Nerve Fibers Coaxed to Regrow After Spinal Cord Injury
Posted: Wed Sep 06, 2006 3:56 am
I posted this on the UK site while UBPN.org was down. This is a current write up on some great science that is very promising...
Chris
--snippet----
The study, whose findings were published in the July 18 issue of the Proceedings of the National Academy of Sciences, has implications for treating people who may face amputation of an arm after a violent injury in which nerves are wrenched from the spinal cord. The new treatment currently is under study for other types of traumatic spinal cord injury.
------------
-between this study and this one >> http://www.youtube.com/watch?v=tHzdePQHyVQ (amazing video of paralyzed rats regaining mobility), Johns Hopkins University is kicking butt!!!
read on!!!
http://www.jhu.edu/gazette/2006/05sep06/05nerves.html
The newspaper of The Johns Hopkins University September 5, 2006 | Vol. 36 No. 1
Nerve Fibers Coaxed to Regrow After Spinal Cord Injury
By Audrey Huang
Johns Hopkins Medicine
In tests on rats, researchers at Johns Hopkins and the University of Michigan have developed a treatment that helps spinal cord nerves regrow after injury.
The study, whose findings were published in the July 18 issue of the Proceedings of the National Academy of Sciences, has implications for treating people who may face amputation of an arm after a violent injury in which nerves are wrenched from the spinal cord. The new treatment currently is under study for other types of traumatic spinal cord injury.
The researchers treated experimental nerve injuries in rats with an enzyme called sialidase that they isolated from bacteria. Four weeks later, more than twice as many nerves in the spinal cords of sialidase-treated rats grew new nerve fibers compared to untreated rats.
The experimental injury in rats mimicked an injury in humans that may occur during childbirth or in a motorcycle accident when an arm is pulled violently away from the body. This injury causes nerves to be yanked out of the spinal cord. Without these nerves, the arm loses feeling and muscle tone. Without muscle tone, the body cannot support the weight of the arm, and many health problems can develop.
While surgeons can sometimes reattach the nerves to the spinal cord, this treatment is not as effective as physicians or patients would like, in part because nerves in the brain and spinal cord, unlike those in the rest of the body, fail to grow new nerve fibers. Nerves in the brain and spinal cord are surrounded by signals from other cells in the injured area that stop them from growing.
"Molecules in the environment of the injured spinal cord are specifically instructing the nerve end not to regrow," said the study's director, Ronald Schnaar, professor of pharmacology and neuroscience in the Institute of Basic Biomedical Sciences at Johns Hopkins.
"The brain and spinal cord are extremely crowded with nerves and nerve fibers, which may be why we have developed careful controls that tell cells to stop making new connections," he said. "The crowded central nervous system has ways to say 'OK, we're done' to keep nerves from sprouting willy-nilly and making inappropriate connections. But in gaining the ability to crowd nerves close together, we have given up flexibility — the ability to heal after injury.
"If you sever your finger, it can be surgically reattached, and nerve fibers typically grow back so that you can use your finger again," Schnaar said. "In contrast, the injured brain and spinal cord are rocky terrain for nerve fiber growth. Finding ways to smooth that road might help the nerve fibers to regrow."
Several molecules in the spinal cord are known to stop nerve fibers from growing. Schnaar refers to these molecules as axon regeneration inhibitors, or simply ARIs.
"Treatments that eliminate ARIs might allow the nerve ends to regain their natural regenerative abilities as they do in the periphery and improve recovery," Schnaar said.
The researchers looked at the boundary between the spinal cord and the periphery to see if they could coax a nerve end to grow out of the inhibitory spinal cord into a more permissive environment that contains fewer ARIs. They chose to mimic the injury commonly seen in motorcycle accidents, called brachial plexus avulsion, because it involves nerves at the boundary between the spinal cord and periphery.
In anesthetized rats, the researchers surgically severed nerves that normally extend from the spinal cord to the shoulder. They then transplanted a nerve from the hind leg of the same animal into the spinal cord to reconnect the injured nerve ends.
To coax the injured nerve ends to grow fibers and connect to the transplanted nerve, they implanted a pump to bathe the area with one of three enzymes known to destroy ARIs. Four weeks after transplantation and enzyme treatment, the researchers injected dyes into the nerves to see whether and how many nerve fibers had grown from the injured cells of the spinal cord into the transplanted nerve.
Rats treated with sialidase, one of the three enzymes tested, showed well over twice the number of new nerve fibers than rats treated with saline, which is not expected to enhance nerve growth. Moreover, the researchers saw that the new fibers were made by nerve cells residing in the spinal cord.
"We have established that the enzyme sialidase, which destroys one of the molecules that inhibits nerve regeneration, is sufficient to robustly improve nerve fiber outgrowth from the spinal cord," Schnaar said.
Surgical transplantation of a peripheral nerve to help nerve fiber growth from the spinal cord has shown limited success in humans. Lynda Yang, the study's lead author and an assistant professor of neurosurgery at the University of Michigan, said, "The addition of a new treatment to enhance our current surgical management of brachial plexus avulsion in people would be welcomed by patients and surgeons alike." Yang helped pioneer the study of ARIs in the 1990s while a doctoral student with Schnaar at Johns Hopkins.
Having shown in this study that sialidase can increase the number of spinal cord nerve cells that extend fibers into a transplanted nerve, Yang now is testing to see if the nerves re-establish muscle control. "We're very interested in seeing how much function you can get back," she said.
According to Schnaar, there is some evidence that this transplant technique coupled with sialidase treatment can coax other, nearby nerve cells within the spinal cord to grow out as well. "Once you rewire, then the brain does an amazing job of sorting it all out," he said.
Having established the ability of sialidase to improve spinal nerve regeneration into transplanted peripheral nerves, Schnaar and his research team at Johns Hopkins are testing the same treatment to see whether it will help nerve regeneration in other types of spinal cord injuries.
"Even a small improvement might mean a lot," Schnaar said. "People with spinal cord injuries generally are not looking to play football but to regain basic functions. A modest improvement in nerve regeneration might make a big improvement in a patient's quality of life."
The researchers were funded by two branches of the National Institutes of Health: the National Institute of Neurological Disorders and Stroke and the National Heart, Lung and Blood Institute; and by the Department of Neurosurgery at the University of Michigan.
In addition to Yang and Schnaar, authors on the paper are Ileana Lorenzini, Katarina Vajn, Andrea Mountney and Lawrence Schramm, all of Johns Hopkins.
Chris
--snippet----
The study, whose findings were published in the July 18 issue of the Proceedings of the National Academy of Sciences, has implications for treating people who may face amputation of an arm after a violent injury in which nerves are wrenched from the spinal cord. The new treatment currently is under study for other types of traumatic spinal cord injury.
------------
-between this study and this one >> http://www.youtube.com/watch?v=tHzdePQHyVQ (amazing video of paralyzed rats regaining mobility), Johns Hopkins University is kicking butt!!!
read on!!!
http://www.jhu.edu/gazette/2006/05sep06/05nerves.html
The newspaper of The Johns Hopkins University September 5, 2006 | Vol. 36 No. 1
Nerve Fibers Coaxed to Regrow After Spinal Cord Injury
By Audrey Huang
Johns Hopkins Medicine
In tests on rats, researchers at Johns Hopkins and the University of Michigan have developed a treatment that helps spinal cord nerves regrow after injury.
The study, whose findings were published in the July 18 issue of the Proceedings of the National Academy of Sciences, has implications for treating people who may face amputation of an arm after a violent injury in which nerves are wrenched from the spinal cord. The new treatment currently is under study for other types of traumatic spinal cord injury.
The researchers treated experimental nerve injuries in rats with an enzyme called sialidase that they isolated from bacteria. Four weeks later, more than twice as many nerves in the spinal cords of sialidase-treated rats grew new nerve fibers compared to untreated rats.
The experimental injury in rats mimicked an injury in humans that may occur during childbirth or in a motorcycle accident when an arm is pulled violently away from the body. This injury causes nerves to be yanked out of the spinal cord. Without these nerves, the arm loses feeling and muscle tone. Without muscle tone, the body cannot support the weight of the arm, and many health problems can develop.
While surgeons can sometimes reattach the nerves to the spinal cord, this treatment is not as effective as physicians or patients would like, in part because nerves in the brain and spinal cord, unlike those in the rest of the body, fail to grow new nerve fibers. Nerves in the brain and spinal cord are surrounded by signals from other cells in the injured area that stop them from growing.
"Molecules in the environment of the injured spinal cord are specifically instructing the nerve end not to regrow," said the study's director, Ronald Schnaar, professor of pharmacology and neuroscience in the Institute of Basic Biomedical Sciences at Johns Hopkins.
"The brain and spinal cord are extremely crowded with nerves and nerve fibers, which may be why we have developed careful controls that tell cells to stop making new connections," he said. "The crowded central nervous system has ways to say 'OK, we're done' to keep nerves from sprouting willy-nilly and making inappropriate connections. But in gaining the ability to crowd nerves close together, we have given up flexibility — the ability to heal after injury.
"If you sever your finger, it can be surgically reattached, and nerve fibers typically grow back so that you can use your finger again," Schnaar said. "In contrast, the injured brain and spinal cord are rocky terrain for nerve fiber growth. Finding ways to smooth that road might help the nerve fibers to regrow."
Several molecules in the spinal cord are known to stop nerve fibers from growing. Schnaar refers to these molecules as axon regeneration inhibitors, or simply ARIs.
"Treatments that eliminate ARIs might allow the nerve ends to regain their natural regenerative abilities as they do in the periphery and improve recovery," Schnaar said.
The researchers looked at the boundary between the spinal cord and the periphery to see if they could coax a nerve end to grow out of the inhibitory spinal cord into a more permissive environment that contains fewer ARIs. They chose to mimic the injury commonly seen in motorcycle accidents, called brachial plexus avulsion, because it involves nerves at the boundary between the spinal cord and periphery.
In anesthetized rats, the researchers surgically severed nerves that normally extend from the spinal cord to the shoulder. They then transplanted a nerve from the hind leg of the same animal into the spinal cord to reconnect the injured nerve ends.
To coax the injured nerve ends to grow fibers and connect to the transplanted nerve, they implanted a pump to bathe the area with one of three enzymes known to destroy ARIs. Four weeks after transplantation and enzyme treatment, the researchers injected dyes into the nerves to see whether and how many nerve fibers had grown from the injured cells of the spinal cord into the transplanted nerve.
Rats treated with sialidase, one of the three enzymes tested, showed well over twice the number of new nerve fibers than rats treated with saline, which is not expected to enhance nerve growth. Moreover, the researchers saw that the new fibers were made by nerve cells residing in the spinal cord.
"We have established that the enzyme sialidase, which destroys one of the molecules that inhibits nerve regeneration, is sufficient to robustly improve nerve fiber outgrowth from the spinal cord," Schnaar said.
Surgical transplantation of a peripheral nerve to help nerve fiber growth from the spinal cord has shown limited success in humans. Lynda Yang, the study's lead author and an assistant professor of neurosurgery at the University of Michigan, said, "The addition of a new treatment to enhance our current surgical management of brachial plexus avulsion in people would be welcomed by patients and surgeons alike." Yang helped pioneer the study of ARIs in the 1990s while a doctoral student with Schnaar at Johns Hopkins.
Having shown in this study that sialidase can increase the number of spinal cord nerve cells that extend fibers into a transplanted nerve, Yang now is testing to see if the nerves re-establish muscle control. "We're very interested in seeing how much function you can get back," she said.
According to Schnaar, there is some evidence that this transplant technique coupled with sialidase treatment can coax other, nearby nerve cells within the spinal cord to grow out as well. "Once you rewire, then the brain does an amazing job of sorting it all out," he said.
Having established the ability of sialidase to improve spinal nerve regeneration into transplanted peripheral nerves, Schnaar and his research team at Johns Hopkins are testing the same treatment to see whether it will help nerve regeneration in other types of spinal cord injuries.
"Even a small improvement might mean a lot," Schnaar said. "People with spinal cord injuries generally are not looking to play football but to regain basic functions. A modest improvement in nerve regeneration might make a big improvement in a patient's quality of life."
The researchers were funded by two branches of the National Institutes of Health: the National Institute of Neurological Disorders and Stroke and the National Heart, Lung and Blood Institute; and by the Department of Neurosurgery at the University of Michigan.
In addition to Yang and Schnaar, authors on the paper are Ileana Lorenzini, Katarina Vajn, Andrea Mountney and Lawrence Schramm, all of Johns Hopkins.