BIOMAT Database Logo BIOMAT Database Logo

Magnetoencephalographic evaluation for the myoelectric hand prosthesis with tacit learning system. 2019

Katsuyuki Iwatsuki, and Minoru Hoshiyama, and Shintaro Oyama, and Shingo Shimoda, and Hitoshi Hirata
Department of Hand Surgery, Nagoya University School of Medicine, Nagoya, Aichi, Japan.

BACKGROUND The effect of tacit learning systems (TLSs) on brain plasticity are as of yet unknown. We developed a myoelectric hand prosthesis equipped with a TLS to auto-regulate forearm rotation in response to upper extremity movement patterns. OBJECTIVE To evaluate the effects of tacit learning on the central nervous system during a prosthesis control exercise. METHODS The experienced prosthetic user performed a series of simple mechanical tasks with the TLS inactivated (the baseline condition) and then with it activated (the enhanced, experimental condition). The process was video recorded. Subsequently, the participant viewed video recordings of each condition (baseline and experimental) during magnetoencephalography and electroencephalography recordings. RESULTS Stronger connections between the motor area and other cortical areas were observed, as indicated by a significant increase in coherence values. CONCLUSIONS Integration and interoperability may underlie tacit learning and promote motor function-related adaptive neuroplasticity.

UI MeSH Term Description Entries
D007858 Learning Relatively permanent change in behavior that is the result of past experience or practice. The concept includes the acquisition of knowledge. Phenomenography
D008297 Male Males
D009473 Neuronal Plasticity The capacity of the NERVOUS SYSTEM to change its reactivity as the result of successive activations. Brain Plasticity,Plasticity, Neuronal,Axon Pruning,Axonal Pruning,Dendrite Arborization,Dendrite Pruning,Dendritic Arborization,Dendritic Pruning,Dendritic Remodeling,Neural Plasticity,Neurite Pruning,Neuronal Arborization,Neuronal Network Remodeling,Neuronal Pruning,Neuronal Remodeling,Neuroplasticity,Synaptic Plasticity,Synaptic Pruning,Arborization, Dendrite,Arborization, Dendritic,Arborization, Neuronal,Arborizations, Dendrite,Arborizations, Dendritic,Arborizations, Neuronal,Axon Prunings,Axonal Prunings,Brain Plasticities,Dendrite Arborizations,Dendrite Prunings,Dendritic Arborizations,Dendritic Prunings,Dendritic Remodelings,Network Remodeling, Neuronal,Network Remodelings, Neuronal,Neural Plasticities,Neurite Prunings,Neuronal Arborizations,Neuronal Network Remodelings,Neuronal Plasticities,Neuronal Prunings,Neuronal Remodelings,Neuroplasticities,Plasticities, Brain,Plasticities, Neural,Plasticities, Neuronal,Plasticities, Synaptic,Plasticity, Brain,Plasticity, Neural,Plasticity, Synaptic,Pruning, Axon,Pruning, Axonal,Pruning, Dendrite,Pruning, Dendritic,Pruning, Neurite,Pruning, Neuronal,Pruning, Synaptic,Prunings, Axon,Prunings, Axonal,Prunings, Dendrite,Prunings, Dendritic,Prunings, Neurite,Prunings, Neuronal,Prunings, Synaptic,Remodeling, Dendritic,Remodeling, Neuronal,Remodeling, Neuronal Network,Remodelings, Dendritic,Remodelings, Neuronal,Remodelings, Neuronal Network,Synaptic Plasticities,Synaptic Prunings
D010775 Photic Stimulation Investigative technique commonly used during ELECTROENCEPHALOGRAPHY in which a series of bright light flashes or visual patterns are used to elicit brain activity. Stimulation, Photic,Visual Stimulation,Photic Stimulations,Stimulation, Visual,Stimulations, Photic,Stimulations, Visual,Visual Stimulations
D004569 Electroencephalography Recording of electric currents developed in the brain by means of electrodes applied to the scalp, to the surface of the brain, or placed within the substance of the brain. EEG,Electroencephalogram,Electroencephalograms
D004576 Electromyography Recording of the changes in electric potential of muscle by means of surface or needle electrodes. Electromyogram,Surface Electromyography,Electromyograms,Electromyographies,Electromyographies, Surface,Electromyography, Surface,Surface Electromyographies
D006225 Hand The distal part of the arm beyond the wrist in humans and primates, that includes the palm, fingers, and thumb. Hands
D006801 Humans Members of the species Homo sapiens. Homo sapiens,Man (Taxonomy),Human,Man, Modern,Modern Man
D000328 Adult A person having attained full growth or maturity. Adults are of 19 through 44 years of age. For a person between 19 and 24 years of age, YOUNG ADULT is available. Adults
D000674 Amputees Persons who have lost part of, or all of, a limb or other appendage of their body. Amputee,Multiple Amputee,Multiple Amputees,Amputee, Multiple,Amputees, Multiple

Related Publications

Katsuyuki Iwatsuki, and Minoru Hoshiyama, and Shintaro Oyama, and Shingo Shimoda, and Hitoshi Hirata
Evaluation of a myoelectric hand prosthesis for children with a below-elbow absence.
December 1985, Prosthetics and orthotics international,
Katsuyuki Iwatsuki, and Minoru Hoshiyama, and Shintaro Oyama, and Shingo Shimoda, and Hitoshi Hirata
The Southampton Hand: an intelligent myoelectric prosthesis.
November 1994, Journal of rehabilitation research and development,
Katsuyuki Iwatsuki, and Minoru Hoshiyama, and Shintaro Oyama, and Shingo Shimoda, and Hitoshi Hirata
Hand prosthesis control via myoelectric patterns.
January 1973, Acta orthopaedica Scandinavica,
Katsuyuki Iwatsuki, and Minoru Hoshiyama, and Shintaro Oyama, and Shingo Shimoda, and Hitoshi Hirata
Stable myoelectric control of a hand prosthesis using non-linear incremental learning.
January 2014, Frontiers in neurorobotics,
Katsuyuki Iwatsuki, and Minoru Hoshiyama, and Shintaro Oyama, and Shingo Shimoda, and Hitoshi Hirata
Design and Functional Evaluation of a Dexterous Myoelectric Hand Prosthesis With Biomimetic Tactile Sensor.
July 2018, IEEE transactions on neural systems and rehabilitation engineering : a publication of the IEEE Engineering in Medicine and Biology Society,
Katsuyuki Iwatsuki, and Minoru Hoshiyama, and Shintaro Oyama, and Shingo Shimoda, and Hitoshi Hirata
The SSSA-MyHand: A Dexterous Lightweight Myoelectric Hand Prosthesis.
May 2017, IEEE transactions on neural systems and rehabilitation engineering : a publication of the IEEE Engineering in Medicine and Biology Society,
Katsuyuki Iwatsuki, and Minoru Hoshiyama, and Shintaro Oyama, and Shingo Shimoda, and Hitoshi Hirata
A compact-sized surface EMG sensor for myoelectric hand prosthesis.
November 2019, Biomedical engineering letters,
Katsuyuki Iwatsuki, and Minoru Hoshiyama, and Shintaro Oyama, and Shingo Shimoda, and Hitoshi Hirata
Editorial. Myoelectric functional hand prosthesis for total brachial plexus injury.
November 2017, Journal of neurosurgery,
Katsuyuki Iwatsuki, and Minoru Hoshiyama, and Shintaro Oyama, and Shingo Shimoda, and Hitoshi Hirata
Intuitive real-time control strategy for high-density myoelectric hand prosthesis using deep and transfer learning.
May 2021, Scientific reports,
Katsuyuki Iwatsuki, and Minoru Hoshiyama, and Shintaro Oyama, and Shingo Shimoda, and Hitoshi Hirata
A biomechanical model for the development of myoelectric hand prosthesis control systems.
January 2010, Annual International Conference of the IEEE Engineering in Medicine and Biology Society. IEEE Engineering in Medicine and Biology Society. Annual International Conference,
Copied contents to your clipboard!