Organ failure impacts millions of patients each year and costs hundreds of billions of US Dollars. Over the last 30 years, scientists have utilized a combination of tools, methods, and molecules of ...

Regenerative medicine combines tissue engineering and cell therapies to repair or replace damaged human tissues and organs. Key applications include treating osteoarthritis with mesenchymal stem cells ...

The field of tissue engineering and regenerative medicine has seen remarkable progress with the advent of 3D bioprinting technologies and the development of ...

Primary tissues are fixed by the magnetic microneedle scaffold and cut into small pieces by a slicing device, which are imparted with magnetic responsiveness because of the encapsulated microneedle ...

3D bioprinting combines cells, growth factors, and biomaterials to fabricate biomedical parts. The process requires special “bio-inks,” often made of materials like alginate or gelatin. A key goal is ...

These fields aim to facilitate healing and restore lost function in damaged or diseased tissues and organs by integrating scaffolds, cells, and biological signaling molecules. This combination aims to ...

The study shows that fat tissue, when processed and cultured in a specific way, can self-organize into structures resembling bone marrow, pancreatic islets, and even neural tissue. These organoids ...

Researchers at RIT are developing non-invasive technology that will better assess cardiac tissue response to thermal energy, a common therapy approach for both cancer and cardiac arrhythmia treatments ...