Long-term unsupervised recalibration of cursor BCIs

Wilson, Guy H; Willett, Francis R.; Stein, Elias A; Kamdar, Foram; Avansino, Donald T.; Hochberg, Leigh R.; Shenoy, Krishna V.; Druckmann, Shaul; Henderson, Jaimie M.

doi:10.1101/2023.02.03.527022

Cited by 8 publications

(14 citation statements)

References 53 publications

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“…To first establish a baseline for decoder performance, we deployed fixed decoders 27,51 for the purpose of identifying, over a comparatively long period, how neural instabilities may lead to deteriorating control. Data were collected from 15 consecutive research sessions spanning 142 days of T11 performing a center-out-and-back task using a fixed nonlinear (recurrent neural network) decoder, as previously described 51 (see Methods).…”

Section: Fixed Decoders Results In Initially Stable and Then Unstable...mentioning

confidence: 99%

“…The type and magnitude of model drift results in various forms of performance degradation 19 , sometimes necessitating decoder recalibration to restore control. Existing solutions to reduce the need for recalibration tasks include adaptive decoders that require shorter recalibration sessions to maintain or restore stable performance 3,10,42 , self-supervised recalibration using retrospective labeling that avoids explicit recalibration sessions 26,27,43,44 , and robust decoders that experience less model drift by extracting stable, time-invariant features from high-dimensional recordings [20][21][22][45][46][47][48][49][50][51] or by adaptively adjusting decoder parameters 12,52 .…”

Section: Introductionmentioning

confidence: 99%

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Measuring instability in chronic human intracortical neural recordings towards stable, long-term brain-computer interfaces

Pun,

Khoshnevis,

Hosman

et al. 2024

Preprint

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Intracortical brain-computer interfaces (iBCIs) enable people with tetraplegia to gain intuitive cursor control from movement intentions. To translate to practical use, iBCIs should provide reliable performance for extended periods of time. However, performance begins to degrade as the relationship between kinematic intention and recorded neural activity shifts compared to when the decoder was initially trained. In addition to developing decoders to better handle long-term instability, identifying when to recalibrate will also optimize performance. We propose a method to measure instability in neural data without needing to label user intentions. Longitudinal data were analyzed from two BrainGate2 participants with tetraplegia as they used fixed decoders to control a computer cursor spanning 142 days and 28 days, respectively. We demonstrate a measure of instability that correlates with changes in closed-loop cursor performance solely based on the recorded neural activity (Pearson r = 0.93 and 0.72, respectively). This result suggests a strategy to infer online iBCI performance from neural data alone and to determine when recalibration should take place for practical long-term use.

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Section: Fixed Decoders Results In Initially Stable and Then Unstable...mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Measuring instability in chronic human intracortical neural recordings towards stable, long-term brain-computer interfaces

Pun,

Khoshnevis,

Hosman

et al. 2024

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…Although high performance was achieved using this decoding system, potential improvements to increase the likelihood of clinical adoption include reducing the calibration times and increasing the robustness to neural instabilities. Several approaches could be applied to this decoding system, including rapid decoder calibration 35 , training decoders using a long history of previously recorded data 36 , adaptive decoders using task knowledge 37,38 , and algorithms that perform dimensionality reduction to a stable manifold followed by realignment 39,40 .…”

Section: Discussionmentioning

confidence: 99%

A real-time, high-performance brain-computer interface for finger decoding and quadcopter control

Willsey,

Shah,

Avansino

et al. 2024

Preprint

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People with paralysis express unmet needs for peer support, leisure activities, and sporting activities. Many within the general population rely on social media and massively multiplayer video games to address these needs. We developed a high-performance finger brain-computer-interface system allowing continuous control of 3 independent finger groups with 2D thumb movements. The system was tested in a human research participant over sequential trials requiring fingers to reach and hold on targets, with an average acquisition rate of 76 targets/minute and completion time of 1.58 ± 0.06 seconds. Performance compared favorably to previous animal studies, despite a 2-fold increase in the decoded degrees-of-freedom (DOF). Finger positions were then used for 4-DOF velocity control of a virtual quadcopter, demonstrating functionality over both fixed and random obstacle courses. This approach shows promise for controlling multiple-DOF end-effectors, such as robotic fingers or digital interfaces for work, entertainment, and socialization.

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“…Without mapping that range, BCIs based on neural data pretraining alone will need continuous supervision. This is still a practical path forward: beyond explicit calibration phases, strategies for supervising BCIs are diverse, and can derive from user feedback [59], neural error signals [60, 61], or task-based estimation of user intent [62, 57, 63]. The ambition of pretrained BCI models, with broad paired coverage of the neural-behavior domain will be challenging given the experimental costs of data collection; the field of robotics suggests that scaled offline or simulated learning are important strategies given this expense.…”

Section: Discussionmentioning

confidence: 99%

“…The ambition of pretrained BCI models, with broad paired coverage of the neural-behavior domain will be challenging given the experimental costs of data collection; the field of robotics suggests that scaled offline or simulated learning are important strategies given this expense. Since we lack convincing closed-loop neural data simulators (though see [64, 62]), understanding how to leverage behavior from existing heterogeneous datasets is an important next step.…”

Section: Discussionmentioning

confidence: 99%

Neural Data Transformer 2: Multi-context Pretraining for Neural Spiking Activity

Ye,

Collinger,

Wehbe

et al. 2023

Preprint

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The neural population spiking activity recorded by intracortical brain-computer interfaces (iBCIs) contain rich structure. Current models of such spiking activity are largely prepared for individual experimental contexts, restricting data volume to that collectable within a single session and limiting the effectiveness of deep neural networks (DNNs). The purported challenge in aggregating neural spiking data is the pervasiveness of context-dependent shifts in the neural data distributions. However, large scale unsupervised pretraining by nature spans heterogeneous data, and has proven to be a fundamental recipe for successful representation learning across deep learning. We thus develop Neural Data Transformer 2 (NDT2), a spatiotemporal Transformer for neural spiking activity, and demonstrate that pretraining can leverage motor BCI datasets that span sessions, subjects, and experimental tasks. NDT2 enables rapid adaptation to novel contexts in downstream decoding tasks and opens the path to deployment of pretrained DNNs for iBCI control. Code: https://github.com/joel99/context_general_bci .

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Long-term unsupervised recalibration of cursor BCIs

Cited by 8 publications

References 53 publications

Measuring instability in chronic human intracortical neural recordings towards stable, long-term brain-computer interfaces

Measuring instability in chronic human intracortical neural recordings towards stable, long-term brain-computer interfaces

A real-time, high-performance brain-computer interface for finger decoding and quadcopter control

Neural Data Transformer 2: Multi-context Pretraining for Neural Spiking Activity

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