F.G. te Nijenhuis
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2 records found
1
Master thesis
(2026)
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M.A. Leenders, F.M. Vos, T. van Walsum, F.G. te Nijenhuis, R. Su, D.M.J. Tax, F.J.H. Gijsen
Digital subtraction angiography (DSA) is widely used to assess vascular changes during endovascular thrombectomy, but manual comparison of image pairs is challenging and subjective. This work presents a deep learning-based method for arterial change detection in cerebral DSA by combining inter-sequence registration with a siamese spatiotemporal U-Net for joint arterial segmentation and change detection. Experiments on data from the MR CLEAN registry demonstrate that the proposed registration method significantly improves accuracy compared with the best-performing baseline (p=0.0054) and that the change-detection network consistently identifies arterial changes in successfully co-registered DSA pairs (Dice = 0.70). A preliminary reader study indicated that marking these changes can improve inter-rater agreement of extended thrombolysis in cerebral infarction (eTICI) scoring and increase the detection rate of emboli in new territory (ENT).
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Digital subtraction angiography (DSA) is widely used to assess vascular changes during endovascular thrombectomy, but manual comparison of image pairs is challenging and subjective. This work presents a deep learning-based method for arterial change detection in cerebral DSA by combining inter-sequence registration with a siamese spatiotemporal U-Net for joint arterial segmentation and change detection. Experiments on data from the MR CLEAN registry demonstrate that the proposed registration method significantly improves accuracy compared with the best-performing baseline (p=0.0054) and that the change-detection network consistently identifies arterial changes in successfully co-registered DSA pairs (Dice = 0.70). A preliminary reader study indicated that marking these changes can improve inter-rater agreement of extended thrombolysis in cerebral infarction (eTICI) scoring and increase the detection rate of emboli in new territory (ENT).
Background: Cerebrovascular diseases, which often involve a disruption in blood flow in the Circle of Willis (CoW) and its branching arteries, pose a major global health risk. Computational fluid dynamics (CFD) analyses present an opportunity to study their pathophysiology but require high-quality vessel segmentations. Methods: To generate pseudo-labeled training data, computed tomography angiography (CTA) images were preprocessed and inference was run using two pretrained models: an nnU-Net for multi-class CoW segmentation and a DTUNet for binary cerebral vessel segmentation. These outputs were combined using a region-growing approach; the resulting pseudolabels were used to train an nnU-Net V2 with a topologyaware loss function. CFD analyses were performed on both a model-generated segmentation and a ground truth segmentation derived from a CTA scan which had been expert-labeled by a neuroradiologist. The resulting velocity, pressure and wall shear stress (WSS) profiles for both segmentations were compared across 10 cross-sections of the middle cerebral artery (MCA). Results: After filtering out inaccurate labels, 1,709 of 2,201 pseudo-labeled images were retained for training and testing. Common errors included over-segmentation of small vessels, under-segmentation of large vessels and poor separation of the anterior cerebral arteries when compared to expert-annotated ground truth segmentations. The proposed segmentation model was evaluated on the test set, which used pseudo-labels as a reference standard, and achieved a mean Dice score of 62%, clDice of 40%, IoU of 51%, a HD of 16.9 voxels and an ASD of 3.9 voxels. In terms of centerline-based metrics, the model achieved a mean overlap (OV) of 72% and an average ASCD of 4.26 voxels. In CFD simulations, the predicted segmentation yielded absolute errors of 48.96 �} 30.69 mm/s, 7.47 �} 6.07 Pa and 1.22 �} 0.81 Pa for blood flow velocity, pressure and WSS, respectively, compared to the expert-annotated reference (p < 0.05 for all). Conclusions: This study demonstrates that a deep learning model, trained using pseudo-labels, can successfully generate anatomically plausible multi-class segmentations of the CoW suitable for downstream CFD analysis. However, discrepancies in key hemodynamic metrics compared to expert-annotated data highlight the need for improved pseudo-label accuracy, especially in regions of complex vascular geometry.
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Background: Cerebrovascular diseases, which often involve a disruption in blood flow in the Circle of Willis (CoW) and its branching arteries, pose a major global health risk. Computational fluid dynamics (CFD) analyses present an opportunity to study their pathophysiology but require high-quality vessel segmentations. Methods: To generate pseudo-labeled training data, computed tomography angiography (CTA) images were preprocessed and inference was run using two pretrained models: an nnU-Net for multi-class CoW segmentation and a DTUNet for binary cerebral vessel segmentation. These outputs were combined using a region-growing approach; the resulting pseudolabels were used to train an nnU-Net V2 with a topologyaware loss function. CFD analyses were performed on both a model-generated segmentation and a ground truth segmentation derived from a CTA scan which had been expert-labeled by a neuroradiologist. The resulting velocity, pressure and wall shear stress (WSS) profiles for both segmentations were compared across 10 cross-sections of the middle cerebral artery (MCA). Results: After filtering out inaccurate labels, 1,709 of 2,201 pseudo-labeled images were retained for training and testing. Common errors included over-segmentation of small vessels, under-segmentation of large vessels and poor separation of the anterior cerebral arteries when compared to expert-annotated ground truth segmentations. The proposed segmentation model was evaluated on the test set, which used pseudo-labels as a reference standard, and achieved a mean Dice score of 62%, clDice of 40%, IoU of 51%, a HD of 16.9 voxels and an ASD of 3.9 voxels. In terms of centerline-based metrics, the model achieved a mean overlap (OV) of 72% and an average ASCD of 4.26 voxels. In CFD simulations, the predicted segmentation yielded absolute errors of 48.96 �} 30.69 mm/s, 7.47 �} 6.07 Pa and 1.22 �} 0.81 Pa for blood flow velocity, pressure and WSS, respectively, compared to the expert-annotated reference (p < 0.05 for all). Conclusions: This study demonstrates that a deep learning model, trained using pseudo-labels, can successfully generate anatomically plausible multi-class segmentations of the CoW suitable for downstream CFD analysis. However, discrepancies in key hemodynamic metrics compared to expert-annotated data highlight the need for improved pseudo-label accuracy, especially in regions of complex vascular geometry.