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Divergent trajectories of cellular bioenergetics, intermediary metabolism and systemic redox status in survivors and non-survivors of critical illness
- Source :
- Redox Biology, Vol 41, Iss, Pp 101907-(2021), Redox Biology
- Publication Year :
- 2021
- Publisher :
- Elsevier, 2021.
-
Abstract
- Background Numerous pathologies result in multiple-organ failure, which is thought to be a direct consequence of compromised cellular bioenergetic status. Neither the nature of this phenotype nor its relevance to survival are well understood, limiting the efficacy of modern life-support. Methods To explore the hypothesis that survival from critical illness relates to changes in cellular bioenergetics, we combined assessment of mitochondrial respiration with metabolomic, lipidomic and redox profiling in skeletal muscle and blood, at multiple timepoints, in 21 critically ill patients and 12 reference patients. Results We demonstrate an end-organ cellular phenotype in critical illness, characterized by preserved total energetic capacity, greater coupling efficiency and selectively lower capacity for complex I and fatty acid oxidation (FAO)-supported respiration in skeletal muscle, compared to health. In survivors, complex I capacity at 48 h was 27% lower than in non-survivors (p = 0.01), but tended to increase by day 7, with no such recovery observed in non-survivors. By day 7, survivors’ FAO enzyme activity was double that of non-survivors (p = 0.048), in whom plasma triacylglycerol accumulated. Increases in both cellular oxidative stress and reductive drive were evident in early critical illness compared to health. Initially, non-survivors demonstrated greater plasma total antioxidant capacity but ultimately higher lipid peroxidation compared to survivors. These alterations were mirrored by greater levels of circulating total free thiol and nitrosated species, consistent with greater reductive stress and vascular inflammation, in non-survivors compared to survivors. In contrast, no clear differences in systemic inflammatory markers were observed between the two groups. Conclusion Critical illness is associated with rapid, specific and coordinated alterations in the cellular respiratory machinery, intermediary metabolism and redox response, with different trajectories in survivors and non-survivors. Unravelling the cellular and molecular foundation of human resilience may enable the development of more effective life-support strategies.<br />Graphical abstract Image 1
- Subjects :
- 0301 basic medicine
Medicine (General)
Redox signaling
Bioenergetics
QH301-705.5
Stress physiology
Clinical Biochemistry
Physiology
Mitochondrion
medicine.disease_cause
Biochemistry
Lipid peroxidation
03 medical and health sciences
chemistry.chemical_compound
0302 clinical medicine
R5-920
Respiration
Medicine
Humans
Survivors
Biology (General)
Beta oxidation
chemistry.chemical_classification
Reactive oxygen species
business.industry
Organic Chemistry
Skeletal muscle
Energy metabolism
Mitochondria
030104 developmental biology
medicine.anatomical_structure
chemistry
Oxidative stress
business
Critical illness
Oxidation-Reduction
030217 neurology & neurosurgery
Research Paper
Subjects
Details
- Language :
- English
- ISSN :
- 22132317
- Volume :
- 41
- Database :
- OpenAIRE
- Journal :
- Redox Biology
- Accession number :
- edsair.doi.dedup.....4b4fd19659c1696bd062cf9e51b3a5bc