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Home NEWS Science News Technology

Longitudinal Urine Metabolomics Predicts High-Grade Brain Injury in Very Preterm Infants

Bioengineer by Bioengineer
July 15, 2026
in Technology
Reading Time: 2 mins read
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Longitudinal Urine Metabolomics Predicts High-Grade Brain Injury in Very Preterm Infants
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Preterm birth leaves many infants vulnerable to brain injury, but detecting damage early is notoriously difficult. A new viral science news report highlights research that uses longitudinal urine metabolomics to forecast high-grade brain injury before magnetic resonance imaging (MRI) can reveal it.

In a prospective study, researchers collected urine from 64 very preterm infants (<32 weeks gestation) on multiple postnatal days: days 1–4, 6, 8, 28, and again at term-equivalent age. The goal was to map how small-molecule signatures in urine change over time in relation to later neurologic outcomes.

Across the samples, investigators quantified 43 metabolites and neurotransmitters using LC-MS/MS, a technique that separates and identifies compounds based on mass and chromatographic behavior. Instead of relying on a single time point, the team analyzed temporal trajectories to capture evolving biochemical processes during brain development.

Brain injury severity was measured with an MRI-derived Global Brain Abnormality Score. This composite metric summarizes injury across major regions, including white matter, cortex, deep grey matter, and cerebellum—providing a global view of damage rather than a single localized endpoint.

The key finding was that urinary metabolites displayed distinct time-linked patterns that correlated with global injury severity. Notably, early elevations in energy-related molecules—such as lactate and α-hydroxybutyrate—appeared first, suggesting metabolic stress in the earliest window after birth.

Between postnatal days 3 and 6, these early signals were followed by broader biochemical disruptions spanning amino acids, fatty acids, and the tryptophan–kynurenine pathway. Together, these pathway shifts point to mechanisms that can include mitochondrial dysfunction, oxidative stress, and excitotoxicity.

For severe injury cases, multi-block modeling achieved striking performance: at the default decision threshold, it identified 100% of severe injury patients, with an area under the curve (AUC) of 0.849, using only day 3–6 data. This suggests a potentially actionable neurosurveillance window for risk stratification.

Region-specific MRI prediction was even more varied. The model was strongest for cerebellar anomaly (AUC 0.891 in the full model) and showed more moderate but still meaningful performance for white matter in an early model (AUC 0.724).

Overall, the study suggests that urine metabolomics may detect brain injury dynamics well before term-equivalent MRI, with days 3–6 emerging as a particularly informative period. If validated, this noninvasive biochemical early-warning system could enable earlier monitoring and potentially guide neuroprotective interventions for very preterm infants.

Subject of Research: Preterm infant brain injury prediction using longitudinal urine metabolomics

Article Title: Longitudinal urine metabolomics predicts high-grade brain injury in very preterm infants

Article References: Kuncewicz, T., Zasada, M., Olszewska, M. et al. Longitudinal urine metabolomics predicts high-grade brain injury in very preterm infants. Pediatr Res (2026). https://doi.org/10.1038/s41390-026-05289-6

Image Credits: AI Generated

DOI: 10.1038/s41390-026-05289-6

Keywords: Preterm infants; urine metabolomics; LC-MS/MS; brain injury; MRI; neurosurveillance window; mitochondrial dysfunction; oxidative stress; excitotoxicity

Tags: biomarkers for early brain damage detectionbiomarkers predicting neurological outcomesearly prediction of high-grade brain injuryLC-MS/MS in neonatal researchlongitudinal urine metabolomics in preterm infantsmetabolic signatures of brain injurymetabolic trajectories in brain developmentMRI-based global brain injury assessmentneonate neurodevelopment biomarkerspreterm infant neuroprotection strategiestime-course analysis of urine metabolitesurine-based diagnostic tools for neonates

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