INTRODUCTION: Classification methods have been proposed to detect Alzheimer’s disease (AD) using magnetic resonance images. Most rely on features such as the shape/volume of brain structures that need to be defined a priori. In this work, we propose a method that does not require either the segmentation of specific brain regions or the nonlinear alignment to a template. Besides classification, we also analyze which brain regions are discriminative between a group of normal controls and a group of AD patients. METHODS: We perform 3D texture analysis using Local Binary Patterns computed at local image patches in the whole brain, combined in a classifier ensemble.We evaluate our method in a publicly available database including very mild-to-mild AD subjects and healthy elderly controls. RESULTS: For the subject cohort including only mild AD subjects, the best results are obtained using a combination of large (30×30×30 and 40×40×40 voxels) patches. A spatial analysis on the best performing patches shows that these are located in the medial-temporal lobe and in the periventricular regions. When very mild AD subjects are included in the dataset, the small (10×10×10 voxels) patches perform best, with the most discriminative ones being located near the left hippocampus. CONCLUSION: We show that our method is able not only to perform accurate classification, but also to localize dis-criminative brain regions, which are in accordance with the medical literature. This is achieved without the need to segment-specific brain structures and without performing nonlinear registration to a template, indicating that the method may be suitable for a clinical implementation that can help to diagnose AD at an earlier stage.
INTRODUCTION: Classification methods have been proposed to detect Alzheimer’s disease (AD) using magnetic resonance images. Most rely on features such as the shape/volume of brain structures that need to be defined a priori. In this work, we propose a method that does not require either the segmentation of specific brain regions or the nonlinear alignment to a template. Besides classification, we also analyze which brain regions are discriminative between a group of normal controls and a group of ADpatients. METHODS: We perform 3D texture analysis using Local Binary Patterns computed at local image patches in the whole brain, combined in a classifier ensemble.We evaluate our method in a publicly available database including very mild-to-mild AD subjects and healthy elderly controls. RESULTS: For the subject cohort including only mild AD subjects, the best results are obtained using a combination of large (30×30×30 and 40×40×40 voxels) patches. A spatial analysis on the best performing patches shows that these are located in the medial-temporal lobe and in the periventricular regions. When very mild AD subjects are included in the dataset, the small (10×10×10 voxels) patches perform best, with the most discriminative ones being located near the left hippocampus. CONCLUSION: We show that our method is able not only to perform accurate classification, but also to localize dis-criminative brain regions, which are in accordance with the medical literature. This is achieved without the need to segment-specific brain structures and without performing nonlinear registration to a template, indicating that the method may be suitable for a clinical implementation that can help to diagnose AD at an earlier stage.
Authors: D P Devanand; G Pradhaban; X Liu; A Khandji; S De Santi; S Segal; H Rusinek; G H Pelton; L S Honig; R Mayeux; Y Stern; M H Tabert; M J de Leon Journal: Neurology Date: 2007-03-13 Impact factor: 9.910
Authors: Stefan J Teipel; Christine Born; Michael Ewers; Arun L W Bokde; Maximilian F Reiser; Hans-Jürgen Möller; Harald Hampel Journal: Neuroimage Date: 2007-07-18 Impact factor: 6.556
Authors: M P Laakso; H Soininen; K Partanen; E L Helkala; P Hartikainen; P Vainio; M Hallikainen; T Hänninen; P J Riekkinen Journal: J Neural Transm Park Dis Dement Sect Date: 1995
Authors: Rachael I Scahill; Jonathan M Schott; John M Stevens; Martin N Rossor; Nick C Fox Journal: Proc Natl Acad Sci U S A Date: 2002-04-02 Impact factor: 11.205
Authors: Stefan Klöppel; Cynthia M Stonnington; Carlton Chu; Bogdan Draganski; Rachael I Scahill; Jonathan D Rohrer; Nick C Fox; Clifford R Jack; John Ashburner; Richard S J Frackowiak Journal: Brain Date: 2008-01-17 Impact factor: 13.501