Neural prosthetic control signals from plan activity

Krishna V. Shenoy; Daniella Meeker; Shiyan Cao; Sohaib A. Kureshi; Bijan Pesaran; Christopher A. Buneo; Aaron P. Batista; Partha P. Mitra; Joel W. Burdick; Richard A. Andersen

doi:10.1097/00001756-200303240-00013

Neural prosthetic control signals from plan activity

Krishna V. Shenoy, Daniella Meeker, Shiyan Cao, Sohaib A. Kureshi, Bijan Pesaran, Christopher A. Buneo, Aaron P. Batista, Partha P. Mitra, Joel W. Burdick, Richard A. Andersen

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

157 Scopus citations

Abstract

The prospect of assisting disabled patients by translating neural activity from the brain into control signals for prosthetic devices, has flourished in recent years. Current systems rely on neural activity present during natural arm movements. We propose here that neural activity present before or even without natural arm movements can provide an important, and potentially advantageous, source of control signals. To demonstrate how control signals can be derived from such plan activity we performed a computational study with neural activity previously recorded from the posterior parietal cortex of rhesus monkeys planning arm movements. We employed maximum likelihood decoders to estimate movement direction and to drive finite state machines governing when to move. Performance exceeded 90% with as few as 40 neurons.

Original language	English (US)
Pages (from-to)	591-596
Number of pages	6
Journal	NeuroReport
Volume	14
Issue number	4
DOIs	https://doi.org/10.1097/00001756-200303240-00013
State	Published - Mar 2003
Externally published	Yes

Keywords

Bayesian decoders
Brain-computer interfaces
Finite state machines
Maximum likelihood
Neural prosthetic systems
Posterior parietal cortex

ASJC Scopus subject areas

General Neuroscience

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10.1097/00001756-200303240-00013

Cite this

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title = "Neural prosthetic control signals from plan activity",

abstract = "The prospect of assisting disabled patients by translating neural activity from the brain into control signals for prosthetic devices, has flourished in recent years. Current systems rely on neural activity present during natural arm movements. We propose here that neural activity present before or even without natural arm movements can provide an important, and potentially advantageous, source of control signals. To demonstrate how control signals can be derived from such plan activity we performed a computational study with neural activity previously recorded from the posterior parietal cortex of rhesus monkeys planning arm movements. We employed maximum likelihood decoders to estimate movement direction and to drive finite state machines governing when to move. Performance exceeded 90% with as few as 40 neurons.",

keywords = "Bayesian decoders, Brain-computer interfaces, Finite state machines, Maximum likelihood, Neural prosthetic systems, Posterior parietal cortex",

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AU - Shenoy, Krishna V.

AU - Meeker, Daniella

AU - Cao, Shiyan

AU - Kureshi, Sohaib A.

AU - Pesaran, Bijan

AU - Buneo, Christopher A.

AU - Batista, Aaron P.

AU - Mitra, Partha P.

AU - Burdick, Joel W.

AU - Andersen, Richard A.

PY - 2003/3

Y1 - 2003/3

N2 - The prospect of assisting disabled patients by translating neural activity from the brain into control signals for prosthetic devices, has flourished in recent years. Current systems rely on neural activity present during natural arm movements. We propose here that neural activity present before or even without natural arm movements can provide an important, and potentially advantageous, source of control signals. To demonstrate how control signals can be derived from such plan activity we performed a computational study with neural activity previously recorded from the posterior parietal cortex of rhesus monkeys planning arm movements. We employed maximum likelihood decoders to estimate movement direction and to drive finite state machines governing when to move. Performance exceeded 90% with as few as 40 neurons.

AB - The prospect of assisting disabled patients by translating neural activity from the brain into control signals for prosthetic devices, has flourished in recent years. Current systems rely on neural activity present during natural arm movements. We propose here that neural activity present before or even without natural arm movements can provide an important, and potentially advantageous, source of control signals. To demonstrate how control signals can be derived from such plan activity we performed a computational study with neural activity previously recorded from the posterior parietal cortex of rhesus monkeys planning arm movements. We employed maximum likelihood decoders to estimate movement direction and to drive finite state machines governing when to move. Performance exceeded 90% with as few as 40 neurons.

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KW - Brain-computer interfaces

KW - Finite state machines

KW - Maximum likelihood

KW - Neural prosthetic systems

KW - Posterior parietal cortex

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Neural prosthetic control signals from plan activity

Abstract

Keywords

ASJC Scopus subject areas

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