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 ...

A new human spinal cord organoid model replicates key injury responses, such as inflammation, cell loss, and scar formation.

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 ...

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.

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

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 organoids - ...

Discover the groundbreaking research on organoid models for spinal cord injury, promising new therapies for paralysis recovery.

Can "dancing molecules" repair spinal cord injuries? A new lab model using human organoids shows promising results, reducing scars and regrowing nerve fibers.

Touch—the first sense to develop in the womb—is fundamental to our bodily experience and our everyday lives. Yet, as the least studied of the five senses, it remains somewhat mysterious at the ...

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 ...