Accurate detection of acute sleep deprivation using a metabolomic biomarker—A machine learning approach

Katherine Jeppe; Suzanne Ftouni; Brunda Nijagal; Leilah K. Grant; Steven W. Lockley; Shantha M.W. Rajaratnam; Andrew J.K. Phillips; Malcolm J. McConville; Dedreia Tull; Clare Anderson

doi:10.1126/sciadv.adj6834

Accurate detection of acute sleep deprivation using a metabolomic biomarker—A machine learning approach

Katherine Jeppe, Suzanne Ftouni, Brunda Nijagal, Leilah K. Grant, Steven W. Lockley, Shantha M.W. Rajaratnam, Andrew J.K. Phillips, Malcolm J. McConville, Dedreia Tull, Clare Anderson

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Abstract

Sleep deprivation enhances risk for serious injury and fatality on the roads and in workplaces. To facilitate future management of these risks through advanced detection, we developed and validated a metabolomic biomarker of sleep deprivation in healthy, young participants, across three experiments. Bi-hourly plasma samples from 2 × 40-hour extended wake protocols (for train/test models) and 1 × 40-hour protocol with an 8-hour overnight sleep interval were analyzed by untargeted liquid chromatography–mass spectrometry. Using a knowledge-based machine learning approach, five consistently important variables were used to build predictive models. Sleep deprivation (24 to 38 hours awake) was predicted accurately in classification models [versus well-rested (0 to 16 hours)] (accuracy = 94.7%/AUC 99.2%, 79.3%/AUC 89.1%) and to a lesser extent in regression (R² = 86.1 and 47.8%) models for within- and between-participant models, respectively. Metabolites were identified for replicability/future deployment. This approach for detecting acute sleep deprivation offers potential to reduce accidents through “fitness for duty” or “post-accident analysis” assessments.

Original language	English
Article number	eadj6834
Number of pages	17
Journal	Science Advances
Volume	10
Issue number	10
DOIs	https://doi.org/10.1126/sciadv.adj6834
Publication status	Published - 8 Mar 2024
Externally published	Yes

Keywords

Sleep disorders
Sleep deprivation
metabolomic biomarkers
Machine learning

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1126/sciadv.adj6834Licence: CC BY

Final published versionFinal published version, 3.25 MBLicence: CC BY

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title = "Accurate detection of acute sleep deprivation using a metabolomic biomarker—A machine learning approach",

abstract = "Sleep deprivation enhances risk for serious injury and fatality on the roads and in workplaces. To facilitate future management of these risks through advanced detection, we developed and validated a metabolomic biomarker of sleep deprivation in healthy, young participants, across three experiments. Bi-hourly plasma samples from 2 × 40-hour extended wake protocols (for train/test models) and 1 × 40-hour protocol with an 8-hour overnight sleep interval were analyzed by untargeted liquid chromatography–mass spectrometry. Using a knowledge-based machine learning approach, five consistently important variables were used to build predictive models. Sleep deprivation (24 to 38 hours awake) was predicted accurately in classification models [versus well-rested (0 to 16 hours)] (accuracy = 94.7%/AUC 99.2%, 79.3%/AUC 89.1%) and to a lesser extent in regression (R2 = 86.1 and 47.8%) models for within- and between-participant models, respectively. Metabolites were identified for replicability/future deployment. This approach for detecting acute sleep deprivation offers potential to reduce accidents through “fitness for duty” or “post-accident analysis” assessments.",

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Accurate detection of acute sleep deprivation using a metabolomic biomarker—A machine learning approach

Abstract

Keywords

UN SDGs

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