A new ultra-thin skinpatch with nanotechnology able to monitor 11 human health signals has been developed by researchers
at Monash University.
Researchers from the Faculty of Engineering and Faculty of Information Technology combined nanotechnology and artificial
intelligence to bring machines one step closer to communicating with the human body.
Using specialised algorithms, personalised Artificial Intelligence (AI) technology can now disentangle multiple body
signals, understand them and make a decision on what to do next.
Published recently in Nature Nanotechnology, the research could change how we deliver remote healthcare and be the future of personal alarms and communications
devices.
Worn on the neck, lead researcher Professor Wenlong Cheng said the ultra-thin wearable patch has three layers, measuring
speech, neck movement and touch. It also measures breathing and heart rates.
“Emerging soft electronics have the potential to serve as second-skin-like wearable patches for monitoring human health
vitals, designing perception robotics and bridging interactions between natural and artificial intelligence,” Professor
Cheng said.
Associate Professor Zongyuan Ge, from the Faculty of Information Technology, is part of the Monash team to have
developed a frequency/amplitude-based neural network called Deep Hybrid-Spectro, that can automatically monitor multiple biometrics from a single signal.
“As people all sound and act differently, the next step is to program and personalise the sensors using even more
sophisticated algorithms so they can be tailored to individuals,” Associate Professor Ge added.
The sensor is made from laminated cracked platinum film, vertically aligned gold nanowires and a percolated gold
nanowire film.
Neck skin is the most sensitive skin on the body and connects up to five physiological activities associated with the
human throat: speech, heartbeats, breathing, touch and neck movement.
This work was mainly performed at the Monash Nanobionics lab and in part at the Melbourne Centre for Nanofabrication
(MCN) in the Victorian Node of the Australian National Fabrication Facility (ANFF) and the Monash Centre for Electron
Microscopy.
Lead researcher Professor Wenlong Cheng and co-author Associate Professor Zongyuan Ge are available for interviews.
See the media kit for images and a video and access the full research paper.
ENDS
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