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Written byTwo pears
SourceLilac Academic
As early as 30 years ago, preclinical and clinical studies showed that epidural electrical stimulation (ESS) on the lumbosacral spinal cord restored the ability
to walk in patients with spinal cord injury.
But this requires the assistance of several physical therapists, months of intense training, and extremely limited success
.
Translating these complex, rare cases into a universally applicable treatment is a huge challenge
.
Dr.
Grégoire Courtine of the Swiss Federal Institute of Technology in Lausanne and Jocelyne Bloch, a neurosurgeon at the University Hospital of Lausanne, have developed a targeted neurotechnology that uses electrical stimulation to reactivate spinal cord neurons, allowing multiple chronic paraplegics to regain the ability to
walk.
However, the biological mechanism behind this treatment technology remains unclear
.
On November 9, 2022, the team of Grégoire Courtine et al.
at the Ecole Polytechnique Fédérale de Lausanne published a research paper in Nature entitled: The neurons that restore walking after paralysis.
The study helped nine patients with severe or complete paralysis due to spinal cord injury successfully regain the ability to walk through the use of epidural electrical stimulation (EES) and identified the types
of neurons that play a key role in the spinal nerve remodeling process.
This study advances our understanding of how to regain mobility after paralysis and marks a fundamental clinical breakthrough
.
In the clinical trial, the research team recruited nine participants
who were severely or completely paralyzed due to spinal cord injury.
Participants received five months of epidural electrical stimulation (EES) treatment
.
Over time, participants' ability to bear weight, stand, and walk improved
dramatically.
Video: Patients with spinal cord injuries undergoing EES rehabilitation regain the ability to walk
Continued recovery of walking ability suggests that EES rehabilitation has reshaped the patient's spinal cord
.
The authors speculate that this remodeling would be reflected in the activity
of neurons involved in the walking process.
The spinal cord is made up of
many different cell types that are highly interconnected.
To explore cell types that might be involved in EES therapy-mediated recovery, the research team developed a mouse model that replicates many key features of the human EES therapy-mediated neurorehabilitation process.
The authors obtained high-resolution single-cell maps of gene expression at several stages of rehabilitation by snRNA-seq sequencing and spatial transcriptomics from 61 spinal cord section single cells to capture detailed changes
in gene expression that occur during EES therapy-mediated recovery from paralysis.
The spatial location
of key neuronal subsets was then validated using multiplex RNAscope.
EES rehabilitation reshapes the spinal cord in humans and mice
By combining the above model with the molecular map, the authors identified a class of excitatory neurons activated by EES, SCVsx2::Hoxa10, which are one of the
specific subpopulations of vertebrate brainstem and spinal cord V2a neurons.
These neurons are important for restoring the ability to walk after spinal cord injury, but are not necessary
for individuals without spinal cord injury.
SCVsx2::Hoxa10 converts incoming information from the motor region of the brainstem into executive commands and delivers it to ventral neurons
responsible for the ability to walk.
Silencing these neurons impairs electrical stimulation-mediated walking recovery after spinal cord injury, while activating this group of neurons even in the absence of EES treatment improves walking
in paralyzed patients.
to resume walking after paralysis Data show that in addition to V2a neurons, there are many other types of cells that respond to EES therapy, including many suppressor neurons (such as ventral inhibitory neurons V1 and V2b).
。 The study also found that EES treatment was associated with an overall decline in spinal cord nerve activity, suggesting that neurosuppression is a key part of
motor recovery.
Spinal cord injuries usually damage some of the nerve pathways from the brain to the spinal cord
.
If electrical stimulation therapy alters the signals that V2A neurons receive from the brain, then identifying and regulating these descending pathways may provide another effective therapeutic pathway
.
This finding could help further understand the mechanisms
behind electrical stimulation that allows paralyzed patients to regain their ability to walk.
In a news opinion article published by Nature at the same time, it was stated that improved treatment of spinal cord injuries requires both the development of technology and a deep understanding
of the biology of rehabilitation.
The high-resolution molecular mapping and sequencing methods of the nervous system provided in this study will serve as a useful resource to guide future research on the basic circuits of exercise recovery, making the treatment prospects of spinal cord injury brighter
.
At the same time, the authors also point out that other neurons in the brain and spinal cord can also promote the recovery of walking ability, so further research
is needed.
Expect this treatment to improve the lives of thousands of paralyzed people around the world!
The treatment in the thesis, carried out in collaboration with the Ecole Polytechnique Fédérale de Lausanne, the University Hospital de Lausanne and Onward Medical, was founded in 2014 to develop a tool for the recovery of spinal cord injury patients with sports, Independence and healthy therapy
.
The company has three therapeutic devices that have been awarded breakthrough device designation by the FDA and are conducting clinical trials
in the United States, Canada, Europe and other places.
The paper's corresponding authors, Grégoire Courtine and Jocelyne Bloch, are co-founders
of the company.
The company was listed
on Euronext Amsterdam in the Netherlands in October 2021.
Link to Grégoire Courtine (right) and Jocelyne Bloch (left):
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