraud
Jack DiGiovanna
Kay Bartholdi
Michele Huerlimann
Lucia Friedli
Isabel Vollenweider
Eduardo Martin Moraud
Simone Duis
Nadia Dominici
Silvestro Micera
Pavel Musienko
Gregoire Courtine
Affiliations
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Abstract

Half of human spinal cord injuries lead to chronic paralysis. Here, we introduce an electrochemical neuroprosthesis and a robotic postural interface designed to encourage supraspinally mediated movements in rats with paralyzing lesions. Despite the interruption of direct supraspinal pathways, the cortex regained the capacity to transform contextual information into task-specific commands to execute refined locomotion. This recovery relied on the extensive remodeling of cortical projections, including the formation of brainstem and intraspinal relays that restored qualitative control over electrochemically enabled lumbosacral circuitries. Automated treadmill-restricted training, which did not engage cortical neurons, failed to promote translesional plasticity and recovery. By encouraging active participation under functional states, our training paradigm triggered a cortex-dependent recovery that may improve function after similar injuries in humans.

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