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High-performance brain-to-text communication via handwriting

Author

Listed:
  • Francis R. Willett

    (Howard Hughes Medical Institute at Stanford University
    Stanford University School of Medicine
    Stanford University)

  • Donald T. Avansino

    (Howard Hughes Medical Institute at Stanford University)

  • Leigh R. Hochberg

    (Rehabilitation R&D Service, Providence VA Medical Center
    Brown University
    Brown University
    Harvard Medical School)

  • Jaimie M. Henderson

    (Stanford University School of Medicine
    Stanford University
    Stanford University)

  • Krishna V. Shenoy

    (Howard Hughes Medical Institute at Stanford University
    Stanford University
    Stanford University
    Stanford University)

Abstract

Brain–computer interfaces (BCIs) can restore communication to people who have lost the ability to move or speak. So far, a major focus of BCI research has been on restoring gross motor skills, such as reaching and grasping1–5 or point-and-click typing with a computer cursor6,7. However, rapid sequences of highly dexterous behaviours, such as handwriting or touch typing, might enable faster rates of communication. Here we developed an intracortical BCI that decodes attempted handwriting movements from neural activity in the motor cortex and translates it to text in real time, using a recurrent neural network decoding approach. With this BCI, our study participant, whose hand was paralysed from spinal cord injury, achieved typing speeds of 90 characters per minute with 94.1% raw accuracy online, and greater than 99% accuracy offline with a general-purpose autocorrect. To our knowledge, these typing speeds exceed those reported for any other BCI, and are comparable to typical smartphone typing speeds of individuals in the age group of our participant (115 characters per minute)8. Finally, theoretical considerations explain why temporally complex movements, such as handwriting, may be fundamentally easier to decode than point-to-point movements. Our results open a new approach for BCIs and demonstrate the feasibility of accurately decoding rapid, dexterous movements years after paralysis.

Suggested Citation

  • Francis R. Willett & Donald T. Avansino & Leigh R. Hochberg & Jaimie M. Henderson & Krishna V. Shenoy, 2021. "High-performance brain-to-text communication via handwriting," Nature, Nature, vol. 593(7858), pages 249-254, May.
  • Handle: RePEc:nat:nature:v:593:y:2021:i:7858:d:10.1038_s41586-021-03506-2
    DOI: 10.1038/s41586-021-03506-2
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    Cited by:

    1. Joshua Kosnoff & Kai Yu & Chang Liu & Bin He, 2024. "Transcranial focused ultrasound to V5 enhances human visual motion brain-computer interface by modulating feature-based attention," Nature Communications, Nature, vol. 15(1), pages 1-18, December.
    2. Shanqing Cai & Subhashini Venugopalan & Katie Seaver & Xiang Xiao & Katrin Tomanek & Sri Jalasutram & Meredith Ringel Morris & Shaun Kane & Ajit Narayanan & Robert L. MacDonald & Emily Kornman & Danie, 2024. "Using large language models to accelerate communication for eye gaze typing users with ALS," Nature Communications, Nature, vol. 15(1), pages 1-18, December.
    3. Jeffrey D. Laurence-Chasen & Callum F. Ross & Fritzie I. Arce-McShane & Nicholas G. Hatsopoulos, 2023. "Robust cortical encoding of 3D tongue shape during feeding in macaques," Nature Communications, Nature, vol. 14(1), pages 1-10, December.
    4. Zhouheng Wang & Nanlin Shi & Yingchao Zhang & Ning Zheng & Haicheng Li & Yang Jiao & Jiahui Cheng & Yutong Wang & Xiaoqing Zhang & Ying Chen & Yihao Chen & Heling Wang & Tao Xie & Yijun Wang & Yinji M, 2023. "Conformal in-ear bioelectronics for visual and auditory brain-computer interfaces," Nature Communications, Nature, vol. 14(1), pages 1-11, December.

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