Abstract
With the development of medical imaging modalities and image processing algorithms, there arises a need for methods of their comprehensive quantitative evaluation. In particular, this concerns the algorithms for vessel tracking and segmentation in magnetic resonance angiography images. The problem can be approached by using synthetic images, where true geometry of vessels is known. This paper presents a framework for computer modeling of MRA imaging and the results of its validation. A new model incorporates blood flow simulation within MR signal computation kernel. The proposed solution is unique, especially with respect to the interface between flow and image formation processes. Furthermore it utilizes the concept of particle tracing. The particles reflect the flow of fluid they are immersed in and they are assigned magnetization vectors with temporal evolution controlled by MR physics. Such an approach ensures flexibility as the designed simulator is able to reconstruct flow profiles of any type. The proposed model is validated in a series of experiments with physical and digital flow phantoms. The synthesized 3D images contain various features (including artifacts) characteristic for the time-of-flight protocol and exhibit remarkable correlation with the data acquired in a real MR scanner. The obtained results support the primary goal of the conducted research, i.e. establishing a reference technique for a quantified validation of MR angiography image processing algorithms.
Highlights
Magnetic Resonance Angiography (MRA) is a powerful technique for visualization of blood vessels
Within the MRA setting, there exist both non-invasive imaging protocols, such as e.g. Time-Of-Flight (ToF) [1,2,3] or Phase Contrast Angiography (PCA) [4], and sequences that rely on application of contrast agent [5]
The design of the MRA simulator decomposes into the following tasks: 1. geometry definition of a vessel or a set of vessel branches, 2. simulation of blood flow through the vessels, 3. modeling of stationary tissues which surround vessels, 4. simulation of magnetic resonance imaging sequences
Summary
Magnetic Resonance Angiography (MRA) is a powerful technique for visualization of blood vessels. Within the MRA setting, there exist both non-invasive imaging protocols, such as e.g. Time-Of-Flight (ToF) [1,2,3] or Phase Contrast Angiography (PCA) [4], and sequences that rely on application of contrast agent [5]. Direct examination of the measured ToF images provides essentially qualitative description of the vessel system. The quantitative information about the defects of vascularity of a visualized organ can help decide on the appropriate treatment. Such data can only be obtained with the use of specialized MRA image processing algorithms. The methods for vessels segmentation and tracking [6,7,8,9] enable an automatic identification of occlusions, pathological narrowings and hyper- or neovascularizations
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