Title (eng)
[18F]FDG-PET provides insights into the liver-brain axis and confirms SUVgluc as a surrogate for MRGlu in a mouse model of liver fibrosis
Author
Thomas Wanek
Mari Teuter
Asha Balakrishnan
Tobias L. Ross
Frank M. Bengel
Michael Ott
Jens P. Bankstahl
Abstract (eng)
Purpose
The liver-brain axis regulates metabolic homeostasis, with glucose metabolism playing a key role. Liver dysfunction, such as fibrosis, may impact brain metabolism and consequently, brain function. Positron emission tomography (PET) imaging provides a non-invasive approach to study glucose metabolism in both organs. A recent longitudinal PET/CT study utilizing 2-deoxy-2-[18F]-fluoro-d-glucose ([18F]FDG) amongst other radiotracers revealed significant metabolic changes in the liver in a mouse model of liver fibrosis. Here, we retrospectively analyzed those data to quantify potential associated changes in brain glucose metabolism.
Procedures
Eleven male C57BL/6N mice underwent repeated PET imaging with [18F]FDG at baseline, pre-fibrosis, fibrosis, and remission stages. Cerebral glucose metabolism was assessed using standardized uptake value (SUV), blood glucose-corrected SUV (SUVgluc), and kinetic modeling (Patlak and two-tissue compartment models) for calculation of the glucose metabolic rate (MRGlu).
Results
Both SUVgluc and MRGlu significantly decreased during pre-fibrosis and fibrosis on whole brain level and recovered at remission. SUVgluc statistical parametric mapping identified multiple brain areas with reduced glucose metabolism, which was confirmed by regional analysis showing progressive reduction in SUVgluc. Correlation analyses confirmed SUVgluc as a reliable surrogate for MRGlu, unlike uncorrected SUV. Liver [18F]FDG uptake increased during fibrosis and normalized at remission, mirroring changes in blood glucose concentrations.
Conclusions
[18F]FDG PET imaging revealed that liver fibrosis alters glucose metabolism in both liver and brain, emphasizing the potential of molecular imaging for future assessment of metabolic interaction between liver and brain. [18F]FDG uptake in terms of SUVgluc strongly correlated with MRGlu from kinetic modeling, supporting its utility as a valid surrogate parameter to quantify cerebral glucose metabolism in mice.
Keywords (eng)
[18F]FDGPETQuantificationPreclinical ImagingBrain MetabolismLiver Fibrosis
Type (eng)
Language
[eng]
Persistent identifier
Is in series
Title (eng)
Nuclear Medicine And Biology
Volume
150
ISSN
1872-9614
Issued
2025
Number of pages
9
Publication
Elsevier
Version type (eng)
Date issued
2025
Access rights (eng)
License
Rights statement (eng)
© 2025 The Authors
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Persistent identifier
DOI
https://phaidra.vetmeduni.ac.at/o:4463
https://doi.org/10.1016/j.nucmedbio.2025.109095 - Content
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