They combined a blend of slimy and sticky proteins to produce a fast-acting, bacteria-blocking, waterproof adhesive for use in biomedical applications.

Georgia Tech researchers have created a 3D-printed heart valve made of bioresorbable materials and designed to fit an individual patient’s unique anatomy. Once implanted, the valves will be absorbed by the body and replaced by new tissue that will perform the function that the device once served.

A research group from the Institute for Research on Next-generation Semiconductor and Sensing Science (IRES²) at Toyohashi University of Technology has developed an innovative in vivo electrophysiological neural recording technology that minimizes neuronal death and allows stable recordings for over a year.

Researchers from Tokyo Metropolitan University have created nanostructured alumina surfaces which are strongly antibacterial but can be used to culture cells.

Cardiovascular disease continues to lead as the primary cause of death across the globe, taking millions of lives every year. Damage caused by these diseases is particularly difficult to repair, since the heart has minimal ability to regenerate itself. But what if we could reprogram the body’s own cells to restore damaged tissue? This question has been tackled by scientists at Korea University, led by Dr. Myeong-Hwa Song.

Researchers from IBEC led by Oscar Castaño, senior researcher at the Biomaterials for Regenerative Therapies group, developed a novel approach, recently published in Biomaterials Advances.

The new balloon can be expanded before a meal to prevent overeating, then deflated when no longer needed.