Early prototypes of any technology can be a little persnickety. Just ask Sofia Fluke, a test engineer at the in Eugene.
She sits hunched over her desk with a small, orange flathead screwdriver, trying to replace the lid on an electronics casing about the size of a deck of cards.
The screw wobbles as she turns it.
鈥淚t easily falls out if you鈥檙e not very, very slow,鈥 she says. 鈥淚t鈥檚 a very delicate process because we just made all of this ourselves.鈥
The electronics casing houses the brains of a new device called the WISP 鈥 or the Wireless Interface Sensor Pod.
Its DIY origins are rather obvious. The casing attaches to what looks like a headlamp strap. Wired electrodes dangle off the sides and others are housed in a zip-up pouch on the front.
Despite the inelegance of this early design, the technology itself is anything but.
The WISP has the potential to change the way we think about sleep.
The yawning hole of sleepless nights
The WISP is a headband designed to be worn while sleeping. It harnesses brainwaves to give you a better night鈥檚 rest.
suffers from chronic sleep problems, according to the Centers for Disease Control and Prevention. And for a lot of them 鈥 including new parents, night shift workers, soldiers, and nearly everyone as they get older 鈥 the WISP may eventually provide relief from sleep deprivation and disrupted sleep.
鈥淲e used to think that the need to sleep was something we could minimize or conquer. But really over the past couple of decades, we鈥檝e started to understand just how important it is,鈥 said neurologist Miranda Lim.
And it鈥檚 not just how long we sleep. Quality matters.
鈥淧harmaceutical companies for decades have been seeking this 鈥榤agic pill鈥 or 鈥楬oly Grail.鈥 They have medications out there that do increase total sleep duration, but many of them have side effects,鈥 she said. 鈥淭hose don鈥檛 address the quality of sleep.鈥
The goal of Lim and the team at BEL is to use WISP to influence a sleep stage known as 鈥渄eep sleep鈥 or slow-wave sleep.
鈥淪leep scientists, for many years now, have thought that the most restorative phase of sleep is slow-wave sleep, the sleep that you see usually in the first half of the night as soon as your head hits the pillow,鈥 Lim said.
Brainwaves are normally chaotic. Neurons fire in different parts of your brain as you talk, move, dream and solve problems. It鈥檚 a purposeful cacophony. But during deep sleep, your brain waves slow down and synchronize, throbbing in slow oscillations.
The WISP detects when your brain is just starting to enter deep sleep.
鈥淸WISP users] have a little nanocomputer at their bedside that helps to detect the brainwaves. And there we use machine learning so that we can recognize the brainwaves and tell which stage the sleep they鈥檙e in,鈥 said BEL founder Don Tucker, a .
And this is where it gets weird.
The WISP then delivers a light electrical stimulus to different spots on the head.
鈥淎t that exact moment it sees [the slow waves starting], the device will hook onto those and stimulate the brain to make those larger and last longer,鈥 Lim said.
It only takes a few minutes of WISP stimulation and synchronization.
鈥淭he interesting thing was that once we do that, the brain鈥檚 slow oscillations continue throughout the night. It鈥檚 like we jumpstart the natural rhythms and keep them going,鈥 Tucker said.
Finding the right paradigm
The BEL team didn鈥檛 discover this quirk of neurobiology, but they have been able to isolate and target where these slow waves originate.
They鈥檝e tested WISP on a few people in Oregon so far, and the.
So much so, that it caught the attention of the U.S. military, which to accidents, traumatic brain injury, PTSD and suicide.
The , contributing $4.3 million split between the WISP and other research connected to the project.
In preparation, BEL engineers are busy developing a new prototype that鈥檒l be a little more sleek, stylish and comfortable.
It could be life-changing if the WISP delivers and gives sleep-deprived people a better night鈥檚 rest, but the work is still in the early stages.
鈥淭he concept is that you facilitate what is already there,鈥 said Lisa Marshall, a neuroscientist at the , who , but is not associated with the BEL project. 鈥淚f [the stimulus is] individualized enough in topography and timing and all that, it could have a very good potential.鈥
The extent of that potential will be revealed during the human trials, which are slated to enroll a total of 90 people this summer at the and the . And even then, more refinement will likely be required.
鈥淸You] might have to find the right kind of paradigm. Maybe you use it for three days and then you stop and then you start again. There might be some kind of optimum,鈥 Marshall said. 鈥淭here is usually adaptation of the body to whatever external influence there is. And some parameters will probably have to be changed.鈥
This unremembered state
If effective, it鈥檒l likely be years before the WISP is broadly available, though BEL does hope to market the device as a sleep aid. But this story of Pacific Northwest innovation is about much more than feeling more rested and alert in the morning.
鈥淲e think improving deep sleep is important for everybody who鈥檚 over 30 and not getting any younger,鈥 Tucker said.
That鈥檚 because of the connection between deep sleep and how humans create, organize and store different types of memories.
鈥淎s you get older, as I can verify, your memory is not as good for all the incidental things that happen during the day. And there鈥檚 very good evidence that part of that鈥檚 because you鈥檙e losing the capacity for deep sleep,鈥 he said. 鈥淲e think that sleep is one of the ways to improve the brain function of an aging population.鈥
Tucker is not just talking about memories like where we left our keys or that secret ingredient in grandma鈥檚 pot pie.
Recent discoveries in neuroscience are linking the lack of sleep with much more serious memory disorders like Alzheimer鈥檚 and other types of dementia.
The discoveries involve a part of the brain we didn鈥檛 really know existed until about a decade ago. It鈥檚 called the , which can be thought of as a type of circulatory system in the brain. Instead of blood, the glymphatic system circulates cerebrospinal fluid (CSF).
Jeffrey Iliff is a collaborator on the larger project that includes WISP testing. He studies neurodegeneration at the and the and was part of the team that.
鈥淭he glymphatic system was described as the brain鈥檚 way of washing away wastes during the night that accumulate through the course of the day,鈥 he said.
These proteins and other metabolic wastes are a byproduct of normal brain function. This taking-out-the-trash work done by the glymphatic system is a phenomenon Iliff calls 鈥渂rainwashing.鈥 It happens most efficiently during deep, slow-wave sleep.
When this brainwashing is stymied 鈥 possibly through lack of deep sleep 鈥 Iliff said the waste isn鈥檛 cleared as effectively. And it鈥檚 believed that build-ups of some of these by-products play a starring role in the development of Alzheimer鈥檚 disease.
Measure for measure
This science is so new that most of what we know about the glymphatic system comes from what researchers have observed in mice.
鈥淭he glymphatic system right now is an enigma. We know it exists in mice. We think it exists in people and we have some proof. but we really don鈥檛 know what it looks like. We don鈥檛 know how it functions,鈥 said Swati Rane Levendovszky, director of the.
It鈥檚 still impossible to draw clear lines that connect sleep, glymphatics and dementia.
鈥淲e don鈥檛 yet have the smoking gun that says, 鈥榊es, the impairment of this process is contributing to Alzheimer鈥檚 disease in human populations.鈥 The reason why we don鈥檛 have that smoking gun is because we haven鈥檛 had a good way to measure this function in human populations in a reasonable way,鈥 Iliff said.
In science, if you can鈥檛 measure something, you can鈥檛 truly understand it.
This is where Rane Levendovszky鈥檚 MRI imaging work connected to the WISP trials looms large.
鈥淢RI is my window into their brain,鈥 she explained.
At the , Rane Levendovszky is developing non-invasive ways to measure the flow of the glymphatic system in humans after a good and bad night鈥檚 sleep.
鈥淲e know that the glymphatic system has many different components. The CSF washing is occurring along the (outside of the) brain. It is occurring along the blood vessels in the brain. And then there鈥檚 a component where fluid is moving within the tissue of the brain and then it drains out. So we are trying to see if we can target each of these components using different MRI methods,鈥 she said.
The WISP trials are the perfect opportunity for this because the slow, synchronized waves of deep sleep are when the glymphatic system takes out the most trash.
鈥淲e are trying 鈥 to see the system from many different angles, hoping to catch some part of it. And then put the pieces of the puzzle together and have a picture of glymphatics and how it works,鈥 she said.
If the team鈥檚 hypothesis holds, disrupting sleep will disrupt the glymphatic system, and improving deep sleep will make it work even better. Ideally, Rane Levendovszky鈥檚 new MRI techniques will be able to measure glymphatic flow in both cases.
The techniques could throw open the proverbial shutters on glymphatic science.
鈥淭hey have implications that go way beyond this study鈥 out into Alzheimer鈥檚 disease and Parkinson鈥檚 and headaches and concussions and all sorts of other conditions,鈥 Iliff said.
Rane Levendovszky said she sees the potential for a clinical application as well. She envisions a time when people over 65 get a routine MRI to gauge how well their glymphatic system is working.
鈥淭hat could be an indication that okay, you鈥檙e at risk of Alzheimer鈥檚,鈥 she said. 鈥淪o you can help at first, maybe slow down the progression of the disease. And maybe at some point, develop technology or therapy that can just prevent it 鈥 at a later stage.鈥
And if getting better deep sleep can help prevent the disease, that technology might end up looking something like Don Tucker鈥檚 WISP headband, improving our sleep tonight and into the future.
鈥淥ne of the questions is: Can we keep this up for weeks and months and really change somebody鈥檚 brain aging process? Can we make younger brains by helping to synchronize them in the deep sleep?鈥 he asked.
And maybe if we sleep better, we鈥檒l age better too.
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