Deep learning derived input function in dynamic [18F]FDG PET imaging of mice
Permanent lenke
https://hdl.handle.net/10037/34901Dato
2024-04-11Type
Journal articleTidsskriftartikkel
Peer reviewed
Forfatter
Kuttner, Samuel; Luppino, Luigi Tommaso; Convert, Laurence; Sarrhini, Otman; Lecomte, Roger; Kampffmeyer, Michael Christian; Sundset, Rune; Jenssen, RobertSammendrag
Dynamic positron emission tomography and kinetic modeling play a critical role
in tracer development research using small animals. Kinetic modeling from
dynamic PET imaging requires accurate knowledge of an input function,
ideally determined through arterial blood sampling. Arterial cannulation in
mice, however, requires complex, time-consuming and terminal surgery,
meaning that longitudinal studies are impossible. The aim of the current work
was to develop and evaluate a non-invasive, deep-learning-based prediction
model (DLIF) that directly takes the PET data as input to predict a usable input
function. We first trained and evaluated the DLIF model on 68 [18F]
Fluorodeoxyglucose mouse scans with image-derived targets using cross
validation. Subsequently, we evaluated the performance of a trained DLIF
model on an external dataset consisting of 8 mouse scans where the input
function was measured by continuous arterial blood sampling. The results
showed that the predicted DLIF and image-derived targets were similar, and
the net influx rate constants following from Patlak modeling using DLIF as
input function were strongly correlated to the corresponding values obtained
using the image-derived input function. There were somewhat larger
discrepancies when evaluating the model on the external dataset, which could
be attributed to systematic differences in the experimental setup between the
two datasets. In conclusion, our non-invasive DLIF prediction method may be
a viable alternative to arterial blood sampling in small animal [18F]FDG imaging.
With further validation, DLIF could overcome the need for arterial cannulation
and allow fully quantitative and longitudinal experiments in PET imaging
studies of mice.
Forlag
Frontiers MediaSitering
Kuttner, Luppino, Convert, Sarrhini, Lecomte, Kampffmeyer, Sundset, Jenssen. Deep learning derived input function in dynamic [18F]FDG PET imaging of mice. Frontiers in Nuclear Medicine. 2024;4Metadata
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