University of Adelaide researchers have confirmed that abnormalities in a common brain chemical are linked to sudden infant death syndrome (SIDS).

In the first study of its kind looking at babies outside the United States, researchers from the University of Adelaide’s Adelaide Medical School investigated 41 cases of SIDS deaths and discovered striking abnormalities in chemical serotonin within the brain.

Serotonin, otherwise known as 5-HT, is a neurotransmitter found in different parts of the human body, including the central nervous system. Among its many roles, serotonin is involved in the regulation of sleep, and also control of the cardiovascular and respiratory systems.

This latest research, published in the Journal of Neuropathology & Experimental Neurology, supports the concept that brain stem dysfunction, resulting in significantly altered serotonin expression, is associated with some SIDS deaths.

SIDS is the sudden unexpected death of an infant under 1 year of age that cannot be explained after a thorough investigation, including an autopsy. It is the leading cause of death in infants between 1 month and 1 year of age in Australia and the developed world.

The research was conducted by Fiona Bright, PhD, under the supervision of University of Adelaide Professor of Pathology Roger Byard, BMedSci, MBBS, MMedSci, MD.

Her work builds on research conducted in the United States at the Boston Children’s Hospital and Harvard Medical School, whereBright was based for 18 months during her combined studies.

“Our research is significant because it has confirmed that abnormalities in serotonin in the brain are most definitely linked to cases of SIDS. This helps to support the findings of the American research,”Bright says in a release.

“Serotonin is a key neurochemical that plays an important role in the control and management of the complex respiratory, cardiovascular, and autonomic systems within the human infant brain stem.

“Our research suggests that alterations in these neurochemicals may contribute to brainstem dysfunction during a critical postnatal developmental period. As a result, this could lead to an inability of a SIDS infant to appropriately respond to life-threatening events, such as lack of oxygen supply during sleep.

“Notably, the SIDS cases we studied were all linked to at least one major risk factor for SIDS, with more than half of the infants found in an adverse sleeping position and having had an illness one month prior to death.”

Byard adds: “Better understanding of the complex role of these neurochemicals, and the exact causes of their dysfunction in the brain, will help future research to develop potential biomarkers for infants at increased risk of SIDS.

“Ultimately, we hope that this work will lead to improved prevention strategies, helping to save baby’s lives and the emotional trauma experienced by many families.”