Cognitive control signals for neural prosthetics

S. Musallam; B. D. Corneil; B. Greger; H. Scherberger; R. A. Andersen

doi:10.1126/science.1097938

Cognitive control signals for neural prosthetics

S. Musallam, B. D. Corneil, B. Greger, H. Scherberger, R. A. Andersen

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

584 Scopus citations

Abstract

Recent development of neural prosthetics for assisting paralyzed patients has focused on decoding intended hand trajectories from motor cortical neurons and using this signal to control external devices. In this study, higher level signals related to the goals of movements were decoded from three monkeys and used to position cursors on a computer screen without the animals emitting any behavior. Their performance in this task improved over a period of weeks. Expected value signals related to fluid preference, the expected magnitude, or probability of reward were decoded simultaneously with the intended goal. For neural prosthetic applications, the goal signals can be used to operate computers, robots, and vehicles, whereas the expected value signals can be used to continuously monitor a paralyzed patient's preferences and motivation.

Original language	English (US)
Pages (from-to)	258-262
Number of pages	5
Journal	Science
Volume	305
Issue number	5681
DOIs	https://doi.org/10.1126/science.1097938
State	Published - Jul 9 2004
Externally published	Yes

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10.1126/science.1097938

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abstract = "Recent development of neural prosthetics for assisting paralyzed patients has focused on decoding intended hand trajectories from motor cortical neurons and using this signal to control external devices. In this study, higher level signals related to the goals of movements were decoded from three monkeys and used to position cursors on a computer screen without the animals emitting any behavior. Their performance in this task improved over a period of weeks. Expected value signals related to fluid preference, the expected magnitude, or probability of reward were decoded simultaneously with the intended goal. For neural prosthetic applications, the goal signals can be used to operate computers, robots, and vehicles, whereas the expected value signals can be used to continuously monitor a paralyzed patient's preferences and motivation.",

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AU - Musallam, S.

AU - Corneil, B. D.

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AU - Scherberger, H.

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AB - Recent development of neural prosthetics for assisting paralyzed patients has focused on decoding intended hand trajectories from motor cortical neurons and using this signal to control external devices. In this study, higher level signals related to the goals of movements were decoded from three monkeys and used to position cursors on a computer screen without the animals emitting any behavior. Their performance in this task improved over a period of weeks. Expected value signals related to fluid preference, the expected magnitude, or probability of reward were decoded simultaneously with the intended goal. For neural prosthetic applications, the goal signals can be used to operate computers, robots, and vehicles, whereas the expected value signals can be used to continuously monitor a paralyzed patient's preferences and motivation.

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Cognitive control signals for neural prosthetics

Abstract

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