Patients with ID receiving TNF inhibitors are at greater risk for cutaneous malignancy than patients who are biologic-naïve.

Instead of focusing on sensor readings at specific points, their magnetoreceptor captures electrical resistance information ...

In a giant leap towards humanizing machines, scientists have developed an innovative electric skin that allows robots to sense the world around them- from a gentle tap to a sudden burst of heat, and ...

Scientists have developed a new type of robotic skin that allows robots to feel touch, heat, pressure, and even damage.

When aiming for stretchable, health-monitoring, skin-like sensor sheets, materials with demanding properties are required: they need to be flexible, biocompatible, and electrically conductive at the ...

S cientists have developed a new type of electronic "skin" that could give robots the ability to "feel" different tactile ...

The skin is the largest organ in the human body, possessing elasticity, self-healing, mechanical resilience and tactile sensing functions. “Electronic skins are devices and systems that imitate the ...

Nearly invisible, seaweed-based electronic skin precisely monitors pulse pressure and temperature, rivaling medical equipment in accuracy with its innovative bioelectronic design.

Researchers at the University of Texas at Austin have developed a new kind of electronic skin that stretches, bends, and senses touch and pressure with the same sensitivity as human skin.

A first-ever stretchable electronic skin was developed by researchers at the University of Texas at Austin.

Researchers at Texas A&M University have made strides in developing 3D-printed electronic skin that mimics the flexibility and sensitivity of human skin.

Stanford scientists have developed a soft and stretchable electronic skin that can directly talk to the brain, imitating the sensory feedback of real skin using a strategy that, if improved, could ...