Long-term wireless streaming of neural recordings for circuit discovery and adaptive stimulation in individuals with Parkinson’s disease

Ro’ee Gilron; Simon Little; Randy Perrone; Robert Wilt; Coralie de Hemptinne; Maria S. Yaroshinsky; Caroline A. Racine; Sarah S. Wang; Jill L. Ostrem; Paul S. Larson; Doris D. Wang; Nick B. Galifianakis; Ian O. Bledsoe; Marta San Luciano; Heather E. Dawes; Gregory A. Worrell; Vaclav Kremen; David A. Borton; Timothy Denison; Philip A. Starr

doi:10.1038/s41587-021-00897-5

Long-term wireless streaming of neural recordings for circuit discovery and adaptive stimulation in individuals with Parkinson’s disease

Ro’ee Gilron, Simon Little, Randy Perrone, Robert Wilt, Coralie de Hemptinne, Maria S. Yaroshinsky, Caroline A. Racine, Sarah S. Wang, Jill L. Ostrem, Paul S. Larson, Doris D. Wang, Nick B. Galifianakis, Ian O. Bledsoe, Marta San Luciano, Heather E. Dawes, Gregory A. Worrell, Vaclav Kremen, David A. Borton, Timothy Denison, Philip A. Starr

Neurology

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

Abstract

Neural recordings using invasive devices in humans can elucidate the circuits underlying brain disorders, but have so far been limited to short recordings from externalized brain leads in a hospital setting or from implanted sensing devices that provide only intermittent, brief streaming of time series data. Here, we report the use of an implantable two-way neural interface for wireless, multichannel streaming of field potentials in five individuals with Parkinson’s disease (PD) for up to 15 months after implantation. Bilateral four-channel motor cortex and basal ganglia field potentials streamed at home for over 2,600 h were paired with behavioral data from wearable monitors for the neural decoding of states of inadequate or excessive movement. We validated individual-specific neurophysiological biomarkers during normal daily activities and used those patterns for adaptive deep brain stimulation (DBS). This technological approach may be widely applicable to brain disorders treatable by invasive neuromodulation.

Original language	English (US)
Pages (from-to)	1078-1085
Number of pages	8
Journal	Nature biotechnology
Volume	39
Issue number	9
DOIs	https://doi.org/10.1038/s41587-021-00897-5
State	Published - Sep 2021

ASJC Scopus subject areas

Biotechnology
Bioengineering
Applied Microbiology and Biotechnology
Molecular Medicine
Biomedical Engineering

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10.1038/s41587-021-00897-5

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Gilron, R., Little, S., Perrone, R., Wilt, R., de Hemptinne, C., Yaroshinsky, M. S., Racine, C. A., Wang, S. S., Ostrem, J. L., Larson, P. S., Wang, D. D., Galifianakis, N. B., Bledsoe, I. O., San Luciano, M., Dawes, H. E., Worrell, G. A., Kremen, V., Borton, D. A., Denison, T., & Starr, P. A. (2021). Long-term wireless streaming of neural recordings for circuit discovery and adaptive stimulation in individuals with Parkinson’s disease. Nature biotechnology, 39(9), 1078-1085. https://doi.org/10.1038/s41587-021-00897-5

Gilron, R, Little, S, Perrone, R, Wilt, R, de Hemptinne, C, Yaroshinsky, MS, Racine, CA, Wang, SS, Ostrem, JL, Larson, PS, Wang, DD, Galifianakis, NB, Bledsoe, IO, San Luciano, M, Dawes, HE, Worrell, GA, Kremen, V, Borton, DA, Denison, T & Starr, PA 2021, 'Long-term wireless streaming of neural recordings for circuit discovery and adaptive stimulation in individuals with Parkinson’s disease', Nature biotechnology, vol. 39, no. 9, pp. 1078-1085. https://doi.org/10.1038/s41587-021-00897-5

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abstract = "Neural recordings using invasive devices in humans can elucidate the circuits underlying brain disorders, but have so far been limited to short recordings from externalized brain leads in a hospital setting or from implanted sensing devices that provide only intermittent, brief streaming of time series data. Here, we report the use of an implantable two-way neural interface for wireless, multichannel streaming of field potentials in five individuals with Parkinson{\textquoteright}s disease (PD) for up to 15 months after implantation. Bilateral four-channel motor cortex and basal ganglia field potentials streamed at home for over 2,600 h were paired with behavioral data from wearable monitors for the neural decoding of states of inadequate or excessive movement. We validated individual-specific neurophysiological biomarkers during normal daily activities and used those patterns for adaptive deep brain stimulation (DBS). This technological approach may be widely applicable to brain disorders treatable by invasive neuromodulation.",

author = "Ro{\textquoteright}ee Gilron and Simon Little and Randy Perrone and Robert Wilt and {de Hemptinne}, Coralie and Yaroshinsky, {Maria S.} and Racine, {Caroline A.} and Wang, {Sarah S.} and Ostrem, {Jill L.} and Larson, {Paul S.} and Wang, {Doris D.} and Galifianakis, {Nick B.} and Bledsoe, {Ian O.} and {San Luciano}, Marta and Dawes, {Heather E.} and Worrell, {Gregory A.} and Vaclav Kremen and Borton, {David A.} and Timothy Denison and Starr, {Philip A.}",

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AU - de Hemptinne, Coralie

AU - Yaroshinsky, Maria S.

AU - Racine, Caroline A.

AU - Wang, Sarah S.

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AU - Larson, Paul S.

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AU - Galifianakis, Nick B.

AU - Bledsoe, Ian O.

AU - San Luciano, Marta

AU - Dawes, Heather E.

AU - Worrell, Gregory A.

AU - Kremen, Vaclav

AU - Borton, David A.

AU - Denison, Timothy

AU - Starr, Philip A.

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Long-term wireless streaming of neural recordings for circuit discovery and adaptive stimulation in individuals with Parkinson’s disease

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