Inside Pediatrics Magazine Fall/Winter 2025

NEONATOLOGY

Using Mitochondrial Genetics to Predict BPD

SOLVING THE PUZZLE FOR EARLY INTERVENTION AND INSIGHT INTO RACIAL DISPARITIES

B ronchopulmonary dysplasia (BPD), a chronic lung condition affecting some extremely preterm infants, continues to be a significant clinical challenge in neonatology. While often lifesaving, supplemental oxygen can be a key contributor to long-term pulmonary complications in this vulnerable population. At Children’s of Alabama and the University of Alabama at Birmingham (UAB), researchers are exploring how mitochondrial function may hold the key to understanding and preventing BPD. Jegen Kandasamy, M.D., an associate professor in the Division of Neonatology at UAB, leads a multidisciplinary team supported by a research grant dedicated to studying mitochondrial dysfunction in BPD. The research centers on individual differences in how mitochondrial DNA (mtDNA) haplogroups—genetic variations inherited maternally and varying by ethnicity—may influence an infant’s susceptibility to lung injury from oxygen exposure, particularly hyperoxia. “Hyperoxia is a double-edged sword,” Kandasamy said. “It’s essential for survival, yet it introduces oxidative stress that preterm lungs are poorly equipped to handle. Our research is aimed at understanding how mitochondrial genetics impact that response.” Using collected blood samples and clinical data from preterm infants, Kandasamy’s team is working to identify mtDNA haplogroups associated with higher BPD risk. The goal is to develop precise, genetically informed risk profiles that allow for early intervention. Hopefully, this will improve outcomes while addressing racial disparities in BPD prevalence and severity.

Jegen Kandasamy, M.D.

“Understanding how mitochondrial genetics intersect with environmental exposures can help us identify at-risk infants earlier and intervene more effectively.”

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Inside Pediatrics | Children’s of Alabama