PORTLAND, Oreg. (Ivanhoe Newswire) - Fully aware of his surroundings, but unable to communicate; he's locked-in. Now, new technology is helping an accident victim unlock his voice.
A car crash, then a stroke left this champion wrestler, college student, and army communications specialist locked-in.
Now, Greg Bieker communicates with his eyes.
Using a chart, those closest to him can figure out what Greg is saying.
It's tedious and time consuming. Greg can only communicate when someone else is in the room.
Now researchers at the Oregon Health and Science University Brain Institute are using this brain-computer interface to give people like Greg more freedom.
Greg puts on a cap with electrodes.
"The computer detects changes. That change is noted as basically a mouse click," Aimee R. Mooney, M.S., CCC-SLP/L at the Oregon Health and Science University, told Ivanhoe.
"Say the word is "the," when he sees that ‘t' he needs to think yeah! Or he thinks t and that creates a spike in the brain signal that the computer can recognize," Betts Peters, Speech-language Pathologist at the Oregon Health & Science University, told Ivanhoe.
Like texting on a smartphone, the technology can predict words. Soon it could also predict whole sentences and possibly do even more for Greg.
"Maybe change the channel in a TV or the volume," Kelly Jo Stransky, Greg's caregiver, told Ivanhoe.
We asked Greg why he's doing this; his response, "to help people less fortunate than himself."
Brain Institute officials believe locked-in patients are just the beginning. Currently in trials, this technology could also be used to help people with advanced Lou Gehrig's disease, severe Parkinson's, MS, and spinal cord injuries.
BACKGROUND: There are over 2 million people in the U.S. with some level of functional LIS. (Source: www.ohsu.edu/xd/research) Locked-In Syndrome is a rare neurological disorder characterized by paralysis of voluntary muscles in all parts of the body except for the muscles that control eye movement. The disease will leave the person completely paralyzed and mute. Communication is possible through blinking of the eyes. Patients are able to reason and are conscious; they just cannot move or speak. It could be a result from traumatic brain injury, diseases that destroy the myelin sheath surrounding nerve cells, diseases of the circulatory system, or medication overdose. There are three classifications of Locked-In Syndrome: complete LIS (quadriplegia), classic LIS (preserved vertical eye movement), and Incomplete LIS (recovery of some voluntary movements). (Source: www.ninds.nih.gov)
CAUSES: Locked-In Syndrome is most commonly caused by any condition that affects an area of the brain called the ventral pons. This part of the brain is where all of the nerve tracts that are responsible for voluntary movement pass through. The area of the brain that is responsible for consciousness is preserved above the ventral pons; therefore, allowing the person to be able to think. Diagnosis for a conscious individual with no muscle functioning means they respond to questions by blinking. Doctors will diagnose further by CT or MRI scans to reveal if there is a presence of stroke or aneurysm that could have caused the condition. (Source:www.ninds.nih.gov)
TREATMENT: Unfortunately, there is no cure or a standard treatment plan. A therapy called functional neuromuscular stimulation, which uses electrodes to stimulate muscle reflexes, might help to activate paralyzed muscles. There are also several devices to help with communication. The most important goal of rehabilitation is finding devices to assist the patient with communicating. (Source: www.ninds.nih.gov)
NEW TECHNOLOGY: A new device called noninvasive brain-computer interface (BCI) can allow people who are locked-in to communicate by operating a computer cursor. This type of technology was invented originally to be assistive technology and now it can be used for controlling video games, automating sailboats, robotics, and military tasks. Early studies of the BCI involved implantable sensors. Now the new BCI system can detect the brain's activities through the scalp, from the surface of the brain, and then it can be processed by a computer to extract certain patterns. Patterns are then translated into commands for a device. Technology substitutes for the loss of typical neuromuscular outputs so that people can interact with their environments through brain signals rather than through muscle. (Source:www.ohsu.edu/xd/research)
Aimee R. Mooney, M.S.CCC-SLP/L, Oregon Health & Science University, Brain Institute, talks about a brain computer interface that is helping patients with locked-in-syndrome.
So how long have you been working with Greg?
Ms. Mooney: I have been working with Greg for about three years. Greg has been part of the project for five years.
When you met Greg, what was he like when he first started?
Ms. Mooney: Greg has always had strong opinions and he's got a great sense of humor. Now to the naked eye that might be hard to interpret because Greg has virtually no facial movement and no facial expression. So I've come to learn this through our many interactions. I learned about his communication from his caregivers and through our e-mails together.
How can you tell?
Ms. Mooney: How can I tell? He's hilarious when he sends me e-mails. There's a joke in every one, he teases, and he's really fun.
How important is it that he has a way to communicate?
Ms. Mooney: It's important for each of us. It's essential to be able to communicate, not only your basic wants and needs, but pain and discomfort. Then there's emotion and social closeness. I think communication is essential to all human relationships.
But you see on the other side patients with locked-in-syndrome who just don't have the desire to want to get to the level that Greg is at.
Dr. Mooney: True. So, as you might imagine being locked in could cause severe depression and we do see people that have given up. Typically those who have given up who haven't been given the opportunity to try and learn to communicate.
I was trying to follow him, but it seems exhausting for everyone?
Ms. Mooney: I think it seems that way initially but once you do it, it becomes second nature.
So you're trying to eliminate that so you would not need to communicate that way.
Ms. Mooney: That's right. So the very title of that form of communication is called partner dependent. As with all rehabilitation, we're trying to make people as independent as they can be. So we would like to bypass having somebody else have to be in the room for you to communicate and have you to be able to use a technology where your brain wave is the way that you communicate or changes in your brain wave is the way that you communicate.
So how does that work?
Ms. Mooney: We're using a noninvasive brain computer interface, BCI. What happens is the computer detects changes in your P300, which is one of your brain waves, and that change in the P300 wave is noted basically as a mouse click. A person utilizing the system will have on an electrode cap that is picking up changes or monitoring brain signals. We have something called RSVP, which is rapid serial visual presentation; those are letters that are flashing on a computer screen. So these letters are flashing at two hundred milliseconds. So let's say you wanted to spell the word dog, when your brain sees the letter D in that series of letter your P300 spikes. The electrode cap sends that message to the program in the computer and it chooses D for you. You then see the next series of letters, as they go you see the O, there's no movement in your entire body but again your P300 changes in response to seeing that O. The computer then picks up that and selects O for you. So in that way people can spell on a computer with having no movement.
Does every person with locked-in syndrome have that ability to change their brain wave?
Ms. Mooney: Yes, every human being has a P300 that is responsive to novel stimuli. People's P300s may change as they age, and there are medications that affect your P300. Of course being fatigued affects your P300. There are factors that contribute to a less precise P300 change, but for the most part we think we can get an accurate P300 response in most patients.
Right now it's a little cumbersome because you have to have the cap on and all the electrodes, where is this technology going in the future?
Ms. Mooney: Our goal for the future is to use dry electrodes instead of wet. So right now you observed last night with Greg, they were inserting conducting gel. So we are hoping to go to an electrode system that does not need a gel at all.
Would it have to have that many electrodes?
Ms. Mooney: Probably.
Could it be attached to the cap where you just have someone put the cap on?
Dr. Mooney: Yes there are electrode caps right now that are dry electrode caps that you just put on and you can use. The engineering team still needs to do a lot of work to try and cut out some of the electrical artifacts. A lot of people that who have locked-in syndrome are on respirators or surrounded by other medical machinery that gives off a lot of electrical energy. So we have to still work on filtering out that electrical energy so our P300 signal is very clear.
So it can take a while, but you had mentioned that maybe in the future there might be words that they can choose from instead letters?
Ms. Mooney: Absolutely. It's like when you're using text entry on your smart phone and you start to type in something and up pops a word that would be the goal. The goal is to have words selection and word completion as part of the BCI. Our BCI project is using word prediction (similar to cell phones) in the background when a letter is chosen. Soon the RSVP Keyboard will have full sentences being typed and word prediction will appear on the screen as well.
When do you see this getting out there to people?
Ms. Mooney: Well it sounds like it's a long ways off, but I think we're still probably seven to eight years for this to be a reality for most patients with locked in syndrome. It doesn't mean it's not coming sooner than that. There's still so much to make it user friendly in the home, easier for people to access, and affordable for people.
It could be used for a lot more than just locked in?
Ms. Mooney: What's interesting about our research here at Oregon Health and Science University is that we use a definition of functionally locked in. So these are people that have a variety of diagnoses, even end stage ALS, severe Parkinson's disease, severe MS, and severe spinal cord injury. They may have vertical eye movement and maybe some other small motor movement, maybe a tilt of the chin where they could use a switch but it's not consistent. So our research is opening up to multiple diagnoses where people are what we're calling functionally locked in. They don't have that definition of classic locked in where all they have is eye movement, but their other motor movement is not reliable or efficient for communication. There are many more diagnoses, such as muscular dystrophy, multiple system atrophy, progressive supra-nuclear palsy, just to name a few, where individuals could benefit from a BCI interface as one way for them to control their environment, their computers and communicate. We want to open up the BCI technology to a much larger group of people.
I think the hardest part is people think when you're locked in, that you're not intelligent.
Ms. Mooney. Right. Most diagnoses that I'm talking about retain excellent cognitive function. I'll give the example of ALS, Lou Gehrig's disease. Even in the end stages there have been multiple studies that show that people can retain excellent thinking skills but they have lost their motor ability to use their speech. So they have intact cognitive skills but almost an inability to communicate their thoughts and feelings.
Do you think there are still a lot of people out there who are locked in that have been diagnosed as brain dead?
Ms. Mooney: Oh absolutely, yes.
How else can you see BCI helping?
Ms. Mooney: Again there are so many different circumstances where we can see this helping. The ICU or even a step down unit in a hospital where people are coming out of coma and regaining consciousness, the BCI has some utilization there. So we're very proud that Oregon Health and Science University Brain Institute partnered with Northeastern University to bring this BCI technology to fruition. Something that is unique about our research is that we do include people who have the condition on our research team. Greg is part of our team here; he comes to a meeting every six weeks and gives his feedback on the development of this technology. That's called participatory action research and we're very enthusiastic to have people like Greg on our team who are really committed to moving this research forward.
Has Greg told you anything that you used for developing?
Ms. Mooney: Absolutely, Greg has a preference for the color of the letters in the RSVP. There were engineers that were kind of playing around with changing the colors and Greg had a very definitive opinion on that. He's given us feedback about the screen being too busy when we tried to put part of the message up in one corner and part in another. So we absolutely take what Greg says and try and put it in to effect in the program.
Do you have other participants other than Greg?
Ms. Mooney: Well we have eleven and I think three have been part of the team giving input. Community base was the other thing that we go out to people's homes and they don't have to come here.
FOR MORE INFORMATION, PLEASE CONTACT:
Todd Murphy Senior Communications Specialist Oregon Health & Science University (503) 494-8231 firstname.lastname@example.org
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