Since we have NO LEADERSHIP IN STROKE, there is no one who will look at this and say. 'Yes, this is in rats and for TBI but we should do the research and test this in humans for stroke. Nothing will happen.
Synthetic hydrogel to repair circuitry in severe TBI
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At
a cost of $38 billion a year, an estimated 5.3 million people are
living with a permanent disability related to traumatic brain injury in
the United States today, according to the Centers for Disease Control
and Prevention. The physical, mental and financial toll of a TBI can be
enormous, but new research provides promise.
In a new study, researchers have demonstrated the long-term benefits of a
hydrogel, which they call "brain glue," for the treatment of traumatic
brain injury. The new study provides evidence that not only does the gel
protect against loss of brain tissue after a severe injury, but it also
might aid in functional neural repair.
Brain damage following significant TBI commonly results in extensive
tissue loss and long-term disability. There currently are no clinical
treatments to prevent the resulting cognitive impairments or tissue
loss.
Reported in Sciences Advances, the new finding is the first to
provide visual and functional evidence of the repair of brain neural
circuits involved in reach-to-grasp movement in brain glue-implanted
animals following severe TBI.
"Our work provides a holistic view of what's going on in the recovery of
the damaged region while the animal is accomplishing a specific
reach-and-grasp task," said the lead author.
Created in 2017, brain glue was designed to mimic the structure and
function of the meshwork of sugars that support brain cells. The gel
contains key structures that bind to basic fibroblast growth factor and
brain-derived neurotrophic factor, two protective protein factors that
can enhance the survival and regrowth of brain cells after severe TBI.
In a prior short-term study, the team showed that brain glue
significantly protected brain tissue from severe TBI damage. In this new
research, to harness the neuroprotective capacity of the original, they
further engineered the delivery surface of protective factors to help
accelerate the regeneration and functional activity of brain cells.
After 10 weeks, the results were apparent.
"Animal subjects that were implanted with the brain glue actually showed
repair of severely damaged tissue of the brain," said the author. "The
animals also elicited a quicker recovery time compared to subjects
without these materials."
To measure the glue's effectiveness, the team used a tissue-clearing
method to make brain tissue optically transparent, which allowed them to
visually capture the immediate response of cells in the reach-to-grasp
circuit using a 3D imaging technique.
"Because of the tissue-clearing method, we were able to obtain a deeper
view of the complex circuitry and recovery supported by brain glue,"
said the author. "Using these methods along with conventional
electrophysiological recordings, we were able to validate that brain
glue supported the regeneration of functional neurons in the lesion
cavity."
The author pointed out that the RTG circuit is evolutionarily similar in
rats and humans. "The modulation of this circuit in the rat could help
speed up clinical translation of brain glue for humans," the author
said.
https://news.uga.edu/brain-glue-helps-repair-circuitry-in-severe-tbi/
https://advances.sciencemag.org/content/7/10/eabe0207
http://sciencemission.com/site/index.php?page=news&type=view&id=publications%2Fengineered-glycomaterial&filter=22
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