Spinal cord injury often triggers a cascade of secondary damage that severely limits functional recovery, largely driven by ...

A research group at the Universidade Federal do Rio de Janeiro has advanced polylaminin, a laminin-based biomaterial, from ...

A secondary stress signaling pathway in the response to optic axon injury is an unexpectedly strong contributor to both neurodegeneration and axon regenerative potential.

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 ...

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 - ...

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 ...

Growing neurons rely on chemical cues to find their targets, but new research shows that the brain’s physical properties help ...

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 - ...

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

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

Researchers say study identifies location of oligodendrocytes in the brain, and integrates information about gene expression and the structural features of neurons.