Collaborative approach in the development of high-performance brain-computer interfaces for a neuroprosthetic arm: Translation from animal models to human control

Jennifer L. Collinger; Michael A. Kryger; Richard Barbara; Timothy Betler; Kristen Bowsher; Elke H.P. Brown; Samuel T. Clanton; Alan D. Degenhart; Stephen T. Foldes; Robert A. Gaunt; Ferenc E. Gyulai; Elizabeth A. Harchick; Deborah Harrington; John B. Helder; Timothy Hemmes; Matthew S. Johannes; Kapil D. Katyal; Geoffrey S.F. Ling; Angus J.C. Mcmorland; Karina Palko; Matthew P. Para; Janet Scheuermann; Andrew B. Schwartz; Elizabeth R. Skidmore; Florian Solzbacher; Anita V. Srikameswaran; Dennis P. Swanson; Scott Swetz; Elizabeth C. Tyler-Kabara; Meel Velliste; Wei Wang; Douglas J. Weber; Brian Wodlinger; Michael L. Boninger

doi:10.1111/cts.12086

Collaborative approach in the development of high-performance brain-computer interfaces for a neuroprosthetic arm: Translation from animal models to human control

Jennifer L. Collinger, Michael A. Kryger, Richard Barbara, Timothy Betler, Kristen Bowsher, Elke H.P. Brown, Samuel T. Clanton, Alan D. Degenhart, Stephen T. Foldes, Robert A. Gaunt, Ferenc E. Gyulai, Elizabeth A. Harchick, Deborah Harrington, John B. Helder, Timothy Hemmes, Matthew S. Johannes, Kapil D. Katyal, Geoffrey S.F. Ling, Angus J.C. Mcmorland, Karina PalkoMatthew P. Para, Janet Scheuermann, Andrew B. Schwartz, Elizabeth R. Skidmore, Florian Solzbacher, Anita V. Srikameswaran, Dennis P. Swanson, Scott Swetz, Elizabeth C. Tyler-Kabara, Meel Velliste, Wei Wang, Douglas J. Weber, Brian Wodlinger, Michael L. Boninger

Research output: Contribution to journal › Article › peer-review

37 Scopus citations

Abstract

Our research group recently demonstrated that a person with tetraplegia could use a brain-computer interface (BCI) to control a sophisticated anthropomorphic robotic arm with skill and speed approaching that of an able-bodied person. This multiyear study exemplifies important principles in translating research from foundational theory and animal experiments into a clinical study. We present a roadmap that may serve as an example for other areas of clinical device research as well as an update on study results. Prior to conducting a multiyear clinical trial, years of animal research preceded BCI testing in an epilepsy monitoring unit, and then in a short-term (28 days) clinical investigation. Scientists and engineers developed the necessary robotic and surgical hardware, software environment, data analysis techniques, and training paradigms. Coordination among researchers, funding institutes, and regulatory bodies ensured that the study would provide valuable scientific information in a safe environment for the study participant. Finally, clinicians from neurosurgery, anesthesiology, physiatry, psychology, and occupational therapy all worked in a multidisciplinary team along with the other researchers to conduct a multiyear BCI clinical study. This teamwork and coordination can be used as a model for others attempting to translate basic science into real-world clinical situations. This article is a U.S. Government work and is in the public domain in the USA.

Original language	English (US)
Pages (from-to)	52-59
Number of pages	8
Journal	Clinical and translational science
Volume	7
Issue number	1
DOIs	https://doi.org/10.1111/cts.12086
State	Published - Feb 2014
Externally published	Yes

Keywords

Brain
Clinical trials
Methodology
Translational research

ASJC Scopus subject areas

General Neuroscience
General Biochemistry, Genetics and Molecular Biology
Pharmacology, Toxicology and Pharmaceutics(all)

Access to Document

10.1111/cts.12086

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Collinger, J. L., Kryger, M. A., Barbara, R., Betler, T., Bowsher, K., Brown, E. H. P., Clanton, S. T., Degenhart, A. D., Foldes, S. T., Gaunt, R. A., Gyulai, F. E., Harchick, E. A., Harrington, D., Helder, J. B., Hemmes, T., Johannes, M. S., Katyal, K. D., Ling, G. S. F., Mcmorland, A. J. C., ... Boninger, M. L. (2014). Collaborative approach in the development of high-performance brain-computer interfaces for a neuroprosthetic arm: Translation from animal models to human control. Clinical and translational science, 7(1), 52-59. https://doi.org/10.1111/cts.12086

Collaborative approach in the development of high-performance brain-computer interfaces for a neuroprosthetic arm: Translation from animal models to human control. / Collinger, Jennifer L.; Kryger, Michael A.; Barbara, Richard et al.
In: Clinical and translational science, Vol. 7, No. 1, 02.2014, p. 52-59.

Research output: Contribution to journal › Article › peer-review

Collinger, JL, Kryger, MA, Barbara, R, Betler, T, Bowsher, K, Brown, EHP, Clanton, ST, Degenhart, AD, Foldes, ST, Gaunt, RA, Gyulai, FE, Harchick, EA, Harrington, D, Helder, JB, Hemmes, T, Johannes, MS, Katyal, KD, Ling, GSF, Mcmorland, AJC, Palko, K, Para, MP, Scheuermann, J, Schwartz, AB, Skidmore, ER, Solzbacher, F, Srikameswaran, AV, Swanson, DP, Swetz, S, Tyler-Kabara, EC, Velliste, M, Wang, W, Weber, DJ, Wodlinger, B & Boninger, ML 2014, 'Collaborative approach in the development of high-performance brain-computer interfaces for a neuroprosthetic arm: Translation from animal models to human control', Clinical and translational science, vol. 7, no. 1, pp. 52-59. https://doi.org/10.1111/cts.12086

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abstract = "Our research group recently demonstrated that a person with tetraplegia could use a brain-computer interface (BCI) to control a sophisticated anthropomorphic robotic arm with skill and speed approaching that of an able-bodied person. This multiyear study exemplifies important principles in translating research from foundational theory and animal experiments into a clinical study. We present a roadmap that may serve as an example for other areas of clinical device research as well as an update on study results. Prior to conducting a multiyear clinical trial, years of animal research preceded BCI testing in an epilepsy monitoring unit, and then in a short-term (28 days) clinical investigation. Scientists and engineers developed the necessary robotic and surgical hardware, software environment, data analysis techniques, and training paradigms. Coordination among researchers, funding institutes, and regulatory bodies ensured that the study would provide valuable scientific information in a safe environment for the study participant. Finally, clinicians from neurosurgery, anesthesiology, physiatry, psychology, and occupational therapy all worked in a multidisciplinary team along with the other researchers to conduct a multiyear BCI clinical study. This teamwork and coordination can be used as a model for others attempting to translate basic science into real-world clinical situations. This article is a U.S. Government work and is in the public domain in the USA.",

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AU - Ling, Geoffrey S.F.

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AU - Schwartz, Andrew B.

AU - Skidmore, Elizabeth R.

AU - Solzbacher, Florian

AU - Srikameswaran, Anita V.

AU - Swanson, Dennis P.

AU - Swetz, Scott

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Collaborative approach in the development of high-performance brain-computer interfaces for a neuroprosthetic arm: Translation from animal models to human control

Abstract

Keywords

ASJC Scopus subject areas

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