RIT researchers solve multiple tissue engineering challenges by developing a novel hydrogel to host human cells and a device to 3D print bioinks safely.

Tissue engineering and regenerative medicine have shown significant potential for repairing and regenerating damaged tissues and can be used to provide personalized treatment plans, with broad ...

Global Scaffold Technology Market OverviewThe global scaffold technology market is poised for robust expansion, registering an estimated growth rate of around 13% over the next five years, driven by ...

A new device that uses light to non-destructively image tissue could revolutionize cartilage and tissue transplant surgery, laying the groundwork for osteoarthritis treatment. Published Sept. 9 in ...

Researchers from MIT have developed a 3D-printable tissue adhesive that demonstrates superior tissue adhesion, rapid sealing capabilities across various surgical scenarios and a unique blood-repelling ...

Anthony Atala at Harvard Medical School Cartilage; Jim Burns at Genzyme Cartilage; Antonios Mikos at Rice U. Bone and cardiovascular tissue; David Mooney at U. Michigan Bone and cartilage Every year, ...

Tissue engineering is a burgeoning academic field, however, the clinical and therapeutic promise of tissue and organ replacement has remained largely unrealized. With the possible exceptions of skin, ...

Nanoscale structure-property relationships of biological materials, genetic and molecular origins of soft joint tissue diseases, biomaterials under extreme conditions, coupling between ...

Humanoid robots can encourage human tendon cells to grow by stretching them in the same way people do when moving. A robotic shoulder that stretches, presses, and twists lab-grown human tendon tissue ...

A new type of tissue model that more accurately mimics the architecture of the liver could help develop drugs to treat MASLD.