Natural sources, such as microorganisms (e.g., bacteria, fungi, yeast, and algae) and plant extracts, have acted as eco-friendly precursors for producing nanoparticles with several potential ...

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 ...

S&T researchers develop new method for 3D printing tissue, with potential to speed up and simplify the process of making ...

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 development of artificial grafts that may recapitulate the tissue microarchitecture is one of the most ambitious and complex approaches to understanding molecular mechanisms in an in vitro ...

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 ...

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

Cardiovascular Reparative Medicine and Tissue Engineering (CRMTE) aims to develop future technologies and therapeutic strategies that will serve as treatment for cardiovascular disease. CRMTE includes ...

In the rapidly evolving field of tissue engineering, the development of functional biomaterials and seed cells holds transformative potential for repairing severe tissue defects. These biomaterials, ...