Few-shot Algorithms for Consistent Neural Decoding (FALCON) Benchmark

Brianna M. Karpowicz; Joel Ye; Chaofei Fan; Pablo Tostado-Marcos; Fabio Rizzoglio; Clay Washington; Thiago Scodeler; Diogo de Lucena; Samuel R. Nason-Tomaszewski; Matthew J. Mender; Xuan Ma; Ezequiel Matias Arneodo; Leigh R. Hochberg; Cynthia A. Chestek; Jaimie M. Henderson; Timothy Q. Gentner; Vikash Gilja; Lee E. Miller; Adam G. Rouse; Robert A. Gaunt; Jennifer L. Collinger; Chethan Pandarinath

Few-shot Algorithms for Consistent Neural Decoding (FALCON) Benchmark

Brianna M. Karpowicz, Joel Ye, Chaofei Fan, Pablo Tostado-Marcos, Fabio Rizzoglio, Clay Washington, Thiago Scodeler, Diogo de Lucena, Samuel R. Nason-Tomaszewski, Matthew J. Mender, Xuan Ma, Ezequiel Matias Arneodo, Leigh R. Hochberg, Cynthia A. Chestek, Jaimie M. Henderson, Timothy Q. Gentner, Vikash Gilja, Lee E. Miller, Adam G. Rouse, Robert A. GauntJennifer L. Collinger, Chethan Pandarinath^*

^*Corresponding author for this work

Neuroscience

Research output: Contribution to journal › Conference article › peer-review

Abstract

Intracortical brain-computer interfaces (iBCIs) can restore movement and communication abilities to individuals with paralysis by decoding their intended behavior from neural activity recorded with an implanted device. While this activity yields high-performance decoding over short timescales, neural data are often nonstationary, which can lead to decoder failure if not accounted for. To maintain performance, users must frequently recalibrate decoders, which requires the arduous collection of new neural and behavioral data. Aiming to reduce this burden, several approaches have been developed that either limit recalibration data requirements (few-shot approaches) or eliminate explicit recalibration entirely (zero-shot approaches). However, progress is limited by a lack of standardized datasets and comparison metrics, causing methods to be compared in an ad hoc manner. Here we introduce the FALCON benchmark suite (Few-shot Algorithms for COnsistent Neural decoding) to standardize evaluation of iBCI robustness. FALCON curates five datasets of neural and behavioral data that span movement and communication tasks to focus on behaviors of interest to modern-day iBCIs. Each dataset includes calibration data, optional few-shot recalibration data, and private evaluation data. We implement a flexible evaluation platform which only requires user-submitted code to return behavioral predictions on unseen data. We also seed the benchmark by applying baseline methods spanning several classes of possible approaches. FALCON aims to provide rigorous selection criteria for robust iBCI decoders, easing their translation to real-world devices. https://snel-repo.github.io/falcon/.

Original language	English (US)
Journal	Advances in Neural Information Processing Systems
Volume	37
State	Published - 2024
Event	38th Conference on Neural Information Processing Systems, NeurIPS 2024 - Vancouver, Canada Duration: Dec 9 2024 → Dec 15 2024

Funding

This work was supported by: Department of Veterans Affairs, Wu Tsai Neurosciences Institute, NIH-NIDCD U01DC017844, NIH-NIDCD R01DC014034, NIH-NIBIB R01EB028171 (CF); NIH National Institute on Deafness and Other Communication Disorders (grants R01DC018446 and R01DC008358), the NSF Emerging Frontiers in Research and Innovation (EFRI) - Brain-Inspired Dynamics for Engineering Energy-Efficient Circuits and Artificial Intelligence (BRAID) (grant 2223822) and the Kavli Institute for Brain and Mind (IRG no. 2021-1759), \"La Caixa\" Foundation, and the IIE Fulbright Fellowship (PTM); R21 NS135413-01 (FR); NIH F32HD112173 (SRN); Kavli Institute for the Brain and Mind Innovative Research Grant 2021-1759 and Pew Latin American Fellowship in the Biomedical Sciences (EMA); NSF-NCS Grant 1926576 (CC); Office of Research and Development, Rehabilitation R&D Service, Department of Veterans Affairs (N2864C, A2295R), Wu Tsai Neurosciences Institute, Howard Hughes Medical Institute, Larry and Pamela Garlick, Samuel and Betsy Reeves, Sons Foundation Collaboration on the Global Brain 543045, NIDCD R01-DC014034, NIDCD U01-DC017844, NINDS UH2-NS095548, NINDS U01-NS098968 (JMH); NIDCD R01DC018446 (TQG); NSF EFRI BRAID 2223822 and NIH NIDCD R01DC018446 (VG); NINDS R01 NS079664, NINDS K99/R00 NS101127 (AGR); NINDS UH3NS107714, NINDS U01NS108922, DARPA N66001-10-C-4056 (RAG); the Defense Advanced Research Projects Agency (DARPA) and Space and Naval Warfare Systems Center Pacific (SSC Pacific) under Contracts N66001-10-C-4056 and N66001-16-C-4051 (JLC); NIH-NINDS/OD DP2NS127291 (CP). Any opinions, findings and conclusions or recommendations expressed in this material are those of the authors and do not necessarily reflect the views of DARPA, SSC Pacific, the National Institutes of Health, the Department of Veterans Affairs, or the United States Government. The authors would like to thank BrainGate clinical trial participant T5, Rehab Neural Engineering Labs clinical study participants, and their families and care partners for their contributions to this research. We would like to thank Beverly Davis, Kathy Tsou, and Sandrin Kosasih for administrative support. We thank Eric Kennedy for animal and experimental support. We thank Gail Rising, Amber Yanovich, Lisa Burlingame, Patrick Lester, Veronica Dunivant, Laura Durham, Taryn Hetrick, Helen Noack, Deanna Renner, Michael Bradley, Goldia Chan, Kelsey Cornelius, Courtney Hunter, Lauren Krueger, Russell Nichols, Brooke Pallas, Catherine Si, Anna Skorupski, Jessica Xu, and Jibing Yang for expert surgical assistance and veterinary care. We thank Marc Schieber for support of original M1 data collection. We thank Gunjan Chhablani and the EvalAI team for support in developing the FALCON evaluation infrastructure.

ASJC Scopus subject areas

Computer Networks and Communications
Information Systems
Signal Processing

Cite this

Karpowicz, B. M., Ye, J., Fan, C., Tostado-Marcos, P., Rizzoglio, F., Washington, C., Scodeler, T., de Lucena, D., Nason-Tomaszewski, S. R., Mender, M. J., Ma, X., Arneodo, E. M., Hochberg, L. R., Chestek, C. A., Henderson, J. M., Gentner, T. Q., Gilja, V., Miller, L. E., Rouse, A. G., ... Pandarinath, C. (2024). Few-shot Algorithms for Consistent Neural Decoding (FALCON) Benchmark. Advances in Neural Information Processing Systems, 37.

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title = "Few-shot Algorithms for Consistent Neural Decoding (FALCON) Benchmark",

abstract = "Intracortical brain-computer interfaces (iBCIs) can restore movement and communication abilities to individuals with paralysis by decoding their intended behavior from neural activity recorded with an implanted device. While this activity yields high-performance decoding over short timescales, neural data are often nonstationary, which can lead to decoder failure if not accounted for. To maintain performance, users must frequently recalibrate decoders, which requires the arduous collection of new neural and behavioral data. Aiming to reduce this burden, several approaches have been developed that either limit recalibration data requirements (few-shot approaches) or eliminate explicit recalibration entirely (zero-shot approaches). However, progress is limited by a lack of standardized datasets and comparison metrics, causing methods to be compared in an ad hoc manner. Here we introduce the FALCON benchmark suite (Few-shot Algorithms for COnsistent Neural decoding) to standardize evaluation of iBCI robustness. FALCON curates five datasets of neural and behavioral data that span movement and communication tasks to focus on behaviors of interest to modern-day iBCIs. Each dataset includes calibration data, optional few-shot recalibration data, and private evaluation data. We implement a flexible evaluation platform which only requires user-submitted code to return behavioral predictions on unseen data. We also seed the benchmark by applying baseline methods spanning several classes of possible approaches. FALCON aims to provide rigorous selection criteria for robust iBCI decoders, easing their translation to real-world devices. https://snel-repo.github.io/falcon/.",

author = "Karpowicz, {Brianna M.} and Joel Ye and Chaofei Fan and Pablo Tostado-Marcos and Fabio Rizzoglio and Clay Washington and Thiago Scodeler and {de Lucena}, Diogo and Nason-Tomaszewski, {Samuel R.} and Mender, {Matthew J.} and Xuan Ma and Arneodo, {Ezequiel Matias} and Hochberg, {Leigh R.} and Chestek, {Cynthia A.} and Henderson, {Jaimie M.} and Gentner, {Timothy Q.} and Vikash Gilja and Miller, {Lee E.} and Rouse, {Adam G.} and Gaunt, {Robert A.} and Collinger, {Jennifer L.} and Chethan Pandarinath",

note = "Publisher Copyright: {\textcopyright} 2024 Neural information processing systems foundation. All rights reserved.; 38th Conference on Neural Information Processing Systems, NeurIPS 2024 ; Conference date: 09-12-2024 Through 15-12-2024",

year = "2024",

language = "English (US)",

volume = "37",

journal = "Advances in Neural Information Processing Systems",

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Karpowicz, BM, Ye, J, Fan, C, Tostado-Marcos, P, Rizzoglio, F, Washington, C, Scodeler, T, de Lucena, D, Nason-Tomaszewski, SR, Mender, MJ, Ma, X, Arneodo, EM, Hochberg, LR, Chestek, CA, Henderson, JM, Gentner, TQ, Gilja, V, Miller, LE, Rouse, AG, Gaunt, RA, Collinger, JL & Pandarinath, C 2024, 'Few-shot Algorithms for Consistent Neural Decoding (FALCON) Benchmark', Advances in Neural Information Processing Systems, vol. 37.

TY - JOUR

T1 - Few-shot Algorithms for Consistent Neural Decoding (FALCON) Benchmark

AU - Karpowicz, Brianna M.

AU - Ye, Joel

AU - Fan, Chaofei

AU - Tostado-Marcos, Pablo

AU - Rizzoglio, Fabio

AU - Washington, Clay

AU - Scodeler, Thiago

AU - de Lucena, Diogo

AU - Nason-Tomaszewski, Samuel R.

AU - Mender, Matthew J.

AU - Ma, Xuan

AU - Arneodo, Ezequiel Matias

AU - Hochberg, Leigh R.

AU - Chestek, Cynthia A.

AU - Henderson, Jaimie M.

AU - Gentner, Timothy Q.

AU - Gilja, Vikash

AU - Miller, Lee E.

AU - Rouse, Adam G.

AU - Gaunt, Robert A.

AU - Collinger, Jennifer L.

AU - Pandarinath, Chethan

PY - 2024

Y1 - 2024

N2 - Intracortical brain-computer interfaces (iBCIs) can restore movement and communication abilities to individuals with paralysis by decoding their intended behavior from neural activity recorded with an implanted device. While this activity yields high-performance decoding over short timescales, neural data are often nonstationary, which can lead to decoder failure if not accounted for. To maintain performance, users must frequently recalibrate decoders, which requires the arduous collection of new neural and behavioral data. Aiming to reduce this burden, several approaches have been developed that either limit recalibration data requirements (few-shot approaches) or eliminate explicit recalibration entirely (zero-shot approaches). However, progress is limited by a lack of standardized datasets and comparison metrics, causing methods to be compared in an ad hoc manner. Here we introduce the FALCON benchmark suite (Few-shot Algorithms for COnsistent Neural decoding) to standardize evaluation of iBCI robustness. FALCON curates five datasets of neural and behavioral data that span movement and communication tasks to focus on behaviors of interest to modern-day iBCIs. Each dataset includes calibration data, optional few-shot recalibration data, and private evaluation data. We implement a flexible evaluation platform which only requires user-submitted code to return behavioral predictions on unseen data. We also seed the benchmark by applying baseline methods spanning several classes of possible approaches. FALCON aims to provide rigorous selection criteria for robust iBCI decoders, easing their translation to real-world devices. https://snel-repo.github.io/falcon/.

AB - Intracortical brain-computer interfaces (iBCIs) can restore movement and communication abilities to individuals with paralysis by decoding their intended behavior from neural activity recorded with an implanted device. While this activity yields high-performance decoding over short timescales, neural data are often nonstationary, which can lead to decoder failure if not accounted for. To maintain performance, users must frequently recalibrate decoders, which requires the arduous collection of new neural and behavioral data. Aiming to reduce this burden, several approaches have been developed that either limit recalibration data requirements (few-shot approaches) or eliminate explicit recalibration entirely (zero-shot approaches). However, progress is limited by a lack of standardized datasets and comparison metrics, causing methods to be compared in an ad hoc manner. Here we introduce the FALCON benchmark suite (Few-shot Algorithms for COnsistent Neural decoding) to standardize evaluation of iBCI robustness. FALCON curates five datasets of neural and behavioral data that span movement and communication tasks to focus on behaviors of interest to modern-day iBCIs. Each dataset includes calibration data, optional few-shot recalibration data, and private evaluation data. We implement a flexible evaluation platform which only requires user-submitted code to return behavioral predictions on unseen data. We also seed the benchmark by applying baseline methods spanning several classes of possible approaches. FALCON aims to provide rigorous selection criteria for robust iBCI decoders, easing their translation to real-world devices. https://snel-repo.github.io/falcon/.

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M3 - Conference article

AN - SCOPUS:105000503732

SN - 1049-5258

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JO - Advances in Neural Information Processing Systems

JF - Advances in Neural Information Processing Systems

T2 - 38th Conference on Neural Information Processing Systems, NeurIPS 2024

Y2 - 9 December 2024 through 15 December 2024

ER -

Few-shot Algorithms for Consistent Neural Decoding (FALCON) Benchmark

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