1762: Metabotranscriptomic Signatures in Pediatric Severe Traumatic Brain Injury: A Role for IPA?

Authors

Elora Hussain, Corewell Health West
Surender Rajasekaran, Corewell Health West
Ali Yilmaz, Corewell Health
Juozas Gordevicius
Jeremy Prokop, Corewell Health West
Emily Nonnemacher, Corewell Health West Fellow
Lena Sanfilippo, Corewell Health West
Nadia Ashrafi, Corewell Health
Romana Ashrafi Mimi, Corewell Health
Stewart Graham, Corewell Health

Document Type

Conference Proceeding

Publication Date

1-2025

Publication Title

Critical Care Medicine

Abstract

Introduction: Traumatic brain injury (TBI) is a leading cause of childhood death and disability. Current care is primarily supportive with no therapies shown to improve outcomes. We hypothesized that a multi-omics approach could reveal unique metabolic patterns supported by transcriptomics that may have therapeutic implications in pediatric severe TBI.

Methods: After IRB approval (CWH 2021-096) and informed consent, seventeen pediatric severe TBI patients ages ≥ 1 and ≤ 21 years were prospectively enrolled. Serial blood samples were collected at 24±12 hours, 48±12 hours, and on day 9±12 hours. Demographics and clinical variables were extracted from the medical record. Blood samples from ten control patients were obtained at a single timepoint. RNA expression was extrapolated using matching reads to human genes using Salmon quasi-alignments. Metabolomic profiling was performed using 1H NMR spectroscopy, and direct injection/liquid chromatography coupled with mass spectrometry. High quality transcripts from RNA-expression data were assessed for association with metabolite abundance, using linear regression models and adjustment for individual age and sex, and potential unknown and unwanted variation inferred from the data.

Results: Severe TBI patients revealed unique metabolite patterns with timepoint 3 (recovery phase) being the most unique, with 21.5 % of all RNA to metabolite associations. Serum Indole-3-prioprionic acid (IPA) was significantly reduced in TBI patients compared to controls (1.74 uM in controls to 0.12uM at timepoint 3; P< 0.05). The IPA signature correlated with multiple genes associated with IPA production. These genes were also related to production of multiple lipids such as triglycerides and ceramides. Some examples include: ATXN7L3,ICAM2, BTNL8, and genes regulating lipid pathways.

Conclusions: We found a significant decrease in serum IPA levels in pediatric severe TBI in the acute period, compared to a later time point and controls. IPA is a deamination product of tryptophan formed by gut flora, demonstrating antioxidant effects and enhanced axonal recovery. Further studies are needed to examine the relationship between potential gut dysbiosis after severe TBI, and potential therapeutic implications of this novel finding in a pediatric cohort.

Volume

53

Issue

1

Recommended Citation

Hussain E, Rajasekaran S, Yilmaz A, Gordevicius J, Prokop J, Nonnemacher E et al [Sanfilioop L, Ashrafi N, Ashrafi Mimi R, Graham SF] 1762: Metabotranscriptomic signatures in pediatric severe traumatic brain injury: a role for ipa? Crit Care Med.2025 Jan; 53(1). doi: 10.1097/01.ccm.0001105712.04108.d7

Comments

The Society of Critical Care Medicine's 54th Critical Care Congress, February 23-25, 2025, Orlando, FL.

DOI

10.1097/01.ccm.0001105712.04108.d7