Title :
Atlas-Based Indexing of Brain Sections via 2-D to 3-D Image Registration
Author :
Gefen, Smadar ; Kiryati, Nahum ; Nissanov, Jonathan
Author_Institution :
LLC, Lawrenceville
Abstract :
A 2-D to 3-D nonlinear intensity-based registration method is proposed in which the alignment of histological brain sections with a volumetric brain atlas is performed. First, sparsely cut brain sections were linearly matched with an oblique slice automatically extracted from the atlas. Second, a planar-to-curved surface alignment was employed in order to match each section with its corresponding image overlaid on a curved-surface within the atlas. For the latter, a PDE-based registration technique was developed that is driven by a local normalized-mutual-information similarity measure. We demonstrate the method and evaluate its performance with simulated and real data experiments. An atlas-guided segmentation of mouse brains´ hippocampal complex, retrieved from the Mouse Brain Library (MBL) database, is demonstrated with the proposed algorithm.
Keywords :
brain; database indexing; feature extraction; image matching; image registration; image segmentation; information retrieval; libraries; medical image processing; 2-D to 3-D image registration; PDE-based registration technique; atlas-based indexing; atlas-guided segmentation; automatic oblique slice extraction; hippocampal complex; histological brain sections; image overlaid; linear matching; local normalized-mutual-information similarity measure; mouse brain library database retrieval; nonlinear intensity-based registration method; planar-to-curved surface alignment; volumetric brain atlas; Aneurysm; Arteries; Biological materials; Biomedical materials; Biomedical measurements; Brain; Image registration; Image segmentation; Indexing; Liver neoplasms; Magnetic resonance imaging; Mice; 2-D to 3-D nonlinear registration; @D-to-3D nonlinear registration; Normalized mutual information; PDE-based methods; normalized mutual information; Algorithms; Anatomy, Cross-Sectional; Animals; Brain; Feasibility Studies; Image Enhancement; Image Interpretation, Computer-Assisted; Imaging, Three-Dimensional; Mice; Pattern Recognition, Automated; Reference Values; Reproducibility of Results; Sensitivity and Specificity; Subtraction Technique;
Journal_Title :
Biomedical Engineering, IEEE Transactions on
DOI :
10.1109/TBME.2007.899361
