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16 October 2019
Yukio Nishimura (Neural Prosthesis Project) published a paper entitled ”Bypassing stroke-damaged neural pathways via a neural interface induces targeted cortical adaptation” in Nature Communications.

An Artificial Neural Connection Allows a New Cortical Site to Control hand Movements


Restoration of lost motor function after stroke is typically accomplished after strenuous rehabilitation therapy lasting for over months. However, new research published by a group led by Yukio Nishimura, the project leader of the Neural Prosthesis Project, Tokyo Metropolitan Institute of Medical Science showed that an artificial neural connection (ANC)*1 successfully allowed a new cortical site, previously unassociated with hand movements, to regain control of a paralyzed hand in a matter of minutes.

<Title of the paper>
Bypassing stroke-damaged neural pathways via a neural interface induces targeted cortical adaptation
Nature Communications
DOI: 10.1038/s41467-019-12647-y


In this research, experimental animals regained voluntary control of a paralyzed hand about ten minutes after establishment of an ANC. Animals engaged in learning with a functional ANC showed variable levels of input signals provided by the cerebral cortex*2 as hand movement improved. Specifically, the activated area of the cortex became more focused as control of hand movements improved.

Through this training of various areas of the cerebral cortex, the research team successfully imparted a new ability to control paralyzed hands via an ANC, even if those areas were not involved in hand control prior to the stroke. Examples of such regions include areas of the cortex that controls the movement of other body parts such as the face or shoulder, and even the somatosensory cortex, which is responsible for tactile and proprioception processing and is normally not associated with motor control. This finding suggests that an ANC can impart new motor control functions to any cortical region.

This research will contribute to the development of innovative therapies that will help stroke patients regain lost motor function by imparting this function to regions of the cerebral cortex previously not associated with hand movement. It is expected that these therapies will have practical clinical applications beyond restoring motor function and lead to the development of novel techniques to further integrate human brains with computers.

The researchers will continue to investigate whether extended use of an ANC will enhance the activity of spared neural networks and facilitate functional recovery so that patients will be able to regain voluntary control of paralyzed body parts even if they discontinue using the ANC.


*1 Artificial neural connection
A system that uses a computer and that functions in a similar way as cerebral neurons. It records neural information (electric signals) generated from more than one cortical site—this process is considered an input—and uses the information to identify particular cerebral activities, detect patterns, transform them into electrical stimuli, and transmit them to motor neurons to achieve muscle movements—this process is considered an output.
*2 Cerebral cortex
The thin outer layer of neurons that forms the surface of the cerebrum. It is responsible for higher-order brain functions such as perception, voluntary physical movement, thought, memory, and inference.

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