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Topic Name: UCLA study finds that the central nervous system can reorganize itself to restore the cellular communication
Category: Biomedical
Research persons: Dr. Michael Sofroniew
Location: University of California, Los Angeles, United States
Details
Spinal cord damage blocks the routes that the brain uses to send messages to
the nerve cells that control walking. Until now, doctors believed that the only
way for injured patients to walk again was to re-grow the long nerve highways
that link the brain
and base of the spinal cord. For the first time, a UCLA
study shows that the
central nervous system can reorganize itself and follow new pathways to restore
the cellular communication required for movement.
Published in the January edition of Nature Medicine, the discovery could lead
to new therapies for the estimated 250,000 Americans who suffer from traumatic
spinal cord injuries. An additional 10,000 cases occur each year, according to
the Christopher
and Dana Reeve Foundation, which helped fund the UCLA study.
“Imagine the long nerve fibers that run between the cells in the brain and
lower spinal cord as major freeways,” explained Dr. Michael Sofroniew, lead
author and professor of neurobiology at the David Geffen School of Medicine at
UCLA. “When there’s a traffic accident on the freeway, what do drivers do?
They take shorter surface streets. These detours aren’t as fast or direct, but
still allow drivers to reach their destination.
“We saw something similar in our research,” he added. “When spinal cord
damage blocked direct signals from the brain, under certain conditions the
messages were able to make detours around the injury. The message would follow a
series of shorter connections to deliver the brain’s command to move the
legs.”
Using a mouse model, Sofroniew and his colleagues blocked half of the long
nerve fibers in different places and at different times on each side of the
spinal cord. They left untouched the spinal cord’s center, which contains a
connected series of shorter nerve pathways. The latter convey information over
short distances up and down the spinal cord.
What they discovered surprised them.
“We were excited to see that most of the mice regained the ability to
control their legs within eight weeks,” said Sofroniew. “They walked more
slowly and less confidently than before their injury, but still recovered
mobility.”
When the researchers blocked the short nerve pathways in the center of the
spinal cord, the regained function disappeared, returning the animals’
paralysis. This step confirmed that the nervous system had rerouted messages
from the brain to the spinal cord via the shorter pathways, and that these nerve
cells were critical to the animal’s recovery.
“When I was a medical student, my professors taught that the brain and
spinal cord were hard-wired at birth and could not adapt to damage. Severe
injury to the spinal cord meant permanent paralysis,” said Sofroniew.
“This pessimistic view has changed over my lifetime, and our findings add
to a growing body of research showing that the nervous system can reorganize
after injury,” he added. “What we demonstrate here is that the body can use
alternate nerve pathways to deliver instructions that control walking.”
The UCLA team’s next step will be to learn how to entice nerve cells in the
spinal cord to grow and form new pathways that connect across or around the
injury site, enabling the brain to direct these cells. If the researchers
succeed, the findings could lead to the development of new strategies for
restoring mobility following spinal cord injury.
“Our study has identified cells that we can target to try to restore
communication between the brain and spinal cord,” explained Sofroniew. “If
we can use existing nerve connections instead of attempting to rebuild the
nervous system the way it existed before injury, our job of repairing spinal
cord damage will become much easier.”
Spinal cord injury involves damage to the nerves enclosed within the spinal
canal; most injuries result from trauma to the vertebral column. This affects
the brain’s ability to send and receive messages below the injury site to the
systems that control breathing, movement and digestion. Patients generally
experience greater paralysis when injury strikes higher in the spinal column.
The UCLA study was supported by grants from the National
Institute of Neurological Disease and Stroke, the Adelson Medical
Foundation, the Roman
Reed Spinal Cord Injury Research Fund of California and the Christopher and
Dana Reeve Foundation.
Sofroniew’s coauthors included Gregoire Courtine, Dr. Bingbing Song, Roland
Roy, Hui Zhong, Julia Herrmann, Dr. Yan Ao, Jingwei Qi and Reggie Edgerton, all
of UCLA.
Note for Spinal cord
The spinal cord is a thin, tubular bundle of nerves that is an extension of the central nervous system from the brain and is enclosed in and protected by the bony vertebral column. The main function of the spinal cord is transmission of neural inputs between the periphery and the brain.
The human spinal cord extends from the medulla oblongata in the brain and continues to the conus medullaris near the lumbar level at L1-2, terminating in a fibrous extension known as the filum
terminale.
It is about 45 cm long in men and 42 cm long in women, ovoid-shaped, and is enlarged in the cervical and lumbar regions. The peripheral regions of the cord contains neuronal white matter tracts containing sensory and motor neurons. The central region is a four-leaf clover shape that surrounds the central canal (an anatomic extension of the fourth ventricle) and contains nerve cell bodies.
Note for Central nervous system
The central nervous system (CNS) represents the largest part of the nervous system, including the brain and the spinal cord. Together with the peripheral nervous system, it has a fundamental role in the control of behavior. The CNS is contained within the dorsal cavity, with the brain within the cranial cavity, and the spinal cord in the spinal cavity. The CNS is covered by the meninges. The brain is also protected by the skull, and the spinal cord is also protected by the vertebrae.
Since the strong theoretical influence of cybernetics in the fifties, the CNS is conceived as a system devoted to information processing, where an appropriate motor output is computed as a response to a sensory input. Yet, many threads of research suggest that motor activity exists well before the maturation of the sensory systems and then, that the senses only influence behavior without dictating it. This has brought the conception of the CNS as an autonomous system.
 
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