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 recent years, there have been tremendous advances in tissue engineering, the field of biomaterials research and development that combines living cells with 3D microstructures and biologically ...

Johns Hopkins biomedical engineers unveil Back-Illumination Tomography (BIT), a high-speed microscope that provides ...

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 ...

Modern biomedical research depends on the ability to see what is happening inside biological tissue. Among the available ...

Researchers have developed a hydrogel composed of poly(N-acryloylglycinamide) (PNAGAm) grafted with arginine (R)–glycine (G)–aspartic acid (D)–serine (S) peptide whose elastic modulus can be changed ...

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 ...

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 ...

“We see in our specialty patients who have ear deformities, called microtia, which can be reconstructed, but it's a technically challenging operation that I think very few people in the world do well, ...

It is relatively easy to grow cells in the lab but turning them into realistic models of human tissue is harder. This requires creating an environment that closely mirrors the conditions in the body’s ...