Abstract
Cardiac-cycle related pulsatile aneurysm motion and deformation is assumed to provide valuable information for assessing cerebral aneurysm rupture risk. Accordingly, numerous studies addressed quantification of cerebral aneurysm wall motion and deformation. Most of them utilized in vivo imaging data, but image-based aneurysm deformation quantification is subject to pronounced uncertainties: unknown ground-truth deformation; image resolution in the order of the expected deformation; direct interplay between contrast agent inflow and image intensity. To analyze the impact of the uncertainties on deformation quantification, a multi-imaging modality ground-truth phantom study is performed. A physical flow phantom was designed that allowed simulating pulsatile flow through a variety of modeled cerebral vascular structures. The phantom was imaged using different modalities [MRI, CT, 3D-RA] and mimicking physiologically realistic flow conditions. Resulting image data was analyzed by an established registration-based approach for automated wall motion quantification. The data reveals severe dependency between contrast media inflow-related image intensity changes and the extent of estimated wall deformation. The study illustrates that imaging-related uncertainties affect the accuracy of cerebral aneurysm deformation quantification, suggesting that in vivo imaging studies have to be accompanied by ground-truth phantom experiments to foster data interpretation and to prove plausibility of the applied image analysis algorithms.
Highlights
Cerebral aneurysms are anomalous dilated arteries with a potentially severe complication: rupture[1]
Our work aims at analyzing respective imaging and image analysis uncertainties regarding the quantification of pulsatile deformation of cerebral vessels and aneurysms
It was designed as a multi-imaging modality ground truth study: A physical flow phantom was developed, 3D-printed, and applied for magnetic resonance imaging (MRI), computed tomography angiography (CTA), and 3D rotational angiography (3D-RA) imaging
Summary
Cerebral aneurysms are anomalous dilated arteries with a potentially severe complication: rupture[1]. Associated intensity fluctuations hinder image analysis and interpretation and might be mistaken as physical deformations; yet, related uncertainties are largely neglected. Our work aims at analyzing respective imaging and image analysis uncertainties regarding the quantification of pulsatile deformation of cerebral vessels and aneurysms. It was designed as a multi-imaging modality ground truth study: A physical flow phantom was developed, 3D-printed, and applied for MRI, CTA, and 3D-RA imaging. The (not existing) wall deformation in the ground truth image sequences was estimated and quantified by an established non-linear registration-based image analysis approach, and differences between the imaging modalities were analyzed. The present study thereby extends our related conference contribution[11,12], which contained first preliminary data obtained by our experimental setup using MRI imaging sequences
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