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Design principles for noninvasive brain-machine interfaces

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Abstract:

With the advent of sophisticated prosthetic limbs, the challenge is now to develop and demonstrate optimal closed-loop control of the these limbs using neural measurement...Show More

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Abstract:

With the advent of sophisticated prosthetic limbs, the challenge is now to develop and demonstrate optimal closed-loop control of the these limbs using neural measurements from single/multiple unit activity (SUA/MUA), electrocorticography (ECoG), local field potentials (LFP), scalp electroencephalography (EEG) or even electromyography (EMG) after targeted muscle reinnervation (TMR) in subjects with upper limb disarticulation. In this paper we propose design principles for developing a noninvasive EEG-based brain-machine interface (BMI) for dexterous control of a high degree-of-freedom, biologically realistic limb.

Published in: 2011 Annual International Conference of the IEEE Engineering in Medicine and Biology Society

Date of Conference: 30 August 2011 - 03 September 2011

Date Added to IEEE Xplore: 01 December 2011

ISBN Information:

ISSN Information:

PubMed ID: 22255271

DOI: 10.1109/IEMBS.2011.6091048

Conference Location: Boston, MA, USA

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IEEE Keywords
Index Terms
- Rational Design ,
- Upper Limb ,
- Electromyography ,
- Prosthetic Limb ,
- Electrode ,
- Gestures ,
- Neural Activity ,
- Spinal Cord Injury ,
- Single Session ,
- Amplitude Modulation ,
- EEG Signals ,
- Movement Control ,
- Robotic Arm ,
- Natural Movement ,
- Gamma Band ,
- Months Of Training ,
- Delta Band ,
- Decoding Accuracy ,
- Local Field Potential Signals ,
- Readiness Potential ,
- Cursor Movement ,
- Sensorimotor Rhythm ,
- High Gamma Band ,
- Input Feature Space ,
- Control Limbs ,
- Brain Signals ,
- Wheelchair ,
- Prosthetic Control ,
- Low-pass ,
- Amputation
MeSH Terms
- Brain ,
- Electromyography ,
- Equipment Design ,
- Humans ,
- Man-Machine Systems ,
- Muscles

Contents

I. Introduction

Electromyography (EMG)-based systems have shown reasonably reliable 7-degrees-of-freedom (DOF) control of a prosthetic limb using EMG after TMR - a surgical technique pioneered by Dr. Kuiken involving the transfer of residual nerves in the amputated arm to the remaining muscle, which then provide EMG signals that correlate to the original nerve functions allowing a virtual or physical prosthetic arm to respond directly and more naturally to the brain signals [1]–[2]. Some critical challenges of this approach concern the stability of EMG recordings, interference from muscles controlling remaining joints, effects of tissue loading, control of fine dexterous movements, and the cognitive burden of operating the device [1]. Thus, it is desirable to develop noninvasive neural interfaces that directly use brain signals, such as scalp electroencephalography (EEG), to control fine dexterous movements.

Keywords assist with retrieval of results and provide a means to discovering other relevant content. Learn more.

IEEE Keywords
Index Terms
- Rational Design ,
- Upper Limb ,
- Electromyography ,
- Prosthetic Limb ,
- Electrode ,
- Gestures ,
- Neural Activity ,
- Spinal Cord Injury ,
- Single Session ,
- Amplitude Modulation ,
- EEG Signals ,
- Movement Control ,
- Robotic Arm ,
- Natural Movement ,
- Gamma Band ,
- Months Of Training ,
- Delta Band ,
- Decoding Accuracy ,
- Local Field Potential Signals ,
- Readiness Potential ,
- Cursor Movement ,
- Sensorimotor Rhythm ,
- High Gamma Band ,
- Input Feature Space ,
- Control Limbs ,
- Brain Signals ,
- Wheelchair ,
- Prosthetic Control ,
- Low-pass ,
- Amputation
MeSH Terms
- Brain ,
- Electromyography ,
- Equipment Design ,
- Humans ,
- Man-Machine Systems ,
- Muscles

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Design principles for noninvasive brain-machine interfaces

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Design principles for noninvasive brain-machine interfaces

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Abstract:

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Abstract:

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I. Introduction

References

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