A biomaterial that can mimic certain behaviors within biological tissues could advance regenerative medicine, disease modeling, soft robotics and more, according to researchers.

A biomaterial that can mimic certain behaviors within biological tissues could advance regenerative medicine, disease modeling, soft robotics and more, according to researchers at Penn State.

A research group led by Prof. Yang Liangbao from the Hefei Institutes of Physical Science of the Chinese Academy of Sciences ...

Scientists have controlled Kelvin waves in superfluid helium-4, using electric fields and nanoparticles to visualize them, ...

Biocompatibility is a key challenge for medical implants, so researchers have engineered apatite nanoparticles with enhanced ...

Northwestern researchers created a reusable sponge that captures pollutants like phosphate, copper, and zinc from water while ...

Silver nanoparticles (Ag-NPs) have long been celebrated for their antimicrobial properties. These microscopic marvels find applications in fields ranging from medicine to food preservation. However, ...

Medical implants have transformed health care, offering innovative solutions with advanced materials and technologies.

Medical implants and biomedical devices often cause inflammatory responses due to poor biocompatibility. Apatite coatings ...

Kelvin waves have been a mystery for decades but a new method involving superfluid helium-4 can help us control them.

A new smart fabric converts light into heat and can raise temperatures by more than 54 degrees Fahrenheit (30 degrees Celsius ...

Novel printing technique enables instant formation of gold nanoparticles within specific regions of 3D printed objects, ...