Your search keyword '"Matsuhisa N"' showing total 2 results

1. An integrated self-healable electronic skin system fabricated via dynamic reconstruction of a nanostructured conducting network.

Author

Son D, Kang J, Vardoulis O, Kim Y, Matsuhisa N, Oh JY, To JW, Mun J, Katsumata T, Liu Y, McGuire AF, Krason M, Molina-Lopez F, Ham J, Kraft U, Lee Y, Yun Y, Tok JB, and Bao Z

Subjects

Electrodes, Electric Conductivity, Electronics instrumentation, Electronics methods, Nanostructures, Skin

Abstract

Electronic skin devices capable of monitoring physiological signals and displaying feedback information through closed-loop communication between the user and electronics are being considered for next-generation wearables and the 'Internet of Things'. Such devices need to be ultrathin to achieve seamless and conformal contact with the human body, to accommodate strains from repeated movement and to be comfortable to wear. Recently, self-healing chemistry has driven important advances in deformable and reconfigurable electronics, particularly with self-healable electrodes as the key enabler. Unlike polymer substrates with self-healable dynamic nature, the disrupted conducting network is unable to recover its stretchability after damage. Here, we report the observation of self-reconstruction of conducting nanostructures when in contact with a dynamically crosslinked polymer network. This, combined with the self-bonding property of self-healing polymer, allowed subsequent heterogeneous multi-component device integration of interconnects, sensors and light-emitting devices into a single multi-functional system. This first autonomous self-healable and stretchable multi-component electronic skin paves the way for future robust electronics.

Published

2018

2. Inflammation-free, gas-permeable, lightweight, stretchable on-skin electronics with nanomeshes.

Author

Miyamoto A, Lee S, Cooray NF, Lee S, Mori M, Matsuhisa N, Jin H, Yoda L, Yokota T, Itoh A, Sekino M, Kawasaki H, Ebihara T, Amagai M, and Someya T

Subjects

Adult, Biocompatible Materials adverse effects, Biocompatible Materials chemistry, Bioengineering instrumentation, Electric Conductivity, Gases chemistry, Humans, Inflammation etiology, Middle Aged, Nanostructures adverse effects, Nanostructures ultrastructure, Nanotechnology instrumentation, Permeability, Young Adult, Biosensing Techniques instrumentation, Electromyography instrumentation, Electronics, Medical instrumentation, Nanostructures chemistry, Skin metabolism

Abstract

Thin-film electronic devices can be integrated with skin for health monitoring and/or for interfacing with machines. Minimal invasiveness is highly desirable when applying wearable electronics directly onto human skin. However, manufacturing such on-skin electronics on planar substrates results in limited gas permeability. Therefore, it is necessary to systematically investigate their long-term physiological and psychological effects. As a demonstration of substrate-free electronics, here we show the successful fabrication of inflammation-free, highly gas-permeable, ultrathin, lightweight and stretchable sensors that can be directly laminated onto human skin for long periods of time, realized with a conductive nanomesh structure. A one-week skin patch test revealed that the risk of inflammation caused by on-skin sensors can be significantly suppressed by using the nanomesh sensors. Furthermore, a wireless system that can detect touch, temperature and pressure is successfully demonstrated using a nanomesh with excellent mechanical durability. In addition, electromyogram recordings were successfully taken with minimal discomfort to the user.

Published

2017