Abstract

Alzheimer's Disease (AD) is the most common neurodegenerative disease in elderly people. Its development has been shown to be closely related to changes in the brain connectivity network and in the brain activation patterns along with structural changes caused by the neurodegenerative process. Methods to infer dependence between brain regions are usually derived from the analysis of covariance between activation levels in the different areas. However, these covariance-based methods are not able to estimate conditional independence between variables to factor out the influence of other regions. Conversely, models based on the inverse covariance, or precision matrix, such as Sparse Gaussian Graphical Models allow revealing conditional independence between regions by estimating the covariance between two variables given the rest as constant. This paper uses Sparse Inverse Covariance Estimation (SICE) methods to learn undirected graphs in order to derive functional and structural connectivity patterns from Fludeoxyglucose (18F-FDG) Position Emission Tomography (PET) data and segmented Magnetic Resonance images (MRI), drawn from the ADNI database, for Control, MCI (Mild Cognitive Impairment Subjects), and AD subjects. Sparse computation fits perfectly here as brain regions usually only interact with a few other areas. The models clearly show different metabolic covariation patters between subject groups, revealing the loss of strong connections in AD and MCI subjects when compared to Controls. Similarly, the variance between GM (Gray Matter) densities of different regions reveals different structural covariation patterns between the different groups. Thus, the different connectivity patterns for controls and AD are used in this paper to select regions of interest in PET and GM images with discriminative power for early AD diagnosis. Finally, functional an structural models are combined to leverage the classification accuracy. The results obtained in this work show the usefulness of the Sparse Gaussian Graphical models to reveal functional and structural connectivity patterns. This information provided by the sparse inverse covariance matrices is not only used in an exploratory way but we also propose a method to use it in a discriminative way. Regression coefficients are used to compute reconstruction errors for the different classes that are then introduced in a SVM for classification. Classification experiments performed using 68 Controls, 70 AD, and 111 MCI images and assessed by cross-validation show the effectiveness of the proposed method.

Highlights

  • Alzheimer’s Disease (AD) is the most common neurodegenerative disease in elderly people, currently affecting more than 40 million people, and its prevalence is expected to be quadrupled by 2050

  • The primary goal of Alzheimer’s Disease Neuroimaging Initiative (ADNI) has been to test whether serial magnetic resonance imaging (MRI), positron emission tomography (PET), other biological markers, and clinical and neuropsychological assessment can be combined to measure the progression of mild cognitive impairment (MCI) and early Alzheimer’s disease (AD)

  • By using binarized inverse covariance matrices for different number of arcs that reveal the connectivity between regions for CN, MCI, and AD

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Summary

Introduction

Alzheimer’s Disease (AD) is the most common neurodegenerative disease in elderly people, currently affecting more than 40 million people, and its prevalence is expected to be quadrupled by 2050. Methods aiming to figure out the neurodegenerative processes involved in the development of AD can provide a better understanding of the disease and the neurophysiological changes produced. These constitute an important tool to develop more effective treatments dealing with the early onset and the development of AD. Correlation analysis captures pairwise information but it does not factor out the contribution to the pairwise correlation due to global or third-party effects. If this is the goal, partial correlation should be adopted instead. It requires the use of methods that use a regularization parameter such as SICE, known as Gaussian graphical model or graphical LASSO (Pourahmadi, 2013)

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