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@MISC{Estrada:270875,
author = {Estrada, Santiago and Kügler, David and Bahrami Rad, Emad
and Xu, Peng and Mousa, Dilshad and Breteler, Monique M. B.
and Aziz, N. Ahmad and Reuter, Martin},
othercontributors = {Estrada, Santiago and Kügler, David and Bahrami, Emad and
Xu, Peng and Mousa, Dilshad and Breteler, Monique M. B. and
Aziz, N. Ahmad and Reuter, Martin},
title = {{D}ataset: {H}yp{VINN} {C}heckpoints (v. 1.1.0)},
publisher = {Zenodo},
reportid = {DZNE-2024-00914},
year = {2024},
abstract = {Training checkpoints for HypVINN
(https://github.com/Deep-MI/FastSurfer) - please cite the
paper when using this resource
$(https://doi.org/10.1162/imag_a_00034).$ Abstract The
hypothalamus plays a crucial role in the regulation of a
broad range of physiological, behavioral, and cognitive
functions. However, despite its importance, only a few
small-scale neuroimaging studies have investigated its
substructures, likely due to the lack of fully automated
segmentation tools to address scalability and
reproducibility issues of manual segmentation. While the
only previous attempt to automatically sub-segment the
hypothalamus with a neural network showed promise for 1.0 mm
isotropic T1-weighted (T1w) magnetic resonance imaging
(MRI), there is a need for an automated tool to sub-segment
also high-resolutional (HiRes) MR scans, as they are
becoming widely available, and include structural detail
also from multi-modal MRI. We, therefore, introduce a novel,
fast, and fully automated deep-learning method named HypVINN
for sub-segmentation of the hypothalamus and adjacent
structures on 0.8 mm isotropic T1w and T2w brain MR images
that is robust to missing modalities. We extensively
validate our model with respect to segmentation accuracy,
generalizability, in-session test-retest reliability, and
sensitivity to replicate hypothalamic volume effects (e.g.,
sex differences). The proposed method exhibits high
segmentation performance both for standalone T1w images as
well as for T1w/T2w image pairs. Even with the additional
capability to accept flexible inputs, our model matches or
exceeds the performance of state-of-the-art methods with
fixed inputs. We, further, demonstrate the generalizability
of our method in experiments with 1.0 mm MR scans from both
the Rhineland Study and the UK Biobank—an independent
dataset never encountered during training with different
acquisition parameters and demographics. Finally, HypVINN
can perform the segmentation in less than a minute
(graphical processing unit [GPU]) and will be available in
the open source FastSurfer neuroimaging software suite,
offering a validated, efficient, and scalable solution for
evaluating imaging-derived phenotypes of the hypothalamus.},
cin = {AG Reuter / AG Breteler / AG Aziz},
cid = {I:(DE-2719)1040310 / I:(DE-2719)1012001 /
I:(DE-2719)5000071},
pnm = {354 - Disease Prevention and Healthy Aging (POF4-354)},
pid = {G:(DE-HGF)POF4-354},
experiment = {EXP:(DE-2719)Rhineland Study-20190321},
typ = {PUB:(DE-HGF)32},
doi = {10.5281/zenodo.11184216},
url = {https://pub.dzne.de/record/270875},
}
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