• A dual-function peptide developed for in-situ engineering native extracellular matrix. • The dual-function peptide specifically anchors endogenous endothelial cells to extracellular matrix. Ischemic ...

You can regrow damaged skin in the area, sure—but also bone, tissue, and nerves.

In a study published in Cell Stem Cell, researchers led by Profs. Dai Jianwu and Zhao Yannan from the Institute of Genetics and Developmental Biology of the Chinese Academy of Sciences have ...

Various tissues and organs in the human body, such as nerves, heart, bones, and skin, rely on bioelectrical signals to maintain function and support regeneration. Although conventional electrical ...

Advanced biomaterials play a central role in the development of functional platforms for biomedical repair and regeneration. A wide range of material ...

Scientists have developed a breakthrough injectable biomaterial that travels through the bloodstream to repair damaged tissue ...

Recently, a research team from Chongqing Medical University, led by Prof. Wei Huang, Dr. Wei Bao, and Dr. Yiting Lei, has successfully developed a novel engineered extracellular matrix (eECM) to ...

Researchers in Rochester Institute of Technology’s Tissue Regeneration and Mechanobiology (TRAM) Laboratory are investigating a new approach that could change how fibrosis is treated across organs in ...

New research from Stanford, Texas A&M, and Wake Forest has revealed biological and genetic mechanisms that allow mammals, ...

Researchers at the Centro Nacional de Investigaciones Cardiovasculares (CNIC) have discovered a specialized population of neutrophils in the skin that produce extracellular matrix components, helping ...