WHOM is the person responsible for shepherding this through human clinical studies to a translational protocol? With no one identified it will fall thru the cracks like the thousands of other research studies that showed promise in animals. Well, years ago Dr. Michael Tymianski of the Toronto Western Hospital Research Institute in Canada referenced 1000+ failed neuroprotective clinical trials. Of course nobody knows of them and what knowledge they provided, but your doctor should know every one of those failed trials.
The answers are out there if someone with a few functioning brain cells would put together a strategy to follow up promising research. We have to direct the research being done for stroke, we can't let researchers flail about.
Brain protein critical to recovery from stroke identified
"Even though traditional stroke therapies are very effective when available, the treatment must be started in the first hours after a stroke and most patients are not able to get these treatments. So there is a clear need for new approaches that can improve recovery days after a patient experiences a stroke," said co-senior author Steven Graham, M.D., Ph.D., professor of neurology at Pitt's School of Medicine, and associate chief of staff for research at VA Pittsburgh. "We think we have identified a protein that is at the root of how the brain recovers from stroke, making it an attractive target for developing drugs that help improve recovery."
UCHL1 is an enzyme that is highly active in the brain and plays a role in clearing away abnormal proteins. Mutations in the gene coding for UCHL1 have been thought to cause motor function deficits in humans. Previous research from Graham's lab had provided some hints as to UCHL1's function, showing that cyclopentenone prostaglandins (CyPgs) - fatty acid molecules - released in nerve cells after a stroke bind to UCHL1 and impair its function.
Graham teamed up with Feng Zhang, Ph.D., an assistant professor of neurology at Pitt's School of Medicine and a co-senior author on the current study published in the Proceedings of the National Academy of Sciences, to tease out the exact role of UCHL1 in stroke and to determine if it could be a viable drug target.
The researchers created a mouse model in which they inserted an altered version of the UCHL1 gene that was resistant to the effects of the CyPgs. They then surgically modelled the effect of a stroke in both genetically engineered and normal mice to compare how the nerve cells recovered.
Preventing CyPgs from inhibiting UCHL1 decreased the amount of injury to the axons after stroke when compared to normal mice. Axons - the long cables projecting outward from the center of the nerve cell - are needed to carry electrical signals and connect to other neurons and make up the bulk of the 'white matter' in the brain.
Further experiments showed that keeping UCHL1 active after a stroke helped preserve the function of neurons and brain tissue by activating cellular repair mechanisms that quickly cleaned up damaged proteins, preventing further nerve cell loss. The mice with the resistant form of UCHL1 also had improved recovery of waking, balance and other motor functions.
"While most stroke therapies focus on preventing neuronal death, preserving axonal integrity and decreasing white matter injury could be equally important for improved recovery," said Graham, who also is a neurologist at the UPMC Stroke Institute. "UCHL1 is a central player in that process."
Graham and his colleagues are now engaged in efforts to identify new drugs that could prevent CyPgs from binding to UCHL1 or to replace damaged UCHL1 proteins with a derivative that can be given intravenously.
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