A team of researchers at the University of Houston, has developed a new form of electronics known as “drawn-on-skin electronics,” allowing multifunctional sensors and circuits to be drawn on the skin with an ink pen.
The advance, the researchers report in the journal Nature Communications, allows for the collection of more precise, motion artifact-free health data, solving the long-standing problem of collecting precise biological data through a wearable device when the subject is in motion.
The imprecision may not be important when your FitBit registers 4,000 steps instead of 4,200, but sensors designed to check heart function, temperature and other physical signals must be accurate if they are to be used for diagnostics and treatment.
The drawn-on-skin electronics are able to seamlessly collect data, regardless of the wearer’s movements.
They also offer other advantages, including simple fabrication techniques that don’t require dedicated equipment.
Wearable bioelectronics – in the form of soft, flexible patches attached to the skin – have become an important way to monitor, prevent and treat illness and injury by tracking physiological information from the wearer. But even the most flexible wearables are limited by motion artifacts, or the difficulty that arises in collecting data when the sensor doesn’t move precisely with the skin.
The drawn-on-skin electronics can be customized to collect different types of information, and it is expected to be especially useful in situations where it’s not possible to access sophisticated equipment, including on a battleground.
The electronics are able to track muscle signals, heart rate, temperature and skin hydration, among other physical data. The researchers also reported that the drawn-on-skin electronics have demonstrated the ability to accelerate healing of wounds.
The drawn-on-skin electronics are actually comprised of three inks, serving as a conductor, semiconductor and dielectric.
Electronic inks, including conductors, semiconductors, and dielectrics, are drawn on-demand in a freeform manner to develop devices, such as transistors, strain sensors, temperature sensors, heaters, skin hydration sensors, and electrophysiological sensors.
News Source: University of Houston
