Touch—the first sense to develop in the womb—is fundamental to our bodily experience and our everyday lives. Yet, as the ...

A first-in-human trial shows the feasibility and safety of delivering placenta-derived stem cells during prenatal ...

A series of converging advances in bio-implant technology, from brain-spine interfaces to lab-grown spinal tissue, is bringing the long-elusive goal of spinal cord repair closer to clinical reality.

Northwestern University scientists have developed the most advanced organoid model for human spinal cord injury to date. In a new study, the research team used lab-grown human spinal cord ...

Researchers develop a 3D-printed, RNA-activated implant that silences the PTEN gene to promote nerve regrowth after spinal cord injury.

In a recent study published in Science Advances, a research team led by Profs. DAI Jianwu and ZHAO Yannan at the Institute of Genetics and Developmental Biology (IGDB) of the Chinese Academy of ...

Scientists at Northwestern University have built what they call the most advanced human spinal ...

The 3D implant copies the structure of the spinal cord and, combined with growth-promoting particles, stimulates nerve cells to regrow.

Complex 3D structures of cells called organoids could be used to test treatments for spinal-cord damage that can lead to paralysis.

Researchers from RCSI University of Medicine and Health Sciences have developed a novel implant that delivers tiny growth-promoting particles directly to injured nerve cells, helping them to regrow ...

By fine tuning the motion of molecules, scientists created an injectable therapy that encouraged the growth of neurites and ...

Please provide your email address to receive an email when new articles are posted on . A global study examined 227 individuals with spinal cord injury seen at three centers in Europe, North America.