Journal
AMERICAN JOURNAL OF PHYSIOLOGY-LUNG CELLULAR AND MOLECULAR PHYSIOLOGY
Volume 321, Issue 1, Pages L79-L90Publisher
AMER PHYSIOLOGICAL SOC
DOI: 10.1152/ajplung.00077.2021
Keywords
acute respiratory distress syndrome (ARDS); ARDS heterogeneity; ARDS metabolic fingerprints; ARDS metabolomics; ARDS subphenotypes
Categories
Funding
- Alberta Innovates-Health Solutions
- Alberta's Health Research Innovation Strategy
- Faculty of Medicine (Cumming School of Medicine), University of Calgary
- Alberta Health Services
- Lung Association of Alberta
- NWT
- Canadian Intensive Care Foundation
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This study aimed to identify metabolic fingerprints of ARDS, comparing them with ICU controls. The subphenotypes and clinical subgroups of ARDS were found to have distinct metabolic profiles, with involvement of serine-glycine metabolism. These identified metabolic fingerprints are not diagnostic biomarkers for ARDS, and further research is needed for generalizability.
In this study, we aimed to identify acute respiratory distress syndrome (ARDS) metabolic fingerprints in selected patient cohorts and compare the metabolic profiles of direct versus indirect ARDS and hypoinflammatory versus hyperinflammatory ARDS. We hypothesized that the biological and inflammatory processes in ARDS would manifest as unique metabolomic fingerprints that set ARDS apart from other intensive care unit (ICU) conditions and could help examine ARDS subphenotypes and clinical subgroups. Patients with ARDS (n = 108) and ICU ventilated controls (n = 27) were included. Samples were randomly divided into 2/3 training and 1/3 test sets. Samples were analyzed using H-1 nuclear magnetic resonance spectroscopy and gas chromatography-mass spectrometry. Twelve proteins/cytokines were also measured. Orthogonal partial least squares discriminant analysis (OPLS-DA) was used to select the most differentiating ARDS metabolites and protein/cytokines. Predictive performance of OPLS-DA models was measured in the test set Temporal changes of metabolites were examined as patients progressed through ARDS until clinical recovery. Metabolic profiles of direct versus indirect ARDS subgroups and hypoinflammatory versus hyperinflammatory ARDS subgroups were compared. Serum metabolomics and proteins/cytokines had similar area under receiver operator curves when distinguishing ARDS from ICU controls. Pathway analysis of ARDS differentiating metabolites identified a dominant involvement of serine-glycine metabolism. In longitudinal tracking, the identified pathway metabolites generally exhibited correction by 7-14 days, coinciding with clinical improvement. ARDS subphenotypes and clinical subgroups were metabolically distinct. However, our identified metabolic fingerprints are not ARDS diagnostic biomarkers, and further research is required to ascertain generalizability. In conclusion, patients with ARDS are metabolically different from ICU controls. ARDS subphenotypes and clinical subgroups are metabolically distinct.
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