News — A new brain-computer interface (BCI) developed at UC Davis Health translates brain signals into speech with up to 97% accuracy — the most accurate system of its kind.
The researchers implanted sensors in the brain of a man with severely impaired speech due to . The man was able to communicate his intended speech within minutes of activating the system.
A study about this work in the New England Journal of Medicine.
ALS, also known as Lou Gehrig's disease, affects the nerve cells that control movement throughout the body. The disease leads to a gradual loss of the ability to stand, walk and use one’s hands. It can also cause a person to lose control of the muscles used to speak, leading to a loss of understandable speech.
The new technology is being developed to restore communication for people who can’t speak due to paralysis or neurological conditions like ALS. It can interpret brain signals when the user tries to speak and turns them into text that is ‘spoken’ aloud by the computer.
“Our BCI technology helped a man with paralysis to communicate with friends, families and caregivers,” said UC Davis neurosurgeon . “Our paper demonstrates the most accurate speech neuroprosthesis (device) ever reported.”
Brandman is the co-principal investigator and co-senior author of this study. He is an assistant professor in the UC Davis and co-director of the .
The new BCI breaks the communication barrier
When someone tries to speak, the new BCI device transforms their brain activity into text on a computer screen. The computer can then read the text out loud.
To develop the system, the team enrolled Casey Harrell, a 45-year-old man with ALS, in the . At the time of his enrollment, Harrell had weakness in his arms and legs (). His speech was very hard to understand () and required others to help interpret for him.
In July 2023, Brandman implanted the investigational BCI device. He placed four microelectrode arrays into the left precentral gyrus, a brain region responsible for coordinating speech. The arrays are designed to record the brain activity from 256 cortical electrodes.
“We’re really detecting their attempt to move their muscles and talk,” explained neuroscientist . Stavisky is an assistant professor in the . He is the co-director of the and co-principal investigator of the study. “We are recording from the part of the brain that’s trying to send these commands to the muscles. And we are basically listening into that, and we’re translating those patterns of brain activity into a — like a syllable or the unit of speech — and then the words they’re trying to say.”
Faster training, better results
Despite recent advances in BCI technology, efforts to enable communication have been slow and prone to errors. This is because the machine-learning programs that interpreted brain signals required a large amount of time and data to perform.
“Previous speech BCI systems had frequent word errors. This made it difficult for the user to be understood consistently and was a barrier to communication,” Brandman explained. “Our objective was to develop a system that empowered someone to be understood whenever they wanted to speak.”
Harrell used the system in both prompted and spontaneous conversational settings. In both cases, speech decoding happened in real time, with continuous system updates to keep it working accurately.
The decoded words were shown on a screen. Amazingly, they were read aloud in a voice that sounded like Harrell’s before he had ALS. The voice was composed using software trained with existing audio samples of his pre-ALS voice.
At the first speech data training session, the system took 30 minutes to achieve 99.6% word accuracy with a 50-word vocabulary.
“The first time we tried the system, he cried with joy as the words he was trying to say correctly appeared on-screen. We all did,” Stavisky said.
In the second session, the size of the potential vocabulary increased to 125,000 words. With just an additional 1.4 hours of training data, the BCI achieved a 90.2% word accuracy with this greatly expanded vocabulary. After continued data collection, the BCI has maintained 97.5% accuracy.
“At this point, we can decode what Casey is trying to say correctly about 97% of the time, which is better than many commercially available smartphone applications that try to interpret a person’s voice,” Brandman said. “This technology is transformative because it provides hope for people who want to speak but can’t. I hope that technology like this speech BCI will help future patients speak with their family and friends.”
The study reports on 84 data collection sessions over 32 weeks. In total, Harrell used the speech BCI in self-paced conversations for over 248 hours to communicate in person and over video chat.
“Not being able to communicate is so frustrating and demoralizing. It is like you are trapped,” Harrell said. “Something like this technology will help people back into life and society.”
“It has been immensely rewarding to see Casey regain his ability to speak with his family and friends through this technology,” said the study’s lead author, . Card is a postdoctoral scholar in the UC Davis Department of Neurological Surgery.
“Casey and our other BrainGate participants are truly extraordinary. They deserve tremendous credit for joining these early clinical trials. They do this not because they’re hoping to gain any personal benefit, but to help us develop a system that will restore communication and mobility for other people with paralysis,” said co-author and BrainGate trial sponsor-investigator . Hochberg is a neurologist and neuroscientist at Massachusetts General Hospital, Brown University and the VA Providence Healthcare System.
Brandman is the site-responsible principal investigator of the BrainGate2 clinical trial. The trial is enrolling participants. To learn more about the study, visit braingate.org or contact [email protected].
A complete list of coauthors and funders is available .
Caution: Investigational device. Limited by Federal law to investigational use.
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; ALS Pilot Clinical Trial Award (AL220043); New Innovator Award (NIH 1DP2DC021055); Simons Collaboration for the Global Brain (872146SPI); National Institute on Deafness and Other Communication Disorders (NIH U01DC017844); Department of Veterans Affairs (A2295-R); Howard Hughes Medical Institute,; Wu Tsai Neurosciences Institute; the A.P. Giannini Foundation; Searle Scholar Program; Burroughs Wellcome Fund; University of California, Davis