Brain patterns can predict speech of words and syllables

Neurons in the brain’s motor cortex previously thought of as active mainly during hand and arm movements also light up during speech in a way that is similar to patterns of brain activity linked to these movements, suggest new findings published today in eLife.

By demonstrating that it is possible to identify different syllables or words from patterns of neural activity, the study provides insights that could potentially be used to restore the voice in people who have lost the ability to speak.

Speaking involves some of the most precise and coordinated movements humans make. Studying it is fascinating but challenging, because there are few opportunities to make measurements from inside someone’s brain while they speak. This study took place as part of the BrainGate2 Brain-Computer Interface pilot clinical trial*, which is testing a computer device that can ‘communicate’ with the brain, helping to restore communication and provide control of prosthetics such as robotic arms.

The researchers studied speech by recording brain activity from multi-electrode arrays previously placed in the motor cortex of two people taking part in BrainGate 2 study. This allowed them to study the timing and location of the firing of a large population of neurons that is activated during speech, rather than just a few at a time.

“We first asked if neurons in the so-called ‘hand knob’ area of the brain’s motor cortex are active during speaking,” explains lead author Sergey Stavisky, Postdoctoral Research Fellow in the Department of Neurosurgery and the Wu Tsai Neurosciences Institute at Stanford University, US. “This seemed unlikely because this is an area known to control hand and arm movements, not speech. But clues in the scientific literature suggested there might be an overlap.”

To test this, the team recorded neural activity from participants during a speaking task where they heard one of 10 different syllables, or one of 10 different short words, and then spoke the prompted sound after hearing a ‘go’ cue. The firing rates of neurons changed strongly during their speaking of words and syllables and the active neurons were spread throughout the part of motor cortex that the researchers were recording from. Moreover, the firing rates did not change as much when the participants heard the sound, only when they spoke it. This change in neuron activity also corresponded to groups of similar sounds, called phonemes, and with face and mouth movements. This suggests that although there is high-level separation of control of different body parts across the motor cortex, activity of the individual neurons overlaps.

Next, the team performed a ‘decoding’ analysis to see whether the neuron-firing patterns could reveal information about the specific sound being spoken. They found that by analysing neural activity across nearly 200 electrodes, they could identify which of several syllables or words the participant was saying. In fact, certain patterns of neuron activity could correctly predict the sound, or lack of sound, in more than 80% of cases for one of the participants, and between 55% and 61% of cases for the other.

“This suggests it might be possible to use this brain activity to understand what words people who cannot speak are trying to say,” says co-senior author Krishna Shenoy, Howard Hughes Medical Institute Investigator and Hong Seh and Vivian W. M. Lim Professor in the School of Engineering, and Co-Director of the Neural Prosthetics Translational Laboratory (NPTL), at Stanford University.

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