Wearable bioelectronic device capable of tracking multiple vital signs developed
University of Missouri researchers have created an ultrasoft “skin-like” material for use in the development of an on-skin, wearable bioelectronic device capable of simultaneously tracking multiple vital signs such as blood pressure, electrical heart activity and skin hydration.
With cancer, diabetes and heart disease among the leading causes of disability and death in the United States, imagine a long-term, in-home monitoring solution that could detect these chronic diseases early and lead to timely interventions.
Zheng Yan and a team of researchers at the University of Missouri may have a solution. They have created an ultrasoft “skin-like” material — that’s both breathable and stretchable — for use in the development of an on-skin, wearable bioelectronic device capable of simultaneously tracking multiple vital signs such as blood pressure, electrical heart activity and skin hydration.
“Our overall goal is to help improve the long-term biocompatibility and the long-lasting accuracy of wearable bioelectronics through the innovation of this fundamental porous material which has many novel properties,” said Yan, an assistant professor in the Department of Chemical and Biomedical Engineering and the Department of Mechanical and Aerospace Engineering.
Made from a liquid-metal elastomer composite, the material’s key feature is its skin-like soft properties.
“It is ultrasoft and ultra-stretchable, so when the device is worn on the human body, it will be mechanically imperceptible to the user,” Yan said. “You cannot feel it, and you will likely forget about it. This is because people can feel about 20 kilopascals or more of pressure when something is stretched on their skin, and this material creates less pressure than that.”
Its integrated antibacterial and antiviral properties can also help prevent harmful pathogens from forming on the surface of the skin underneath the device during extended use.
Lights connected using the new liquid metal elastomer composite illuminate the logo of the research group.
“We call it a mechanical and electrical decoupling, so when the material is stretched, there is only a small change in the electrical performance during human motion, and the device can still record high-quality biological signals from the human body,” Yan said.
While other researchers have worked on similar designs for liquid-metal elastomer composites, Yan said the MU team has a novel approach because the breathable “porous” material they developed can prevent the liquid metal from leaking out when the material is stretched as the human body moves.
The work builds on the team’s existing proof of concept, as demonstrated by their previous work including a heart monitor currently under development. In the future, Yan hopes the biological data gathered by the device could be wirelessly transmitted to smartphone or similar electronics for future sharing with medical professionals.