Health & Wellbeing

Brain-zapping headwear designed to treat Parkinson's

Brain-zapping headwear designed to treat Parkinson's
David Blumenstyk models the STIMband non-invasive brain stimulator prototype for Parkinson's treatment that he co-created with four other Johns Hopkins students
David Blumenstyk models the STIMband non-invasive brain stimulator prototype for Parkinson's treatment that he co-created with four other Johns Hopkins students
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David Blumenstyk models the STIMband non-invasive brain stimulator prototype for Parkinson's treatment that he co-created with four other Johns Hopkins students
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David Blumenstyk models the STIMband non-invasive brain stimulator prototype for Parkinson's treatment that he co-created with four other Johns Hopkins students
The team behind the STIMband device
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The team behind the STIMband device
An illustration of the STIMband headset design
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An illustration of the STIMband headset design
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A team of graduate students at Johns Hopkins University has created a prototype device that delivers non-invasive brain stimulation to sufferers of Parkinson's disease. The brain-zapping headwear, dubbed STIMband, helps to reduce the severity of symptoms without requiring a visit to a hospital or doctor's office.

While the device has not yet been clinically trialled on humans, its design took out second place at the VentureWell BMEidea national design contest earlier this month as well as first place in the People's Choice Award at Johns Hopkins' Biomedical Engineering Design Day 2015.

Parkinson's affects a million people in the United States and seven million people worldwide, with symptoms including uncontrollable tremors and slow movement. It cannot be cured, it gets worse over time, and many of its treatments become less effective after prolonged use.

The students took inspiration from one of the more invasive and advanced treatment options: deep brain stimulation. This involves a surgeon implanting electrical leads into the region of the brain that controls movement. A pulse generator inserted under the skin below the collarbone provides electrical signals that create a lesion, which blocks the abnormal nerve signals and thereby reduces the targeted symptom.

"We saw that this procedure is really invasive and can take 10 to 15 hours to complete," said team member Shruthi Rajan. "It's also very expensive, and not all patients qualify for the surgery. We asked if there was a way to provide the same treatment in a less invasive way that doesn't require brain surgery."

From there, the students learned about an experimental clinical treatment called transcranial direct current stimulation, which involves low-level current being passed through electrodes on a patient's head. Like deep brain stimulation, it affects electrical activity in specific areas of the brain, but it's cheap, safe, and has no known side effects.

The students essentially developed a portable version of the treatment – one that could run off a battery and be activated at the push of a button. Their prototype works for up to 20 minutes per day, with current delivered at a doctor-prescribed level. It goes on your head somewhat like a baseball cap, with an elastic band that stretches to fit the size and shape of your skull.

The students obtained provisional patents to cover STIMband's design, which is still a work in progress. Another Johns Hopkins student team will take over development in September, with a likely additional feature being remote connectivity that allows a doctor to adjust a home patient's treatment levels from his or her office.

Source: Johns Hopkins University

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