Changing stroke rehab and research worldwide now.Time is Brain! trillions and trillions of neurons that DIE each day because there are NO effective hyperacute therapies besides tPA(only 12% effective). I have 523 posts on hyperacute therapy, enough for researchers to spend decades proving them out. These are my personal ideas and blog on stroke rehabilitation and stroke research. Do not attempt any of these without checking with your medical provider. Unless you join me in agitating, when you need these therapies they won't be there.

What this blog is for:

My blog is not to help survivors recover, it is to have the 10 million yearly stroke survivors light fires underneath their doctors, stroke hospitals and stroke researchers to get stroke solved. 100% recovery. The stroke medical world is completely failing at that goal, they don't even have it as a goal. Shortly after getting out of the hospital and getting NO information on the process or protocols of stroke rehabilitation and recovery I started searching on the internet and found that no other survivor received useful information. This is an attempt to cover all stroke rehabilitation information that should be readily available to survivors so they can talk with informed knowledge to their medical staff. It lays out what needs to be done to get stroke survivors closer to 100% recovery. It's quite disgusting that this information is not available from every stroke association and doctors group.

Tuesday, August 6, 2024

New Multiple Sclerosis Drug Regenerates Myelin, Improves Movement

 Does your competent? doctor and hospitals have enough functioning neurons to see this as a possibility for lost myelin during your stroke? Or don't you have a functioning stroke doctor or hospital?

Ask your doctor point blank. 'Does stroke cause demylination?' If it does then what is your doctor doing to get it repaired?

  • myelin (74 posts to April 2011)

 

But there is also this:

Pregnancy Hormone Estriol May Reverse Myelin Damage in Multiple Sclerosis

 June 2023

And this:

 Antihistamine Sparks Hope for Myelin Repair in Multiple Sclerosis June 2023

 

The latest here:

New Multiple Sclerosis Drug Regenerates Myelin, Improves Movement

Summary: A new drug, PIPE-307, shows promise in reversing multiple sclerosis (MS) damage by promoting myelin regeneration around nerve cells, potentially restoring movement and function.

Developed by researchers, this innovative therapy targets a specific receptor, M1R, and has already demonstrated success in animal models. PIPE-307 is currently in Phase II clinical trials, offering hope for a groundbreaking treatment that could stop and even heal the damage caused by MS.

This novel approach could transform the future of MS therapy by addressing both symptoms and underlying damage.

Key Facts

  1. Myelin Restoration: PIPE-307 stimulates myelin regeneration, potentially reversing MS-related nerve damage.
  2. Targeted Action: The drug precisely targets the M1R receptor, enhancing its effectiveness in treating MS.
  3. Clinical Trials: PIPE-307 is in Phase II trials, showing potential as a transformative MS treatment.

Source: UCSF

Multiple sclerosis (MS) degrades the protective insulation around nerve cells, leaving their axons, which carry electrical impulses, exposed like bare wires. This can cause devastating problems with movement, balance and vision; and without treatment, it can lead to paralysis, loss of independence and a shortened lifespan.

Now, scientists at UC San Francisco and Contineum Therapeutics have developed a drug that spurs the body to replace the lost insulation, which is called myelin. If it works in people, it could be a way to reverse the damage caused by the disease.  

This shows neurons.
The original breakthrough came when Chan invented a method to screen drugs for their ability to instigate remyelination. Credit: Neuroscience News

The new therapy, called PIPE-307, targets an elusive receptor on certain cells in the brain that prompts them to mature into myelin-producing oligodendrocytes. Once the receptor is blocked, the oligodendrocytes spring into action, wrapping themselves around the axons to form a new myelin sheath.

It was crucial to prove that the receptor, known as M1R, was present on the cells that can repair damaged fibers. Contineum scientist and first author Michael Poon, PhD, figured this out using a toxin found in green mamba snake venom. 

The work, which appears Aug. 2 in PNAS, caps a decade of work by UCSF scientists Jonah Chan, PhD,  and Ari Green, MD. Chan led the team to discover in 2014 that an obscure antihistamine known as clemastine could induce remyelination, which no one knew was possible. 

“Ten years ago, we discovered one way that the body can regenerate its myelin in response to the right molecular signal, winding back the consequences of MS,” said Chan, a Debbie and Andy Rachleff Distinguished Professor of Neurology at UCSF and senior author of the paper. “By carefully studying the biology of remyelination, we’ve developed a precise therapy to activate it – the first of a new class of MS therapies.”

A dirty drug creates a clean opening

The original breakthrough came when Chan invented a method to screen drugs for their ability to instigate remyelination. The screen identified a group drugs, including clemastine, that had one thing in common: they blocked muscarinic receptors.  

Clemastine’s benefits begin with its effect on oligodendrocyte precursor cells (OPCs). These cells stay dormant in the brain and spinal cord until they sense injured tissue. Then they move in and give rise to oligodendrocytes, which produce myelin. 

For some reason during MS, OPCs gather around decaying myelin but fail to rebuild it. Chan figured out that clemastine activated OPCs by blocking muscarinic receptors, enabling the OPCs to mature into myelin-producing oligodendrocytes.

Nerves and their myelin are notoriously hard to repair, whether due to MS, dementia or other injury. Green and Chan carried out a trial of clemastine in patients with MS, and it was a success – the first time that a drug showed the capacity to restore the myelin lost in MS. Despite being safe to use, however, clemastine was only modestly effective. 

“Clemastine is not a targeted drug, affecting several different pathways in the body,” said Green, Chief of the Division of Neuroimmunology and Glial Biology in the UCSF Department of Neurology and co-author of the paper. “But from the get-go, we saw that its pharmacology with muscarinic receptors could point us toward the next generation of restorative therapies in MS.” 

A snake venom toxin illuminates the right target

The researchers continued using clemastine to understand the curative potential of regenerating myelin in MS. They developed a series of tools to monitor remyelination, both in animal models of MS and in MS patients, showing that the benefits seen with clemastine came from remyelination – and pointing the way for how new drugs should be tested and evaluated.

They also found that clemastine’s benefits came from blocking just one of the five muscarinic receptors, M1R, but the effect on M1R was middling, and the drug also affected the other receptors. The ideal drug would need to zero in on M1R.

At this point, the UCSF scientists needed an industry partner to advance the project. Ultimately, Contineum Therapeutics (then known as Pipeline Therapeutics) was formed to take a meticulous approach to creating that ideal drug. Chan and Green helped the company confirm that M1R was the right target for a remyelinating drug, and then make a drug that blocked it exclusively.

Poon, a biologist at Contineum, realized that MT7, a toxin found in the venom of the deadly green mamba snake, could reveal exactly where M1R was in the brain.

“We needed to prove, beyond doubt, that M1R was present in OPCs that were near the damage caused by MS,” Poon said. “MT7, which is exquisitely selective for M1R, fit the bill.”

Poon used MT7 to engineer a molecular label for M1R that revealed rings of OPCs gathering around damage in a mouse model of MS and in human MS tissue. 

Developing a clinic-ready drug

A team of medicinal chemists at Contineum, led by Austin Chen, PhD, then got to work on the drug that Chan and Green envisioned, designing PIPE-307 to potently block M1R and get into the brain.

The researchers tested the effects of the new drug on OPCs grown in petri dishes and the animal models of MS using Chan’s and Green’s methods for tracking remyelination. PIPE-307 blocked the M1R receptor much better than clemastine; prompted OPCs to mature into oligodendrocytes and begin myelinating nearby axons; and it crossed the blood-brain barrier.

But most tellingly, it reversed the degradation seen in a mouse model of MS.

“A drug might seem to work in these abstract scenarios, affecting the right receptor or cell, but the key finding was actual recovery of nervous system function,” Chan said. 

In 2021, PIPE-307 passed a Phase I clinical trial, demonstrating its safety. It is currently being tested in MS patients in Phase II. 

If it succeeds, it could transform how MS is treated. 

“Every patient we diagnose with MS comes in with some degree of pre-existing injury,” Green said. “Now we might have a chance to not just stop their disease, but to also heal.”

Other authors are Kym I Lorrain, Karin J Stebbins, Geraldine C Edu, Alexander R Broadhead, Ariana J Lorenzana, Jeffrey R Roppe, Jill M Baccei, Christopher S Baccei, and Daniel S Lorrain, all employees of Contineum Therapeutics.

Funding: The work was partially funded by the NIH/National Institute of Neurological Disorders and Stroke (grants R01NS115746 and R01MH125515). 

Disclosures: All Contineum Therapeutics employees hold financial shares of the company. Chan and Green also hold financial shares in Contineum Therapeutics but no longer serve in any role. Contineum Therapeutics owns patent rights to PIPE-307.

About this multiple sclerosis and neuropharmacology research news

Author: Levi Gadye
Source: UCSF
Contact: Levi Gadye – UCSF
Image: The image is credited to Neuroscience News

Original Research: Open access.
Targeting the muscarinic M1 receptor with a selective, brain-penetrant antagonist to promote remyelination in multiple sclerosis” by Jonah Chan et al. PNAS

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