Automatic model-guided segmentation of the human brain ventricular system from CT images.

RATIONALE AND OBJECTIVES Accurate segmentation of the brain ventricular system on computed tomographic (CT) imaging is useful in neurodiagnosis and neurosurgery. Manual segmentation is time consuming, usually not reproducible, and subjective. Because of image noise, low contrast between soft tissues, large interslice distance, large shape, and size variations of the ventricular system, no automatic method is presently available. The authors propose a model-guided method for the automated segmentation of the ventricular system. MATERIALS AND METHODS Fifty CT scans of patients with strokes at different sites were collected for this study. Given a brain CT image, its ventricular system was segmented in five steps: (1) a predefined volumetric model was registered (or deformed) onto the image; (2) according to the deformed model, eight regions of interest were automatically specified; (3) the intensity threshold of cerebrospinal fluid was calculated in a region of interest and used to segment all regions of cerebrospinal fluid from the entire brain volume; (4) each ventricle was segmented in its specified region of interest; and (5) intraventricular calcification regions were identified to refine the ventricular segmentation. RESULTS Compared to ground truths provided by experts, the segmentation results of this method achieved an average overlap ratio of 85% for the entire ventricular system. On a desktop personal computer with a dual-core central processing unit running at 2.13 GHz, about 10 seconds were required to analyze each data set. CONCLUSION Experiments with clinical CT images showed that the proposed method can generate acceptable results in the presence of image noise, large shape, and size variations of the ventricular system, and therefore it is potentially useful for the quantitative interpretation of CT images in neurodiagnosis and neurosurgery.

[1]  David N. Kennedy,et al.  Precise segmentation of the lateral ventricles and caudate nucleus in MR brain images using anatomically driven histograms , 1998, IEEE Transactions on Medical Imaging.

[2]  Wieslaw Lucjan Nowinski,et al.  Extraction of the midsagittal plane from morphological neuroimages using the Kullback-Leibler's measure , 2006, Medical Image Anal..

[3]  Wieslaw Lucjan Nowinski,et al.  A hybrid approach to shape-based interpolation of stereotactic atlases of the human brain , 2007, Neuroinformatics.

[4]  R. Kikinis,et al.  Automated segmentation of MR images of brain tumors. , 2001, Radiology.

[5]  Isabelle Bloch,et al.  From 3D magnetic resonance images to structural representations of the cortex topography using topology preserving deformations , 1995, Journal of Mathematical Imaging and Vision.

[6]  C. Barillot,et al.  Segmentation of 3D brain structures using level sets and dense registration , 2000, Proceedings IEEE Workshop on Mathematical Methods in Biomedical Image Analysis. MMBIA-2000 (Cat. No.PR00737).

[7]  M. Torrens Co-Planar Stereotaxic Atlas of the Human Brain—3-Dimensional Proportional System: An Approach to Cerebral Imaging, J. Talairach, P. Tournoux. Georg Thieme Verlag, New York (1988), 122 pp., 130 figs. DM 268 , 1990 .

[8]  Wieslaw Lucjan Nowinski,et al.  Three dimensional digital atlas of the orbit constructed from multi-modal radiological images , 2007, International Journal of Computer Assisted Radiology and Surgery.

[9]  Zhou Xiaoping,et al.  Risks of intracranial hemorrhage in patients with Parkinson's disease receiving deep brain stimulation and ablation. , 2010, Parkinsonism & related disorders.

[10]  Xiao Han,et al.  Atlas Renormalization for Improved Brain MR Image Segmentation Across Scanner Platforms , 2007, IEEE Transactions on Medical Imaging.

[11]  Wieslaw Lucjan Nowinski,et al.  Stroke Suite: Cad Systems for Acute Ischemic Stroke, Hemorrhagic Stroke, and Stroke in ER , 2007, MIMI.

[12]  R. S. Kahn,et al.  Automatic Segmentation of the Ventricular System from MR Images of the Human Brain , 2001, NeuroImage.

[13]  Omar S. Al-Kadi,et al.  Texture Analysis of Aggressive and Nonaggressive Lung Tumor CE CT Images , 2008, IEEE Transactions on Biomedical Engineering.

[14]  A. Aziz,et al.  Fast Talairach Transformation for Magnetic Resonance Neuroimages , 2006, Journal of computer assisted tomography.

[15]  Calvin R. Maurer,et al.  A Linear Time Algorithm for Computing Exact Euclidean Distance Transforms of Binary Images in Arbitrary Dimensions , 2003, IEEE Trans. Pattern Anal. Mach. Intell..

[16]  Aamer Aziz,et al.  A knowledge-driven algorithm for a rapid and automatic extraction of the human cerebral ventricular system from MR neuroimages , 2004, NeuroImage.

[17]  Wieslaw Lucjan Nowinski,et al.  A Model-Based, Semi-Global Segmentation Approach for Automatic 3-D Point Landmark Localization in Neuroimages , 2008, IEEE Transactions on Medical Imaging.

[18]  Dinggang Shen,et al.  An adaptive-focus statistical shape model for segmentation and shape modeling of 3-D brain structures , 2001, IEEE Transactions on Medical Imaging.

[19]  Derek L. G. Hill,et al.  Quantifying Small Changes in Brain Ventricular Volume Using Non-rigid Registration , 2001, MICCAI.

[20]  Liu Fengqiang,et al.  Computer-assisted stereotactic neurosurgery with framework neurosurgery navigation , 2008, Clinical Neurology and Neurosurgery.

[21]  Bradley D. Clymer,et al.  Three-dimensional texture analysis of cancellous bone cores evaluated at clinical CT resolutions , 2006, Osteoporosis International.

[22]  Milan Sonka,et al.  Knowledge-based interpretation of MR brain images , 1996, IEEE Trans. Medical Imaging.

[23]  Wieslaw Lucjan Nowinski,et al.  A hybrid approach for segmentation of anatomic structures in medical images , 2008, International Journal of Computer Assisted Radiology and Surgery.

[24]  Wieslaw Lucjan Nowinski,et al.  Automatic Segmentation of the Human Brain Ventricles from MR Images by Knowledge-Based Region Growing and Trimming , 2009, Neuroinformatics.