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While more people are surviving strokes, many still face long-term disability. But Johns Hopkins research finds promising ways to retrain the brain and regain independence. Here’s what experts have learned about the power of physical rehab.
“When we speak about recovery we’re really talking about how the nervous system adapts to the brain missing a part of functioning tissue,” explains Johns Hopkins expert(Hah!) Steven Zeiler, M.D., Ph.D. “We’ve done all we could in the acute period,(Completely and totally wrong you solve the neuronal cascade of death. You're making an invalid assumption that new interventions won't be found. Be a leader, tackle the difficult problems), but the damage is done and it’s irreversible.(What about neurogenesis?)” The question then becomes, “How do you get the remainder of the nervous system to adapt?” In other words, can we get other parts of the brain to pick up the slack? Turns out that yes, we can.
Retraining the Brain
A groundbreaking Johns Hopkins study from Zeiler and his colleagues confirmed what clinicians have long suspected—we can rewire the brain so that one part takes over functions typically handled by another, now damaged, area.In studies conducted with mice, the researchers first taught the mice a special way to reach for food. The task is typically directed by a part of the brain called the primary motor cortex, which is involved in physical coordination. Then they gave the mice mild strokes that damaged this motor cortex. As expected, the mice could no longer perform the reaching task with their pre-stroke level of precision. Two days after the stroke, however, researchers began retraining the mice and, after a week, the mice performed the task just as well as before the stroke.
The damaged part of the brain hadn’t recovered, says Zeiler. Instead, another part of the brain called the medial premotor cortex took over. To show that, researchers gave the mice strokes in that part of the brain and saw the reaching ability again disappear. But, once again, the mice relearned the task as yet another part of the brain stepped in to handle the job of the medial premotor cortex.
In a similar study, the researchers found that the earlier retraining started, the better. “If you retrained the mice after a one-day delay they got better, but after a seven-day delay they didn’t improve,” Zeiler says.
Johns Hopkins’ Kata Project, a collaboration between neuroscientists, engineers, animal experts, artists and entertainment industry experts, has designed an immersive experience for post-stroke patients who will try to “swim” as a virtual dolphin named Bandit. Upcoming clinical trials will determine if this unique experience helps patients recover motor function faster than the current conventional treatment of repetitive exercises.
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