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Brain Structure and Function
Published in: Brain Structure and Function 5/2016

01-06-2016 | Original Article

Deep sparse multi-task learning for feature selection in Alzheimer’s disease diagnosis

Authors: Heung-Il Suk, Seong-Whan Lee, Dinggang Shen, The Alzheimer’s Disease Neuroimaging Initiative

Published in: Brain Structure and Function | Issue 5/2016

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Abstract

Recently, neuroimaging-based Alzheimer’s disease (AD) or mild cognitive impairment (MCI) diagnosis has attracted researchers in the field, due to the increasing prevalence of the diseases. Unfortunately, the unfavorable high-dimensional nature of neuroimaging data, but a limited small number of samples available, makes it challenging to build a robust computer-aided diagnosis system. Machine learning techniques have been considered as a useful tool in this respect and, among various methods, sparse regression has shown its validity in the literature. However, to our best knowledge, the existing sparse regression methods mostly try to select features based on the optimal regression coefficients in one step. We argue that since the training feature vectors are composed of both informative and uninformative or less informative features, the resulting optimal regression coefficients are inevidently affected by the uninformative or less informative features. To this end, we first propose a novel deep architecture to recursively discard uninformative features by performing sparse multi-task learning in a hierarchical fashion. We further hypothesize that the optimal regression coefficients reflect the relative importance of features in representing the target response variables. In this regard, we use the optimal regression coefficients learned in one hierarchy as feature weighting factors in the following hierarchy, and formulate a weighted sparse multi-task learning method. Lastly, we also take into account the distributional characteristics of samples per class and use clustering-induced subclass label vectors as target response values in our sparse regression model. In our experiments on the ADNI cohort, we performed both binary and multi-class classification tasks in AD/MCI diagnosis and showed the superiority of the proposed method by comparing with the state-of-the-art methods.
Appendix
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Footnotes
1
In a least squares regression framework, one task corresponds to find optimal regression coefficients to represent the values of a target response variable. So, when we consider multiple target response variables simultaneously, it is regarded as multi-task learning (Argyriou et al. 2008).
 
2
In this work, we define the uninformative and less informative features based on their optimal regression coefficients. Specifically, the features whose regression coefficients are zero or close to zero, are regarded, respectively, as uninformative or less informative in representing the target response variables.
 
4
Although there exist in total more than 800 subjects in ADNI database, only 202 subjects have the baseline data including all the modalities of MRI, PET, and CSF.
 
5
Refer to ‘http://​www.​adniinfo.​org’ for more details.
 
8
In our experiments on the ADNI cohort, we have one sample per subject.
 
9
\(\mathbb {F}^{(0)}\) denotes the original full feature set.
 
10
Initially, we set the current best accuracy zero.
 
13
In this work, we use a negative Euclidian distance for similarity computation.
 
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Metadata
Title
Deep sparse multi-task learning for feature selection in Alzheimer’s disease diagnosis
Authors
Heung-Il Suk
Seong-Whan Lee
Dinggang Shen
The Alzheimer’s Disease Neuroimaging Initiative
Publication date
01-06-2016
Publisher
Springer Berlin Heidelberg
Published in
Brain Structure and Function / Issue 5/2016
Print ISSN: 1863-2653
Electronic ISSN: 1863-2661
DOI
https://doi.org/10.1007/s00429-015-1059-y

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