Independent Mobility Achieved through a Wireless Brain-Machine Interface

Individuals with tetraplegia lack independent mobility, making them highly dependent on others to move from one place to another. Here, we describe how two macaques were able to use a wireless integrated system to control a robotic platform, over which they were sitting, to achieve independent mobil...

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Bibliographic Details
Published in:	PloS one Vol. 11; no. 11; p. e0165773
Main Authors:	Libedinsky, Camilo, So, Rosa, Xu, Zhiming, Kyar, Toe K, Ho, Duncun, Lim, Clement, Chan, Louiza, Chua, Yuanwei, Yao, Lei, Cheong, Jia Hao, Lee, Jung Hyup, Vishal, Kulkarni Vinayak, Guo, Yongxin, Chen, Zhi Ning, Lim, Lay K, Li, Peng, Liu, Lei, Zou, Xiaodan, Ang, Kai K, Gao, Yuan, Ng, Wai Hoe, Han, Boon Siew, Chng, Keefe, Guan, Cuntai, Je, Minkyu, Yen, Shih-Cheng
Format:	Journal Article
Language:	English
Published:	United States Public Library of Science 01-11-2016 Public Library of Science (PLoS)
Subjects:	Algorithms Animals Artificial intelligence Behavior, Animal Biology and Life Sciences Brain Brain-Computer Interfaces Control algorithms Control systems Cortex (motor) Decoding Electrodes Electroencephalography Engineering and Technology Intelligence Macaca Macaca fascicularis Man-machine interfaces Mobility Monkeys & apes Motivation Motor Neurons - cytology Movement Neurons Prostheses Robotics Software Wheelchairs Wireless Technology Singapore
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Summary:	Individuals with tetraplegia lack independent mobility, making them highly dependent on others to move from one place to another. Here, we describe how two macaques were able to use a wireless integrated system to control a robotic platform, over which they were sitting, to achieve independent mobility using the neuronal activity in their motor cortices. The activity of populations of single neurons was recorded using multiple electrode arrays implanted in the arm region of primary motor cortex, and decoded to achieve brain control of the platform. We found that free-running brain control of the platform (which was not equipped with any machine intelligence) was fast and accurate, resembling the performance achieved using joystick control. The decoding algorithms can be trained in the absence of joystick movements, as would be required for use by tetraplegic individuals, demonstrating that the non-human primate model is a good pre-clinical model for developing such a cortically-controlled movement prosthetic. Interestingly, we found that the response properties of some neurons differed greatly depending on the mode of control (joystick or brain control), suggesting different roles for these neurons in encoding movement intention and movement execution. These results demonstrate that independent mobility can be achieved without first training on prescribed motor movements, opening the door for the implementation of this technology in persons with tetraplegia.
Bibliography:	ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 23 Conceptualization: WHN BSH KC CG MJ SCY. Funding acquisition: WHN BSH KC CG MJ SCY. Investigation: CL RS ZX TKK DH CL LC YC LY JHC JHL KVV YG ZNC LKL PL LL XZ SCY. Methodology: CL RS ZX TKK LC YC LY KKA YG WHN BSH KC CG MJ SCY. Project administration: YG CG MJ SCY. Software: RS ZX TKK KKA CG. Supervision: CG SCY. Visualization: CL RS ZX. Writing – original draft: CL RS CG SCY. Writing – review & editing: CL RS CG SCY. Competing Interests: The authors have declared that no competing interests exist.
ISSN:	1932-6203 1932-6203
DOI:	10.1371/journal.pone.0165773