New research has found that scar formation after spinal cord injuries is more complex than previously thought. Scientists at Karolinska Institutet have identified two types of perivascular cells as key contributors to scar tissue, which hinders nerve regeneration and functional recovery. These findings, published in Natural Neuroscience, are also relevant for other brain and spinal cord injuries and could lead to targeted therapies for reducing scarring and improving outcomes.
The central nervous system (CNS) has very limited healing abilities. Injuries or autoimmune diseases like multiple sclerosis often lead to permanent functional deficits.
Regardless of the injury’s cause, the body responds by forming a boundary around the damaged tissue, which eventually becomes permanent scar tissue.
Two contributing cell types
While scar tissue seals the damaged area, it also prevents functional repair. After spinal cord injuries, scar tissue blocks the regeneration of nerve fibers that connect the brain with the body, resulting in paralysis after severe injuries.
The research team led by Christian Göritz at Karolinska Institutet has made significant progress in understanding how scar tissue forms in the CNS. The group now identified two distinct types of perivascular cells, which line different parts of blood vessels, as the major contributors to fibrotic scar tissue after spinal cord injury. Depending on the lesion’s location, the two identified cell types contribute differently.
“We found that damage to the spinal cord activates perivascular cells close to the damaged area and induces the generation of myofibroblasts, which consequently form persistent scar tissue,” explains first author Daniel Holl, researcher at the Department of Cell and Molecular Biology.
By examining the process of scar formation in detail, the researchers hope to identify specific therapeutic targets to control fibrotic scarring.
