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@INPROCEEDINGS{Usman:1053159,
author = {Usman, Khalid and Memis, Ceren and Lennartz, Manfred and
Grunwald, Dirk and Hidehiro, Iida and Scheins, Jürgen and
Shah, Jon and Ziemons, Karl and Tellmann, Lutz and Meurer,
Tobias and Lohmann, Philipp and Herzog, Hans and Wiesmann,
Martin and Lerche, Christoph},
title = {{D}esign and {C}onstruction of a {G}eometrical and {H}ead
{P}hantom with {I}nternal {C}arotid {I}nserts for {F}low
{S}imulation in {I}mage-{D}erived {I}nput {F}unction with
3{T} and 7{T} {MR}-{B}rainpet {I}nsert {S}tudies.},
reportid = {FZJ-2026-01491},
year = {2025},
abstract = {Purpose: Quantitative brain studies with positron emission
tomography (PET) often require an arterial input function
(AIF), which traditionally requires arterial cannulation.
However, this is invasive. An alternative, non-invasive
method is to use the image-derived input function (IDIF)
derived from the activity concentration in the internal
carotid arteries (ICAs) in the images. To achieve an
accurate IDIF, validation and optimization of IDIF
estimations using phantoms with controlled methodological
parameters are required. The goal of this study was to
develop: 1) a geometrical phantom with ICA inserts as a
reliable baseline for IDIF studies, and 2) an
anthropomorphic head phantom with realistic anatomical
features to enhance IDIF accuracy and expand validation
applications.Methods: Phantom 1) was based on a combination
of a cylindrical quality-control phantom already available
in our institute [1] and an additional ICA insert [2].
Phantom 2), based on previous work [3], replicates the human
head contour and brain anatomy. Segmentation of grey matter
(GM), white matter (WM), and scalp was performed using 3D
Slicer v5.4.0, combining manual and semi-automatic threshold
methods. ICA structures were extracted from magnetic
resonance angiography data and refined using CAD software.
The GM, WM, and ICA compartments were designed as fillable
hollow compartments.Results: Both 3D-printed phantoms
include watertight compartments capable of holding different
radiotracer concentrations and ICA dynamic simulations. The
neck structure of the head phantom is extended to facilitate
secure attachment to mechanical holders, enabling precise
motion simulations during PET/MR studies.Conclusion: The
cylindrical phantom with an ICA insert is currently in the
printing phase and the head phantom is in the final
development phase (equivalent tissue materials and printing
tests). After successfully printing both phantoms, PET/MR
acquisitions will be performed for testing and validation.
The updated status of this work will be presented during the
conference.},
month = {Jul},
date = {2025-07-27},
organization = {American Association of Physicists in
Medicine, Washington (USA), 27 Jul 2025
- 30 Jul 2025},
subtyp = {Invited},
cin = {INM-4},
cid = {I:(DE-Juel1)INM-4-20090406},
pnm = {5253 - Neuroimaging (POF4-525)},
pid = {G:(DE-HGF)POF4-5253},
typ = {PUB:(DE-HGF)24},
url = {https://juser.fz-juelich.de/record/1053159},
}
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