Author
Listed:
- Sean L. Metzger
(University of California, San Francisco
University of California, San Francisco
University of California, Berkeley–University of California, San Francisco Graduate Program in Bioengineering)
- Kaylo T. Littlejohn
(University of California, San Francisco
University of California, San Francisco
University of California, Berkeley)
- Alexander B. Silva
(University of California, San Francisco
University of California, San Francisco
University of California, Berkeley–University of California, San Francisco Graduate Program in Bioengineering)
- David A. Moses
(University of California, San Francisco
University of California, San Francisco)
- Margaret P. Seaton
(University of California, San Francisco)
- Ran Wang
(University of California, San Francisco
University of California, San Francisco)
- Maximilian E. Dougherty
(University of California, San Francisco)
- Jessie R. Liu
(University of California, San Francisco
University of California, San Francisco
University of California, Berkeley–University of California, San Francisco Graduate Program in Bioengineering)
- Peter Wu
(University of California, Berkeley)
- Michael A. Berger
(Speech Graphics Ltd)
- Inga Zhuravleva
(University of California, Berkeley)
- Adelyn Tu-Chan
(University of California, San Francisco)
- Karunesh Ganguly
(University of California, San Francisco
University of California, San Francisco)
- Gopala K. Anumanchipalli
(University of California, San Francisco
University of California, San Francisco
University of California, Berkeley)
- Edward F. Chang
(University of California, San Francisco
University of California, San Francisco
University of California, Berkeley–University of California, San Francisco Graduate Program in Bioengineering)
Abstract
Speech neuroprostheses have the potential to restore communication to people living with paralysis, but naturalistic speed and expressivity are elusive1. Here we use high-density surface recordings of the speech cortex in a clinical-trial participant with severe limb and vocal paralysis to achieve high-performance real-time decoding across three complementary speech-related output modalities: text, speech audio and facial-avatar animation. We trained and evaluated deep-learning models using neural data collected as the participant attempted to silently speak sentences. For text, we demonstrate accurate and rapid large-vocabulary decoding with a median rate of 78 words per minute and median word error rate of 25%. For speech audio, we demonstrate intelligible and rapid speech synthesis and personalization to the participant’s pre-injury voice. For facial-avatar animation, we demonstrate the control of virtual orofacial movements for speech and non-speech communicative gestures. The decoders reached high performance with less than two weeks of training. Our findings introduce a multimodal speech-neuroprosthetic approach that has substantial promise to restore full, embodied communication to people living with severe paralysis.
Suggested Citation
Sean L. Metzger & Kaylo T. Littlejohn & Alexander B. Silva & David A. Moses & Margaret P. Seaton & Ran Wang & Maximilian E. Dougherty & Jessie R. Liu & Peter Wu & Michael A. Berger & Inga Zhuravleva &, 2023.
"A high-performance neuroprosthesis for speech decoding and avatar control,"
Nature, Nature, vol. 620(7976), pages 1037-1046, August.
Handle:
RePEc:nat:nature:v:620:y:2023:i:7976:d:10.1038_s41586-023-06443-4
DOI: 10.1038/s41586-023-06443-4
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Citations
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Cited by:
- Elisa Donati & Giacomo Valle, 2024.
"Neuromorphic hardware for somatosensory neuroprostheses,"
Nature Communications, Nature, vol. 15(1), pages 1-18, December.
- Sarah K. Wandelt & David A. Bjånes & Kelsie Pejsa & Brian Lee & Charles Liu & Richard A. Andersen, 2024.
"Representation of internal speech by single neurons in human supramarginal gyrus,"
Nature Human Behaviour, Nature, vol. 8(6), pages 1136-1149, June.
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