Passat Nicolas, Ronse Christian, Baruthio Joseph, Armspach Jean-Paul, Maillot Claude, Jahn Christine
LSIIT, UMR 7005 CNRS-ULP, Illkirch, France.
J Magn Reson Imaging. 2005 Jun;21(6):715-25. doi: 10.1002/jmri.20307.
To propose an atlas-based method that uses both phase and magnitude images to integrate anatomical information in order to improve the segmentation of blood vessels in cerebral phase-contrast magnetic resonance angiography (PC-MRA).
An atlas of the whole head was developed to store the anatomical information. The atlas divides a magnitude image into several vascular areas, each of which has specific vessel properties. It can be applied to any magnitude image of an entire or nearly entire head by deformable matching, which helps to segment blood vessels from the associated phase image. The segmentation method used afterwards consists of a topology-preserving, region-growing algorithm that uses adaptive threshold values depending on the current region of the atlas. This algorithm builds the arterial and venous trees by iteratively adding voxels that are selected according to their grayscale value and the variation of values in their neighborhood. The topology preservation is guaranteed because only simple points are selected during the growing process.
The method was performed on 40 PC-MRA images of the brain. The results were validated using maximum-intensity projection (MIP) and three-dimensional surface rendering visualization, and compared with results obtained with two non-atlas-based methods.
The results show that the proposed method significantly improves the segmentation of cerebral vascular structures from PC-MRA. These experiments tend to prove that the use of vascular atlases is an effective way to optimize vessel segmentation of cerebral images.
提出一种基于图谱的方法,该方法利用相位和幅度图像来整合解剖学信息,以改善脑相位对比磁共振血管造影(PC-MRA)中血管的分割。
开发了一个全脑图谱来存储解剖学信息。该图谱将幅度图像划分为几个血管区域,每个区域都有特定的血管特性。通过可变形匹配,它可以应用于整个或几乎整个头部的任何幅度图像,这有助于从相关的相位图像中分割血管。随后使用的分割方法包括一种拓扑保持区域生长算法,该算法根据图谱的当前区域使用自适应阈值。该算法通过迭代添加根据其灰度值及其邻域中值的变化选择的体素,构建动脉树和静脉树。由于在生长过程中只选择简单点,因此保证了拓扑保持。
该方法在40幅脑部PC-MRA图像上进行了测试。使用最大强度投影(MIP)和三维表面渲染可视化对结果进行了验证,并与两种非基于图谱的方法获得的结果进行了比较。
结果表明,所提出的方法显著改善了PC-MRA中脑血管结构的分割。这些实验倾向于证明,使用血管图谱是优化脑图像血管分割的有效方法。
