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Breathable, wearable nanomesh electronics on skin for long-term health monitoring

(Nanowerk News) A hypoallergenic electronic sensor can be worn on the skin continuously for a week without discomfort, and is so light and thin that users forget they even have it on, says a Japanese group of scientists. The elastic electrode constructed of breathable nanoscale meshes holds promise for the development of noninvasive e-skin devices that can monitor a person's health continuously over a long period.
Index Finger with Gold Nanomesh Conductor
The electric current from a flexible battery placed near the knuckle flows through the conductor and powers the LED just below the fingernail. (Image: Someya Laboratory)
Wearable electronics that monitor heart rate and other vital health signals have made headway in recent years, with next-generation gadgets employing lightweight, highly elastic materials attached directly onto the skin for more sensitive, precise measurements.
However, although the ultrathin films and rubber sheets used in these devices adhere and conform well to the skin, their lack of breathability is deemed unsafe for long-term use: dermatological tests show the fine, stretchable materials prevent sweating and block airflow around the skin, causing irritation and inflammation, which ultimately could lead to lasting physiological and psychological effects.
"We learned that devices that can be worn for a week or longer for continuous monitoring were needed for practical use in medical and sports applications," says Professor Takao Someya at the University of Tokyo's Graduate School of Engineering whose research group had previously developed an on-skin patch that measured oxygen in blood.
Nanomesh Conductors Conform to Contours of Skin Surface
An array of nanomesh conductors attached to a fingertip, top, and a scanning electron microscope (SEM) image of a nanomesh conductor on a skin replica, bottom. (Image: Someya Laboratory)
In the current research (Nature Nanotechnology, "Inflammation-free, gas-permeable, lightweight, stretchable on-skin electronics with nanomeshes"), the group developed an electrode constructed from nanoscale meshes containing a water-soluble polymer, polyvinyl alcohol (PVA), and a gold layer--materials considered safe and biologically compatible with the body.
The device can be applied by spraying a tiny amount of water, which dissolves the PVA nanofibers and allows it to stick easily to the skin--it conformed seamlessly to curvilinear surfaces of human skin, such as sweat pores and the ridges of an index finger's fingerprint pattern.
The researchers next conducted a skin patch test on 20 subjects and detected no inflammation on the participants' skin after they had worn the device for a week. The group also evaluated the permeability, with water vapor, of the nanomesh conductor--along with those of other substrates like ultrathin plastic foil and a thin rubber sheet--and found that its porous mesh structure exhibited superior gas permeability compared to that of the other materials.
Application of Nanomesh Conductors to Skin Surface
The diagram at top illustrates the structure of gold nanomesh conductors laminated onto the skin surface. The nanomesh, constructed from polyvinyl alcohol (PVA) nanofibers and a gold (Au) layer, adheres to the skin when sprayed with water, dissolving the PVA, as depicted in the enlarged diagrams at bottom. (Image: Someya Laboratory)
Furthermore, the scientists proved the device's mechanical durability through repeated bending and stretching, exceeding 10,000 times, of a conductor attached on the forefinger; they also established its reliability as an electrode for electromyogram recordings when its readings of the electrical activity of muscles were comparable to those obtained through conventional gel electrodes.
"It will become possible to monitor patients' vital signs without causing any stress or discomfort," says Someya about the future implications of the team's research. In addition to nursing care and medical applications, the new device promises to enable continuous, precise monitoring of athletes' physiological signals and bodily motion without impeding their training or performance.
Source: University of Tokyo
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