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.

Wednesday, July 19, 2023

Pure Oxygen Speeds Up Learning. Can It Help Stroke Survivors Recover?

 

If your doctor is doing nothing about oxygen delivery to the brain s/he is letting more neurons die than should. ARE YOU OK WITH THAT? Mine let 5.4 billion neurons die that first week.

No protocol, you need to fire the complete stroke department, starting with the board of directors.  I would suggest one of these:

Possible solutions: Obviously not vetted coming from me. Don't do them.  I'm not medically trained.

You can look at the years these were reported on and tell how long your hospital has been incompetent.

 

How to Improve Your Brain Function with An Oxygen Concentrator April 2018 

Or is it more important to increase the loading ability of red blood cells to carry more oxygen? 

Like this?

University of Glasgow Study Demonstrates the Ability of Oxycyte® to Supply Oxygen to Critical Penumbral Tissue in Acute Ischemic Stroke  August 2012

Or like this?

chronic cannabis users have higher cerebral blood flow and extract more oxygen from brain blood flow than nonusers. August 2017   

Vinpocetine increases cerebral blood flow and oxygenation in stroke patients: a near infrared spectroscopy and transcranial Doppler study May 2015 

Or this? having red blood cells release more oxygen.

Methylene blue shows promise for improving short-term memory


HOW FUCKING LONG WILL YOU LET YOUR INCOMPETENT STROKE HOSPITAL STILL TREAT PATIENTS LIKE NOTHING NEW HAS OCCURRED IN THE PAST 50 YEARS?

 

Or maybe this newest one I found about on Shark Tank, what is the downside? You can't listen to anything I have to say, I'm not medically trained, is your doctor?

Boost Oxygen on Shark Tank highlights

The latest here:

Pure Oxygen Speeds Up Learning. Can It Help Stroke Survivors Recover?

As a physical therapist in Shanghai, Zheng Wang worked with people recovering from strokes after their brains had been damaged by oxygen deprivation. They usually followed a predictable recovery pattern, making lots of progress over the first few visits, then hitting a wall. Patients asked when they’d finally feel normal, and Wang told them that they’d get better with time. “But actually,” he remembers, “I knew from the bottom of my heart that they wouldn’t improve much, no matter how hard we tried.”

Meanwhile, halfway across the world, Marc Dalecki, then an associate professor in the School of Kinesiology at Louisiana State University (LSU), couldn’t stop thinking about oxygen. Dalecki spent much of his early career studying scuba diving and remembers divers using nasal cannulas of O2 to help with everything from hypoxia to headaches. He always wondered whether this simple treatment could help neurological patients in rehab. “I promised myself that I would study it when I got my own research lab,” he says.

For its relatively small size, the brain consumes a ridiculous amount of power: 20 to 30 percent of the body’s energy at rest. To fuel all of its neurons, the brain depends on oxygen. When someone has a stroke or a head injury, the flow of oxygenated blood to the brain gets disrupted. Starved of oxygen, the brain tissue is damaged, leading to a host of problems with memory, speech, strength, and motor control.

Rehabilitation from brain trauma usually involves working with a physical therapist to relearn motor skills, building up the strength and coordination required for daily activities, like making coffee, writing, and brushing your teeth. Many physical therapists already use high-tech devices to help patients recover faster, from robots that move impaired limbs to virtual reality games that simulate aspects of day-to-day life that can’t be easily replicated in a hospital setting. But Wang and Dalecki both wondered whether oxygen could be the simple, cheap, accessible addition to neurological rehabilitation they’d been looking for. If they could give patients a little extra oxygen during early motor rehab sessions, they thought, it might help them relearn old skills faster.

The two of them joined forces in Dalecki’s lab at LSU, where Wang, frustrated as a clinician, decided to get a PhD in kinesiology. In a study published last week in Frontiers in Neuroscience, their team showed that sniffing pure oxygen while learning a challenging motor task helped healthy young people learn faster and perform better. They think this relatively low-cost, low-risk idea could be used to speed up stroke recovery.

For their study, they recruited 40 healthy young adults to each sit at a desk while wearing a nasal cannula. Their instructions were simple: Hold a stylus at the center of a tablet screen, then drag it to a target that pops up somewhere else, as quickly and efficiently as possible. But after a few trials, the relationship between the stylus and the screen shifted, creating a 60-degree difference between the line a participant thought they drew and the line that actually appeared on the screen. While the volunteers adjusted their line drawing to these new, more challenging circumstances, air started flowing through the cannula. Half of the participants got pure oxygen, while the other half got medical air (essentially an ultra-clean version of regular air). It was a quick blast, only during these few minutes of initial learning. Then the air flow shut off and the screen went back to normal.

The air tanks were hidden from view, so no one knew whether they received pure oxygen or not. But the participants sniffing pure O2 performed faster and drew more efficient paths—a nearly 30 percent increase in both speed and accuracy—than those who didn’t get an oxygen boost. The biggest improvements happened during early learning.

In a follow-up study that will be published later this year in Behavioral Brain Research, Wang’s team also found that breathing pure oxygen helped healthy young people respond 20 percent faster than those without the oxygen boost in a more cognitively taxing motor task, where they had to learn to quickly press buttons in a specific order (like learning to play the piano). And in a third study, currently under review, they used a noninvasive brain imaging technique called near-infrared spectroscopy to confirm that higher levels of oxygen in the frontal lobe were positively correlated with bigger improvements in response time during the button-pressing task.

It is still unknown exactly how oxygen helps the brain. One theory is that in cases where a brain injury worsens circulation in neural tissues, bringing in more oxygen can help increase plasticity and boost learning and memory, says T. G. Hornby, who is a professor of physical medicine and rehabilitation at Indiana University and was not involved in this study. Wang likens the difference in brain oxygen to the difference between going to the regular grocery store and going to Costco: When you fully stock your pantry, you can sustain yourself for weeks without stress. With better brain oxygenation, he suspects, neurons can draw from a stockpile of extra fuel to help them build new connections.

Even though these studies were conducted in healthy people, Wang and Dalecki think oxygen will be useful for stroke survivors, whose brains need the extra fuel to power motor learning sessions during physical therapy. They envision oxygen someday being used in early stages of rehab—people could use a cannula to breathe air from an oxygen backpack, which would be worn while practicing day-to-day tasks or relearning how to walk. “An oxygen tank could be a very easy add-on to daily training,” says Wang. “It’s just naturally there, not causing lots of distractions. I think it’s very viable.”

Critically, Dalecki says, the boost provided by oxygen during the second test seemed to last overnight—a good sign for rehab, when people need to relearn a wide range of daily tasks and be able to apply the progress they make during physical therapy to their daily lives.

But much more work needs to be done before pure oxygen is incorporated into neurological motor rehab. “We need trials in the right patient population, in more realistic settings. But this is how science starts,” says Hornby. “There are so many other layers to this.”

First of all, stroke risk increases with age, and the brains of young and old people are very different: Will an oxygen treatment that helps twentysomethings also help people over three times their age? With age, learning capacity decreases, blood vessels get stiffer, and metabolism slows down. With older patients, Wang says, “even if you provide them with extra oxygen, it might not help them as much as it helps young people.” But when it comes to relearning lost motor skills, he says, older people generally start at a lower baseline, giving them more room to grow.

Breathing in too much extra oxygen can cause oxygen poisoning, which can present as chest pain, coughing, nausea, and convulsions—and in severe cases, seizures, coma, and death. It’s a risk for scuba divers and people on ventilators, but Dalecki says this is very unlikely to happen in a rehab setting, where people are breathing oxygen at normal atmospheric pressure for less than an hour at a time. The motor task in the first study took about 30 to 45 minutes, about the same amount of time someone in stroke recovery would do physical therapy before getting too tired to continue.

Given the promising early results, low risk, and potential benefit to patients, Wang (who is now a postdoc at the Mayo Clinic) and Dalecki (now at the German University of Health and Sports in Berlin) aim to start testing oxygen in older people, and eventually in older people recovering from a stroke. There are still many details of this treatment to nail down: Should oxygen-assisted learning only happen in the first rehab session or two or does it need to be ongoing? How long will the effects last?

The skills stroke patients want to practice, like walking, speaking, and doing household chores, are much more complex than the simple tasks participants learned in the lab. Dalecki hopes that more scientists will dive into these questions now that the initial work has been done. “It sounds so simple,” he says, “and it’s now out in the world. I’m very excited to see what comes along with that.” 

“There is so much to do,” Dalecki adds. “I’ll do it until I’m retired.”

 

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