TY - UNPB
T1 - VesselBoost
T2 - A Python Toolbox for Small Blood Vessel Segmentation in Human Magnetic Resonance Angiography Data
AU - Xu, Marshall
AU - Ribeiro, Fernanda L
AU - Barth, Markus
AU - Bernier, Michaël
AU - Bollmann, Steffen
AU - Chatterjee, Soumick
AU - Cognolato, Francesco
AU - Gulban, Omer Faruk
AU - Itkyal, Vaibhavi
AU - Liu, Siyu
AU - Mattern, Hendrik
AU - Polimeni, Jonathan R
AU - Shaw, Thomas B
AU - Speck, Oliver
AU - Bollmann, Saskia
PY - 2024/5/22
Y1 - 2024/5/22
N2 - Magnetic resonance angiography (MRA) performed at ultra-high magnetic field provides a unique opportunity to study the arteries of the living human brain at the mesoscopic level. From this, we can gain new insights into the brain's blood supply and vascular disease affecting small vessels. However, for quantitative characterization and precise representation of human angioarchitecture to, for example, inform blood-flow simulations, detailed segmentations of the smallest vessels are required. Given the success of deep learning-based methods in many segmentation tasks, we here explore their application to high-resolution MRA data, and address the difficulty of obtaining large data sets of correctly and comprehensively labelled data. We introduce , a vessel segmentation package, which utilizes deep learning and imperfect training labels for accurate vasculature segmentation. Combined with an innovative data augmentation technique, which leverages the resemblance of vascular structures, enables detailed vascular segmentations.
AB - Magnetic resonance angiography (MRA) performed at ultra-high magnetic field provides a unique opportunity to study the arteries of the living human brain at the mesoscopic level. From this, we can gain new insights into the brain's blood supply and vascular disease affecting small vessels. However, for quantitative characterization and precise representation of human angioarchitecture to, for example, inform blood-flow simulations, detailed segmentations of the smallest vessels are required. Given the success of deep learning-based methods in many segmentation tasks, we here explore their application to high-resolution MRA data, and address the difficulty of obtaining large data sets of correctly and comprehensively labelled data. We introduce , a vessel segmentation package, which utilizes deep learning and imperfect training labels for accurate vasculature segmentation. Combined with an innovative data augmentation technique, which leverages the resemblance of vascular structures, enables detailed vascular segmentations.
U2 - 10.1101/2024.05.22.595251
DO - 10.1101/2024.05.22.595251
M3 - Preprint
BT - VesselBoost
PB - Cold Spring Harbor Laboratory - bioRxiv
ER -