News Release

Newly identified lipid in breast milk might reduce cerebral palsy in infants

In animal studies, the fat molecule encourages stem cells to generate new cells that produce the brain’s white matter

Peer-Reviewed Publication

Duke University Medical Center

Newly Identified Lipid in Breast Milk Might Reduce Cerebral Palsy in Infants

image: In experiments using neonatal mice, researchers at Duke Health have identified a fatty molecule in breast milk that triggers a process in which stem cells in the brain produce cells that create new white matter, reversing brain injury. view more 

Credit: Duke Health

While it’s known that the white matter loss will lead to neurological deficits, there is currently no treatment to help these infants avoid the outcome.

In experiments using neonatal mice, researchers at Duke Health have identified a fatty molecule in breast milk that triggers a process in which stem cells in the brain produce cells that create new white matter, reversing the injury. 

The study appears Aug. 3 in the journal Cell Stem CellEric Benner, M.D., Ph.D., is the study’s corresponding author and is a distinguished assistant professor in the Department of Pediatrics at Duke University School of Medicine. Benner said further study in a clinical trial is needed, but the finding is promising.

“Developing therapies for children -- especially such medically fragile children -- is very difficult to do because there are justifiably strict safety concerns,” Benner said. “The fact that this molecule is already found in something that is safe for premature babies – breast milk – is extremely encouraging.

“It’s been known that fats in breast milk benefit a child’s brain development, but there are many types of fats in breast milk,” Benner said. “This work has identified a lipid molecule in breast milk that promotes white matter development. Now, we can begin to develop a therapy that isolates and delivers this lipid in a way that is safe for the unique challenges of these infants.”

Benner is a neonatologist at Duke University and one of the co-founders of Tellus Therapeutics, a Duke spinout company developed with the help of the Duke University Office for Translation & Commercialization to bring this therapy from the bench into the neonatal intensive care unit.

The fatty molecule identified in the study will be administered intravenously to patients in an upcoming clinical trial. This is significant because many of the infants who are part of this vulnerable population also have gastrointestinal issues and cannot safely be given milk or medication by mouth.

 

The lipid molecule enters the brain and binds with stem cells there, encouraging the stem cells to become or produce a type of cell called oligodendrocytes. 

The oligodendrocytes are like a hub that allow for the production of white matter in the central nervous system. This newly produced white matter in pre-term infants prevents the neurological damage that would otherwise impact the child’s ability to move – the hallmarks of cerebral palsy.

“The timing of brain injury is extremely difficult to predict, thus a treatment that could be safely given to all preterm babies at risk would be revolutionary,” said Agnes Chao, M.D., a former fellow in the Division of Neonatology and first author of the paper.

“As a neonatologist, I'm so excited that I may be able to offer a treatment to families with babies that are affected by preterm brain injury who would otherwise have no other options,” Chao said.

In addition to Benner and Chao, study authors include Pavle Matak, Kelly Pegram, James Powers, Collin Hutson, Rebecca Jo, Laura Dubois, J. Will Thompson, P. Brian Smith, Jason R. Gibson, Noelle E. Younge, Blaire Rikard, Simon G. Gregory, Ronald N. Goldberg, Mari L Shinohara, Estefany Y. Reyes, Chunlei Liu.

The study was funded by the National Institutes of Health (1R01NS114578, T32HD094671, K12HD043494, T32HD043728, R01AG070826, R01MH127104, P41EB015897, 1UL1-TR002553), Jean and George Brumley Jr. Neonatal Perinatal Research Institute, with additional support from the Duke Scholars Award from the School of Medicine, Duke University Center for In Vivo Microscopy, and the National Center for Advancing Translational Sciences.

Download illustrations here: https://duke.box.com/s/47rkw3hpn4tu5lwf1s60q5nm4edagws8

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