Organoids modeled on the structure of the human spinal cord have been shown to match the behavior of an injured spine. Now, a treatment that has worked well in mice has been applied to the organoids, ...

Northwestern University scientists have developed the most advanced organoid model for human spinal cord injury to date. In a new study published in Nature Biomedical Engineering, the research team ...

By fine tuning the motion of molecules, scientists created an injectable therapy that encouraged the growth of neurites and neurons in damaged spinal organoids.

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

The new organoids were grown in the lab for up to 40 days, and they mimicked the central nervous system of an 11-week-old human embryo. When you purchase through links on our site, we may earn an ...

Add Yahoo as a preferred source to see more of our stories on Google. Scientists have taken a major step toward treating spinal cord injuries that cause paralysis. In lab dishes, researchers at ...

Spinal cord injuries cause permanent paralysis in part because inflammation, cell death, and glial scarring block nerve regeneration, and there has been no reliable human tissue model to test ...

Prof. Tal Dvir, Head of the Sagol Center for Regenerative Biotechnology, Head of the Nanotechnology Center at Tel Aviv University, and Chief Scientist of the biotech company Matricelf. The surgery is ...

Injuries in the central nervous system (CNS)—such as those in the spinal cord—trigger glial scar formation, which inhibits nerve regeneration from healthy neurons surrounding the damage. This results ...

Fluorescent micrographs showing increased neurite outgrowth from a human spinal cord organoid treated with fast-moving “dancing molecules” (left) compared to one treated with slow-moving molecules ...