Abstract
It is often a difficult task to accurately segment brain magnetic resonance (MR) images with intensity in-homogeneity and noise. This paper introduces a novel level set method for simultaneous brain MR image segmentation and intensity inhomogeneity correction. To reduce the effect of noise, novel anisotropic spatial information, which can preserve more details of edges and corners, is proposed by incorporating the inner relationships among the neighbor pixels. Then the proposed energy function uses the multivariate Student's t-distribution to fit the distribution of the intensities of each tissue. Furthermore, the proposed model utilizes Hidden Markov random fields to model the spatial correlation between neigh-boring pixels/voxels. The means of the multivariate Student's t-distribution can be adaptively estimated by multiplying a bias field to reduce the effect of intensity inhomogeneity. In the end, we reconstructed the energy function to be convex and calculated it by using the Split Bregman method, which allows our framework for random initialization, thereby allowing fully automated applications. Our method can obtain the final result in less than 1 second for 2D image with size 256 × 256 and less than 300 seconds for 3D image with size 256 × 256 × 171. The proposed method was compared to other state-of-the-art segmentation methods using both synthetic and clinical brain MR images and increased the accuracies of the results more than 3%.
Highlights
Brain disease has become one of the most talked-about diseases in the world
Many segmentation methods have been reported [1], automated and accurate segmentation still remains a difficult task due to the noise and intensity inhomogeneity, which can be found in MRI
The clinical brain magnetic resonance (MR) images are downloaded from the Internet Brain Segmentation Repository
Summary
Brain disease has become one of the most talked-about diseases in the world. The use of magnetic resonance imaging has become a preferred choice of method because it is generally painless, harmless and can provide very informative diagnostic images of most of the relevant organs and tissues. Among the MRI (Magnetic resonance image) data analysis, precise measurement of the distribution of tissues of interest (TOI), including gray matter (GM), white matter (WM) and cerebrospinal fluid (CSF), plays an important role for brain studies. In order to obtain the precise measurement, accurate image segmentation is a crucial step. Many segmentation methods have been reported [1], automated and accurate segmentation still remains a difficult task due to the noise and intensity inhomogeneity ( named as bias field), which can be found in MRI
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