A cell therapy developed by University of California, Irvine, (UCI) researchers may help improve memory and prevent seizures in mice following traumatic brain injury.

In their study, published recently in Nature Communications, the UCI team transplanted embryonic progenitor cells capable of generating inhibitory interneurons, a specific type of nerve cell that controls the activity of brain circuits, into the brains of mice with traumatic brain injury. They targeted the hippocampus, a brain region responsible for learning and memory.

The researchers discovered that the transplanted neurons migrated into the injury where they formed new connections with the injured brain cells and thrived long term. Within a month after treatment, the mice showed signs of memory improvement, such as being able to tell the difference between a box where they had an unpleasant experience from one where they did not.

They were able to do this just as well as mice that never had a brain injury. The cell transplants also prevented the mice from developing epilepsy, which affected more than half of the mice who were not treated with new interneurons, a media release from University of California – Irvine explains.

“Inhibitory neurons are critically involved in many aspects of memory, and they are extremely vulnerable to dying after a brain injury,” says Robert Hunt, PhD, assistant professor of anatomy and neurobiology at UCI School of Medicine, who led the study.

“While we cannot stop interneurons from dying, it was exciting to find that we can replace them and rebuild their circuits.”

This is not the first time Hunt and his team has used interneuron transplantation therapy to restore memory in mice. In 2018, the UCI team used a similar approach, delivered the same way but to newborn mice, to improve memory of mice with a genetic disorder.

“The idea to regrow neurons that die off after a brain injury is something that neuroscientists have been trying to do for a long time,” Hunt adds, in the release. “But often, the transplanted cells don’t survive, or they aren’t able to migrate or develop into functional neurons.”

To further test their observations, Hunt and his team silenced the transplanted neurons with a drug, which caused the memory problems to return.

“It was exciting to see the animals’ memory problems come back after we silenced the transplanted cells, because it showed that the new neurons really were the reason for the memory improvement,” Bingyao Zhu, a junior specialist and first author of the study, comments.

The next step, according to the researchers, is to create interneurons from human stem cells.

“So far, nobody has been able to convincingly create the same types of interneurons from human pluripotent stem cells,” Hunt continues. “But I think we’re close to being able to do this.”

[Source(s): University of California – Irvine, Science Daily]