Filling Large Discontinuities in 3D Vascular Networks Using Skeleton- and Intensity-Based Information

Bates, Russell; Risser, Laurent; Irving, Benjamin; Papież, Bartłomiej W.; Kannan, Pavitra; Kersemans, Veerle; Schnabel, Julia A.

doi:10.1007/978-3-319-24574-4_19

Cited by 6 publications

(8 citation statements)

References 14 publications

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“…Briefly, pre- and post-contrast scans were cropped to exclude non-tumor regions in the analysis, intensity normalized, co-registered using non-rigid registration, and then subtracted (Figure 1). Vessel structures were then segmented using a modified vesselness filter (27), and skeletonized using an iterative thinning algorithm (28) and an intensity-based gap filling model previously developed in our group (23). Because many cancer therapies are thought to normalize vascular structure in tumors, structural parameters such as vessel volume, branching points, diameter, length, and tortuosity were chosen to characterize morphological changes (1).…”

Section: Methodsmentioning

confidence: 99%

“…In this study, we attempt to tackle this shortcoming by measuring the 3D relationship between functional imaging parameters and structural vascular features in vivo to facilitate clinical utility. To achieve this aim, we used improved imaging (22) and 3D segmentation techniques (23) to extract functional parameters derived from DCE-MRI and structural parameters derived from contrast-enhanced CT performed in vivo . Relationships were first assessed in untreated tumors from two different preclinical models with high and low levels of vascularization.…”

Section: Introductionmentioning

confidence: 99%

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Functional Parameters Derived from Magnetic Resonance Imaging Reflect Vascular Morphology in Preclinical Tumors and in Human Liver Metastases

Kannan

Kretzschmar

Winter

et al. 2018

Clinical Cancer Research

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Tumor vessels influence the growth and response of tumors to therapy. Imaging vascular changes using dynamic contrast-enhanced MRI (DCE-MRI) has shown potential to guide clinical decision making for treatment. However, quantitative MR imaging biomarkers of vascular function have not been widely adopted, partly because their relationship to structural changes in vessels remains unclear. We aimed to elucidate the relationships between vessel function and morphology Untreated preclinical tumors with different levels of vascularization were imaged sequentially using DCE-MRI and CT. Relationships between functional parameters from MR (AUC, , and BAT) and structural parameters from CT (vessel volume, radius, and tortuosity) were assessed using linear models. Tumors treated with anti-VEGFR2 antibody were then imaged to determine whether antiangiogenic therapy altered these relationships. Finally, functional-structural relationships were measured in 10 patients with liver metastases from colorectal cancer. Functional parameters AUC and primarily reflected vessel volume in untreated preclinical tumors. The relationships varied spatially and with tumor vascularity, and were altered by antiangiogenic treatment. In human liver metastases, all three structural parameters were linearly correlated withAUC and ForAUC, structural parameters also modified each other's effect. Our findings suggest that MR imaging biomarkers of vascular function are linked to structural changes in tumor vessels and that antiangiogenic therapy can affect this link. Our work also demonstrates the feasibility of three-dimensional functional-structural validation of MR biomarkers to improve their biological interpretation and clinical utility..

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Functional Parameters Derived from Magnetic Resonance Imaging Reflect Vascular Morphology in Preclinical Tumors and in Human Liver Metastases

Kannan

Kretzschmar

Winter

et al. 2018

Clinical Cancer Research

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“…An iterative tensor voting strategy for identifying curvilinear structures in two-dimensional (2-D) images, primarily from microscopy, was introduced by Loss et al 16 However, it only applies to relatively small gaps. Bates et al 17 presented a strategy where they combine both skeleton-and intensity-based information to fill large discontinuities. Since the main goal of this method is to fill gaps originating from thresholding the vesselness likelihood map, the method may not be suitable for detecting collateral arteries.…”

Section: Previous Workmentioning

confidence: 99%

Improved centerline tree detection of diseased peripheral arteries with a cascading algorithm for vascular segmentation

et al. 2017

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Vascular segmentation plays an important role in the assessment of peripheral arterial disease. The segmentation is very challenging especially for arteries with severe stenosis or complete occlusion. We present a cascading algorithm for vascular centerline tree detection specializing in detecting centerlines in diseased peripheral arteries. It takes a three-dimensional computed tomography angiography (CTA) volume and returns a vascular centerline tree, which can be used for accelerating and facilitating the vascular segmentation. The algorithm consists of four levels, two of which detect healthy arteries of varying sizes and two that specialize in different types of vascular pathology: severe calcification and occlusion. We perform four main steps at each level: appropriate parameters for each level are selected automatically, a set of centrally located voxels is detected, these voxels are connected together based on the connection criteria, and the resulting centerline tree is corrected from spurious branches. The proposed method was tested on 25 CTA scans of the lower limbs, achieving an average overlap rate of 89% and an average detection rate of 82%. The average execution time using four CPU cores was 70 s, and the technique was successful also in detecting very distal artery branches, e.g., in the foot.

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“…Topological data analysis offers great potential for relating the form and function of vascular networks, and proposing novel biomarkers for tumour progression and treatment.Introduction. The advent of high resolution imaging techniques has driven the development of reconstruction algorithms, which generate exquisitely detailed 3D renderings of biological tissues, such as tumour vascular networks 10,11 . Analyses of these images have quantified structural features and shape, including vessel density, number of vessels and branch points 7 , fractal dimension 12 , and lacunarity 13 , and highlighted their relevance for monitoring disease progression 14,15 and treatment 6 .…”

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confidence: 99%

Multiscale Topology Characterises Dynamic Tumour Vascular Networks

Stolz¹,

Kaeppler²,

Markelc³

et al. 2020

Preprint

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Advances in imaging techniques enable high resolution 3D visualisation of vascular networks over time and reveal abnormal structural features such as twists and loops 1-6 . Quantitative descriptors of vascular networks are an active area of research 1, 2, 7 and often focus on a single spatial resolution. Simultaneously, topological data analysis (TDA) 8, 9 , the mathematical field that studies 'shape' of data, has expanded from theory to applications through advances in computation and machine learning integration. Fully characterising the geometric, spatial and temporal tissue organisation is challenging, and its quantification is necessary to assess treatment effects. Here we showcase TDA to analyse intravital and ultramicroscopy imaging modalities and quantify spatio-temporal variation of twists, loops, and avascular regions (voids) in 3D vascular networks. We propose two topological lenses to study vasculature which capture inherent multi-scale organisation and vessel connectivity invisible to existing methods. This topological approach validates and quantifies known qualitative trends; specifically, dynamic changes in tortuosity and loops in response to antibodies that modulate vessel sprouting. Using these topological descriptors, we show further how radiotherapy alters the structure of tumour vasculature. Topological data analysis offers great potential for relating the form and function of vascular networks, and proposing novel biomarkers for tumour progression and treatment.Introduction. The advent of high resolution imaging techniques has driven the development of reconstruction algorithms, which generate exquisitely detailed 3D renderings of biological tissues, such as tumour vascular networks 10,11 . Analyses of these images have quantified structural features and shape, including vessel density, number of vessels and branch points 7 , fractal dimension 12 , and lacunarity 13 , and highlighted their relevance for monitoring disease progression 14,15 and treatment 6 . Tumours may contain regions of high and low vessel density 2 , the latter corresponding to vascular voids which are associated with tumour hypoxia and necrosis, and lead to reduced survival in patients and poor responses to therapy 2 . Artificial intelligence and machine learning algorithms represent the state-of-the-art for learning how to segment images; we employ them here.

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Filling Large Discontinuities in 3D Vascular Networks Using Skeleton- and Intensity-Based Information

Cited by 6 publications

References 14 publications

Functional Parameters Derived from Magnetic Resonance Imaging Reflect Vascular Morphology in Preclinical Tumors and in Human Liver Metastases

Functional Parameters Derived from Magnetic Resonance Imaging Reflect Vascular Morphology in Preclinical Tumors and in Human Liver Metastases

Improved centerline tree detection of diseased peripheral arteries with a cascading algorithm for vascular segmentation

Multiscale Topology Characterises Dynamic Tumour Vascular Networks

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