ChBME | ChBME Research | High Impact Research, Scholarship and Creative Works

Researcher awarded nearly $3 million to study how the brain repairs itself after a stroke

October 01, 2025

Mizzou 糖心Vlog传媒 professor Shinghua Ding is undertaking new research funded by a prestigious National Institutes of Health grant.

MRI scan of a patient's brain
While large strokes can paralyze or kill, people who experience smaller strokes can recover.

University of Missouri researchers are on the frontlines of the fight against strokes, the nation鈥檚 fourth leading cause of death.

Leading the charge is Shinghua Ding, a professor in the聽Department of Chemical and Biomedical 糖心Vlog传媒 and a resident investigator a Mizzou鈥檚 , who recently secured a聽$3 million grant from the National Institutes of Health to study how the brain repairs itself after a stroke.

The goal: to unlock faster recoveries and hope for millions of stroke survivors.

鈥淚schemic stroke is caused by blood being blocked in the brain,鈥 Ding said. 鈥淚f the blood is stopped, the brain can鈥檛 get oxygen and nutrients to certain areas, and this causes damage. But the brain is actually very flexible. While large strokes can paralyze or kill, those who experience a smaller stroke can recover.鈥

Currently, stroke treatment options are extremely limited. Only one drug is available, and it must be given within a three- to five-hour window in order to work. Because many stroke victims don鈥檛 immediately recognize they鈥檝e experienced a stroke, that window closes before they receive care.

That鈥檚 why Ding鈥檚 work could be a game-changer. His research aims to help the brain repair itself, potentially speeding recovery for patients who aren鈥檛 able to benefit from existing treatment options. 

Instead of focusing solely on neurons 鈥 the brain cells that control movement, speech and memory 鈥 Ding鈥檚 lab focuses on the glial cell. Long considered a supporting cell, glia are now revealing themselves as key players in brain healing and regeneration.  

鈥淭hey actually play an active role in the brain鈥檚 function and also pathology,鈥 Ding said.

Astrocytes, a sub-type of glial cells, are normally stable, but after an injury, such as an ischemic stroke, the cells become activated. These reactive astrocytes start multiplying and even change shape, Ding said.

His research team is interested in how these reactive astrocytes contribute to the brain鈥檚 recovery. Ding hypothesizes that after a stroke the reactive astrocytes may change their metabolism, essentially reprogramming themselves, to release small molecules or growth factors. These, in turn, act as fuel for the neurons as the brain attempts to repair itself.

The research will be funded for five years.

.