Reach and grasp by people with tetraplegia using a neurally controlled robotic arm
Two people with long-standing tetraplegia use neural interface system-based control of a robotic arm to perform three-dimensional reach and grasp movements. People with tetraplegia able to grasp with robotic arm John Donoghue and colleagues have previously demonstrated that people with tetraplegia c...
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| Veröffentlicht in: | Nature (London) Jg. 485; H. 7398; S. 372 - 375 |
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| Hauptverfasser: | , , , , , , , , , , |
| Format: | Journal Article |
| Sprache: | Englisch |
| Veröffentlicht: |
London
Nature Publishing Group UK
17.05.2012
Nature Publishing Group |
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| ISSN: | 0028-0836, 1476-4687, 1476-4687 |
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| Abstract | Two people with long-standing tetraplegia use neural interface system-based control of a robotic arm to perform three-dimensional reach and grasp movements.
People with tetraplegia able to grasp with robotic arm
John Donoghue and colleagues have previously demonstrated that people with tetraplegia can learn to use neural signals from the motor cortex to control a computer cursor. Work from another lab has also shown that monkeys can learn to use such signals to feed themselves with a robotic arm. Now, Donoghue and colleagues have advanced the technology to a level at which two people with long-standing paralysis — a 58-year-old woman and a 66-year-old man — are able to use a neural interface to direct a robotic arm to reach for and grasp objects. One subject was able to learn to pick up and drink from a bottle using a device implanted 5 years earlier, demonstrating not only that subjects can use the brain–machine interface, but also that it has potential longevity.
Paralysis following spinal cord injury, brainstem stroke, amyotrophic lateral sclerosis and other disorders can disconnect the brain from the body, eliminating the ability to perform volitional movements. A neural interface system
1
,
2
,
3
,
4
,
5
could restore mobility and independence for people with paralysis by translating neuronal activity directly into control signals for assistive devices. We have previously shown that people with long-standing tetraplegia can use a neural interface system to move and click a computer cursor and to control physical devices
6
,
7
,
8
. Able-bodied monkeys have used a neural interface system to control a robotic arm
9
, but it is unknown whether people with profound upper extremity paralysis or limb loss could use cortical neuronal ensemble signals to direct useful arm actions. Here we demonstrate the ability of two people with long-standing tetraplegia to use neural interface system-based control of a robotic arm to perform three-dimensional reach and grasp movements. Participants controlled the arm and hand over a broad space without explicit training, using signals decoded from a small, local population of motor cortex (MI) neurons recorded from a 96-channel microelectrode array. One of the study participants, implanted with the sensor 5 years earlier, also used a robotic arm to drink coffee from a bottle. Although robotic reach and grasp actions were not as fast or accurate as those of an able-bodied person, our results demonstrate the feasibility for people with tetraplegia, years after injury to the central nervous system, to recreate useful multidimensional control of complex devices directly from a small sample of neural signals. |
|---|---|
| AbstractList | Two people with long-standing tetraplegia use neural interface system-based control of a robotic arm to perform three-dimensional reach and grasp movements.
People with tetraplegia able to grasp with robotic arm
John Donoghue and colleagues have previously demonstrated that people with tetraplegia can learn to use neural signals from the motor cortex to control a computer cursor. Work from another lab has also shown that monkeys can learn to use such signals to feed themselves with a robotic arm. Now, Donoghue and colleagues have advanced the technology to a level at which two people with long-standing paralysis — a 58-year-old woman and a 66-year-old man — are able to use a neural interface to direct a robotic arm to reach for and grasp objects. One subject was able to learn to pick up and drink from a bottle using a device implanted 5 years earlier, demonstrating not only that subjects can use the brain–machine interface, but also that it has potential longevity.
Paralysis following spinal cord injury, brainstem stroke, amyotrophic lateral sclerosis and other disorders can disconnect the brain from the body, eliminating the ability to perform volitional movements. A neural interface system
1
,
2
,
3
,
4
,
5
could restore mobility and independence for people with paralysis by translating neuronal activity directly into control signals for assistive devices. We have previously shown that people with long-standing tetraplegia can use a neural interface system to move and click a computer cursor and to control physical devices
6
,
7
,
8
. Able-bodied monkeys have used a neural interface system to control a robotic arm
9
, but it is unknown whether people with profound upper extremity paralysis or limb loss could use cortical neuronal ensemble signals to direct useful arm actions. Here we demonstrate the ability of two people with long-standing tetraplegia to use neural interface system-based control of a robotic arm to perform three-dimensional reach and grasp movements. Participants controlled the arm and hand over a broad space without explicit training, using signals decoded from a small, local population of motor cortex (MI) neurons recorded from a 96-channel microelectrode array. One of the study participants, implanted with the sensor 5 years earlier, also used a robotic arm to drink coffee from a bottle. Although robotic reach and grasp actions were not as fast or accurate as those of an able-bodied person, our results demonstrate the feasibility for people with tetraplegia, years after injury to the central nervous system, to recreate useful multidimensional control of complex devices directly from a small sample of neural signals. Paralysis following spinal cord injury (SCI), brainstem stroke, amyotrophic lateral sclerosis (ALS) and other disorders can disconnect the brain from the body, eliminating the ability to carry out volitional movements. A neural interface system (NIS)1–5 could restore mobility and independence for people with paralysis by translating neuronal activity directly into control signals for assistive devices. We have previously shown that people with longstanding tetraplegia can use an NIS to move and click a computer cursor and to control physical devices6–8. Able-bodied monkeys have used an NIS to control a robotic arm9, but it is unknown whether people with profound upper extremity paralysis or limb loss could use cortical neuronal ensemble signals to direct useful arm actions. Here, we demonstrate the ability of two people with long-standing tetraplegia to use NIS-based control of a robotic arm to perform three-dimensional reach and grasp movements. Participants controlled the arm over a broad space without explicit training, using signals decoded from a small, local population of motor cortex (MI) neurons recorded from a 96-channel microelectrode array. One of the study participants, implanted with the sensor five years earlier, also used a robotic arm to drink coffee from a bottle. While robotic reach and grasp actions were not as fast or accurate as those of an able-bodied person, our results demonstrate the feasibility for people with tetraplegia, years after CNS injury, to recreate useful multidimensional control of complex devices directly from a small sample of neural signals. Paralysis following spinal cord injury, brainstem stroke, amyotrophic lateral sclerosis and other disorders can disconnect the brain from the body, eliminating the ability to perform volitional movements. A neural interface system could restore mobility and independence for people with paralysis by translating neuronal activity directly into control signals for assistive devices. We have previously shown that people with long-standing tetraplegia can use a neural interface system to move and click a computer cursor and to control physical devices. Able-bodied monkeys have used a neural interface system to control a robotic arm, but it is unknown whether people with profound upper extremity paralysis or limb loss could use cortical neuronal ensemble signals to direct useful arm actions. Here we demonstrate the ability of two people with long-standing tetraplegia to use neural interface system-based control of a robotic arm to perform three-dimensional reach and grasp movements. Participants controlled the arm and hand over a broad space without explicit training, using signals decoded from a small, local population of motor cortex (MI) neurons recorded from a 96-channel microelectrode array. One of the study participants, implanted with the sensor 5 years earlier, also used a robotic arm to drink coffee from a bottle. Although robotic reach and grasp actions were not as fast or accurate as those of an able-bodied person, our results demonstrate the feasibility for people with tetraplegia, years after injury to the central nervous system, to recreate useful multidimensional control of complex devices directly from a small sample of neural signals. Paralysis following spinal cord injury, brainstem stroke, amyotrophic lateral sclerosis and other disorders can disconnect the brain from the body, eliminating the ability to perform volitional movements. A neural interface system (1-5) could restore mobility and independence for people with paralysis by translating neuronal activity directly into control signals for assistive devices. We have previously shown that people with long-standing tetraplegia can use a neural interface system to move and click a computer cursor and to control physical devices (6-8). Able-bodied monkeys have used a neural interface system to control a robotic arm (9), but it is unknown whether people with profound upper extremity paralysis or limb loss could use cortical neuronal ensemble signals to direct useful arm actions. Here we demonstrate the ability of two people with long-standing tetraplegia to use neural interface system-based control of a robotic arm to perform three-dimensional reach and grasp movements. Participants controlled the arm and hand over a broad space without explicit training, using signals decoded from a small, local population of motor cortex (MI) neurons recorded from a 96-channel microelectrode array. One of the study participants, implanted with the sensor 5 years earlier, also used a robotic arm to drink coffee from a bottle. Although robotic reach and grasp actions were not as fast or accurate as those of an able-bodied person, our results demonstrate the feasibility for people with tetraplegia, years after injury to the central nervous system, to recreate useful multidimensional control of complex devices directly from a small sample of neural signals. Paralysis following spinal cord injury, brainstemstroke, amyotrophic lateral sclerosis and other disorders can disconnect the brain from the body, eliminating the ability to perform volitional movements. A neural interface system1-5 could restore mobility and independence for people with paralysis by translating neuronal activity directly into control signals for assistive devices. We have previously shown that people with long-standing tetraplegia can use a neural interface system to move and click a computer cursor and to control physical devices6-8. Able-bodied monkeys have used a neural interface system to control a robotic arm9, but it is unknown whether people with profound upper extremity paralysis or limb loss could use cortical neuronal ensemble signals to direct useful arm actions. Here we demonstrate the ability of two people with long-standing tetraplegia to use neural interface system-based control of a robotic arm to perform three-dimensional reach and graspmovements. Participants controlled the arm and hand over a broad space without explicit training, using signals decoded from a small, local population of motor cortex (MI) neurons recorded from a 96-channel microelectrode array. One of the study participants, implanted with the sensor 5 years earlier, also used a robotic arm to drink coffee from a bottle. Although robotic reach and grasp actions were not as fast or accurate as those of an able-bodied person, our results demonstrate the feasibility for people with tetraplegia, years after injury to the central nervous system, to recreate useful multidimensional control of complex devices directly from a small sample of neural signals. [PUBLICATION ABSTRACT] Paralysis following spinal cord injury, brainstem stroke, amyotrophic lateral sclerosis and other disorders can disconnect the brain from the body, eliminating the ability to perform volitional movements. A neural interface system could restore mobility and independence for people with paralysis by translating neuronal activity directly into control signals for assistive devices. We have previously shown that people with long-standing tetraplegia can use a neural interface system to move and click a computer cursor and to control physical devices. Able-bodied monkeys have used a neural interface system to control a robotic arm, but it is unknown whether people with profound upper extremity paralysis or limb loss could use cortical neuronal ensemble signals to direct useful arm actions. Here we demonstrate the ability of two people with long-standing tetraplegia to use neural interface system-based control of a robotic arm to perform three-dimensional reach and grasp movements. Participants controlled the arm and hand over a broad space without explicit training, using signals decoded from a small, local population of motor cortex (MI) neurons recorded from a 96-channel microelectrode array. One of the study participants, implanted with the sensor 5 years earlier, also used a robotic arm to drink coffee from a bottle. Although robotic reach and grasp actions were not as fast or accurate as those of an able-bodied person, our results demonstrate the feasibility for people with tetraplegia, years after injury to the central nervous system, to recreate useful multidimensional control of complex devices directly from a small sample of neural signals.Paralysis following spinal cord injury, brainstem stroke, amyotrophic lateral sclerosis and other disorders can disconnect the brain from the body, eliminating the ability to perform volitional movements. A neural interface system could restore mobility and independence for people with paralysis by translating neuronal activity directly into control signals for assistive devices. We have previously shown that people with long-standing tetraplegia can use a neural interface system to move and click a computer cursor and to control physical devices. Able-bodied monkeys have used a neural interface system to control a robotic arm, but it is unknown whether people with profound upper extremity paralysis or limb loss could use cortical neuronal ensemble signals to direct useful arm actions. Here we demonstrate the ability of two people with long-standing tetraplegia to use neural interface system-based control of a robotic arm to perform three-dimensional reach and grasp movements. Participants controlled the arm and hand over a broad space without explicit training, using signals decoded from a small, local population of motor cortex (MI) neurons recorded from a 96-channel microelectrode array. One of the study participants, implanted with the sensor 5 years earlier, also used a robotic arm to drink coffee from a bottle. Although robotic reach and grasp actions were not as fast or accurate as those of an able-bodied person, our results demonstrate the feasibility for people with tetraplegia, years after injury to the central nervous system, to recreate useful multidimensional control of complex devices directly from a small sample of neural signals. |
| Audience | Academic |
| Author | Liu, Jie Masse, Nicolas Y. Cash, Sydney S. Hochberg, Leigh R. Bacher, Daniel Vogel, Joern Haddadin, Sami Simeral, John D. Jarosiewicz, Beata Donoghue, John P. van der Smagt, Patrick |
| AuthorAffiliation | 5 Harvard Medical School, Boston, MA 6 German Aerospace Center, Institute of Robotics and Mechatronics (DLR, Oberpfaffenhofen), Germany 4 Massachusetts General Hospital, Boston, MA 1 Rehabilitation Research & Development Service, Department of Veterans Affairs, Providence, RI 2 School of Engineering and Institute for Brain Science, Brown University, Providence, RI 3 Department of Neuroscience and Institute for Brain Science, Brown University, Providence, RI |
| AuthorAffiliation_xml | – name: 6 German Aerospace Center, Institute of Robotics and Mechatronics (DLR, Oberpfaffenhofen), Germany – name: 1 Rehabilitation Research & Development Service, Department of Veterans Affairs, Providence, RI – name: 4 Massachusetts General Hospital, Boston, MA – name: 3 Department of Neuroscience and Institute for Brain Science, Brown University, Providence, RI – name: 2 School of Engineering and Institute for Brain Science, Brown University, Providence, RI – name: 5 Harvard Medical School, Boston, MA |
| Author_xml | – sequence: 1 givenname: Leigh R. surname: Hochberg fullname: Hochberg, Leigh R. email: leigh@brown.edu organization: Department of Veterans Affairs, Rehabilitation Research & Development Service, School of Engineering and Institute for Brain Science, Brown University, Department of Neurology, Massachusetts General Hospital, Harvard Medical School – sequence: 2 givenname: Daniel surname: Bacher fullname: Bacher, Daniel organization: School of Engineering and Institute for Brain Science, Brown University – sequence: 3 givenname: Beata surname: Jarosiewicz fullname: Jarosiewicz, Beata organization: Department of Veterans Affairs, Rehabilitation Research & Development Service, Department of Neuroscience and Institute for Brain Science, Brown University – sequence: 4 givenname: Nicolas Y. surname: Masse fullname: Masse, Nicolas Y. organization: Department of Neuroscience and Institute for Brain Science, Brown University – sequence: 5 givenname: John D. surname: Simeral fullname: Simeral, John D. organization: Department of Veterans Affairs, Rehabilitation Research & Development Service, School of Engineering and Institute for Brain Science, Brown University, Department of Neurology, Massachusetts General Hospital – sequence: 6 givenname: Joern surname: Vogel fullname: Vogel, Joern organization: German Aerospace Center, Institute of Robotics and Mechatronics (DLR – sequence: 7 givenname: Sami surname: Haddadin fullname: Haddadin, Sami organization: German Aerospace Center, Institute of Robotics and Mechatronics (DLR – sequence: 8 givenname: Jie surname: Liu fullname: Liu, Jie organization: Department of Veterans Affairs, Rehabilitation Research & Development Service, School of Engineering and Institute for Brain Science, Brown University – sequence: 9 givenname: Sydney S. surname: Cash fullname: Cash, Sydney S. organization: Department of Neurology, Massachusetts General Hospital, Harvard Medical School – sequence: 10 givenname: Patrick surname: van der Smagt fullname: van der Smagt, Patrick organization: German Aerospace Center, Institute of Robotics and Mechatronics (DLR – sequence: 11 givenname: John P. surname: Donoghue fullname: Donoghue, John P. email: john_donoghue@brown.edu organization: Department of Veterans Affairs, Rehabilitation Research & Development Service, School of Engineering and Institute for Brain Science, Brown University, Department of Neuroscience and Institute for Brain Science, Brown University |
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| Keywords | Human Gripping Tetraplegia Nervous system diseases Motor system disorder Male Robotics Treatment User interface Motor cortex Adult Female Neurological disorder Woman Arm |
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| Snippet | Two people with long-standing tetraplegia use neural interface system-based control of a robotic arm to perform three-dimensional reach and grasp movements.... Paralysis following spinal cord injury, brainstem stroke, amyotrophic lateral sclerosis and other disorders can disconnect the brain from the body, eliminating... Paralysis following spinal cord injury, brainstemstroke, amyotrophic lateral sclerosis and other disorders can disconnect the brain from the body, eliminating... Paralysis following spinal cord injury (SCI), brainstem stroke, amyotrophic lateral sclerosis (ALS) and other disorders can disconnect the brain from the body,... |
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| SubjectTerms | 631/114/1305 631/378/1689 631/443/376 639/766/25 Aged Applied sciences Arm - physiology Biological and medical sciences Calibration Care and treatment Central nervous system Computer science; control theory; systems Computer systems and distributed systems. User interface Control theory. Systems Drinking - physiology Exact sciences and technology Female Hand - physiology Hand Strength - physiology Humanities and Social Sciences Humans letter Local population Male Man-Machine Systems Medical sciences Microelectrodes Middle Aged Motor Cortex - cytology Motor Cortex - physiology Movement - physiology multidisciplinary Nervous system (semeiology, syndromes) Nervous system as a whole Neurology Psychomotor Performance Quadriplegia Quadriplegia - physiopathology Robotics Robotics - instrumentation Robotics - methods Robots Science Science (multidisciplinary) Signal processing Software Time Factors |
| Title | Reach and grasp by people with tetraplegia using a neurally controlled robotic arm |
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