This is a smart diversion of the immune system reaction that slows the initial intense phase that also damages too much.
It certainly presages a really useful protocol to apply to all spinal and nervous system injuries as well. In fact it needs to be part of all surgical interventions as well to clean up the raw damage itself and allow possible nerve repair.
Far too many surgical intervention do cause serious and irreversible nerve damage.
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Scientists Demonstrate Success of a Possible ‘EpiPen’ to Prevent Paralysis From Spinal Cord Injuries
By
Good News Network
Feb 23, 2020
https://www.goodnewsnetwork.org/scientists-demonstrate-success-of-a-possible-epipen-to-prevent-paralysis-from-spinal-cord-injuries/
Calling it an “EpiPen” for trauma to the central nervous system, University of Michigan researchers have shown how an injection of nanoparticles can prevent the body’s immune system from overreacting to trauma—potentially preventing some spinal cord injuries from resulting in paralysis.
The approach was demonstrated in mice by the scientists in Ann Arbor, when the nanoparticles enhanced healing by reprogramming the aggressive immune cells.
“In this work, we demonstrate that instead of overcoming an immune response, we can co-opt the immune response to work for us to promote the therapeutic response,” said Lonnie Shea, the Steven A. Goldstein Collegiate Professor of Biomedical Engineering.
Trauma of any kind kicks the body’s immune response into gear. In a normal injury, immune cells infiltrate the damaged area and clear debris to initiate the regenerative process.
The central nervous system, which includes the brain and spinal cord, however, is normally walled off from the immune activity by the blood-brain barrier. But a spinal cord injury breaks that barrier, letting in overzealous immune cells that create too much inflammation for the delicate neural tissues. This leads to the rapid death of neurons, damage to the insulating sheaths around nerve fibers that allow them to send signals, and the formation of a scar that blocks the regeneration of the spinal cord’s nerve cells.
All of this contributes to the loss of function below the level of the injury. That spectrum includes everything from paralysis to a loss of sensation for many of the 12,000 new spinal injury patients each year in the United States.
Previous attempts to offset complications from this immune response included injecting steroids like methylprednisolone. That practice has largely been discarded since it comes with side effects that include sepsis, gastrointestinal bleeding and blood clots—and the risks outweigh the benefits.
But now, U-M researchers have designed nanoparticles that intercept immune cells on their way to the spinal cord, redirecting them away from the injury. Those that reach the spinal cord have been altered to be more pro-regenerative.
Hopefully, this technology could lead to new therapeutic strategies not only for patients with spinal cord injury but for those with various inflammatory diseases.
With no drugs attached, the nanoparticles reprogram the immune cells with their physical characteristics: a size similar to cell debris and a negative charge that facilitates binding to immune cells. In theory, their non-pharmaceutical nature avoids unwanted side effects.
With fewer immune cells at the trauma location, there is less inflammation and tissue deterioration. Second, immune cells that do make it to the injury are less inflammatory and more suited to supporting tissues that are trying to grow back together.
“Hopefully, this technology could lead to new therapeutic strategies not only for patients with spinal cord injury but for those with various inflammatory diseases,” said Jonghyuck Park, a U-M research fellow working with Shea.
Previous research has shown success for nanoparticles mitigating trauma caused by multiple sclerosis and the West Nile virus, for example.
“The immune system underlies autoimmune disease, cancer, trauma, regeneration—nearly every major disease,” Shea said. “Tools that can target immune cells and reprogram them to a desired response have numerous opportunities for treating or managing disease.”
By
Good News Network
Feb 23, 2020
https://www.goodnewsnetwork.org/scientists-demonstrate-success-of-a-possible-epipen-to-prevent-paralysis-from-spinal-cord-injuries/
Calling it an “EpiPen” for trauma to the central nervous system, University of Michigan researchers have shown how an injection of nanoparticles can prevent the body’s immune system from overreacting to trauma—potentially preventing some spinal cord injuries from resulting in paralysis.
The approach was demonstrated in mice by the scientists in Ann Arbor, when the nanoparticles enhanced healing by reprogramming the aggressive immune cells.
“In this work, we demonstrate that instead of overcoming an immune response, we can co-opt the immune response to work for us to promote the therapeutic response,” said Lonnie Shea, the Steven A. Goldstein Collegiate Professor of Biomedical Engineering.
Trauma of any kind kicks the body’s immune response into gear. In a normal injury, immune cells infiltrate the damaged area and clear debris to initiate the regenerative process.
The central nervous system, which includes the brain and spinal cord, however, is normally walled off from the immune activity by the blood-brain barrier. But a spinal cord injury breaks that barrier, letting in overzealous immune cells that create too much inflammation for the delicate neural tissues. This leads to the rapid death of neurons, damage to the insulating sheaths around nerve fibers that allow them to send signals, and the formation of a scar that blocks the regeneration of the spinal cord’s nerve cells.
All of this contributes to the loss of function below the level of the injury. That spectrum includes everything from paralysis to a loss of sensation for many of the 12,000 new spinal injury patients each year in the United States.
Previous attempts to offset complications from this immune response included injecting steroids like methylprednisolone. That practice has largely been discarded since it comes with side effects that include sepsis, gastrointestinal bleeding and blood clots—and the risks outweigh the benefits.
But now, U-M researchers have designed nanoparticles that intercept immune cells on their way to the spinal cord, redirecting them away from the injury. Those that reach the spinal cord have been altered to be more pro-regenerative.
Hopefully, this technology could lead to new therapeutic strategies not only for patients with spinal cord injury but for those with various inflammatory diseases.
With no drugs attached, the nanoparticles reprogram the immune cells with their physical characteristics: a size similar to cell debris and a negative charge that facilitates binding to immune cells. In theory, their non-pharmaceutical nature avoids unwanted side effects.
With fewer immune cells at the trauma location, there is less inflammation and tissue deterioration. Second, immune cells that do make it to the injury are less inflammatory and more suited to supporting tissues that are trying to grow back together.
“Hopefully, this technology could lead to new therapeutic strategies not only for patients with spinal cord injury but for those with various inflammatory diseases,” said Jonghyuck Park, a U-M research fellow working with Shea.
Previous research has shown success for nanoparticles mitigating trauma caused by multiple sclerosis and the West Nile virus, for example.
“The immune system underlies autoimmune disease, cancer, trauma, regeneration—nearly every major disease,” Shea said. “Tools that can target immune cells and reprogram them to a desired response have numerous opportunities for treating or managing disease.”
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