Sage Journals: Discover world-class research

Abstract

Background

To evaluate the degree of cerebral atrophy for Alzheimer's disease (AD), voxel-based morphometry has been performed with magnetic resonance imaging. Detailed morphological changes in a specific tissue area having the most evidence of atrophy were not considered by the machine-learning technique.

Purpose

To develop a machine-learning system that can capture morphology features for determination of atrophy of brain tissue in early-stage AD and classification of healthy participants or patients.

Material and Methods

Three-dimensional T1-weighted (3D-T1W) data were obtained from AD Neuroimaging Initiative (200 healthy controls and 200 patients with early-stage AD). Automated segmentation of 3D-T1W data was performed. Deep learning (DL) and support vector machine (SVM) were trained using 66-segmented volume values as input and AD diagnosis as output. DL was performed using 66 volume values or gray matter (GM) and white matter (WM) volume values. SVM learning was performed using 66 volume values and six regions with high variable importance. 3D convolutional neural network (3D-CNN) was trained using the segmented images. Accuracy and area under curve (AUC) were obtained. Variable importance was evaluated from logistic regression analysis.

Results

DL for GM and WM volume values, accuracy 0.6; SVM for all volume values, accuracy 0.82 and AUC 0.81; DL for all volume values, accuracy 0.82 and AUC 0.8; 3D-CNN using segmental images of the whole brain, accuracy 0.5 and AUC 0.51. SVM using volume values of six regions, accuracy 0.82; image-based 3D-CNN, highest accuracy 0.69.

Conclusion

Our results show that atrophic features are more considerable than morphological features in the early detection of AD.

Keywords

Alzheimer's disease magnetic resonance imaging convolutional neural network deep learning support vector machine voxel-based morphometry

Get full access to this article

View all access options for this article.

References

Whitwell

Dickson

Murray

, et al. Neuroimaging correlates of pathologically defined subtypes of Alzheimer’s disease: a case-control study. Lancet Neurol 2012;11:868–877.

Selkoe

. Normal and abnormal biology of the beta-amyloid precursor protein. Annu Rev Neurosci 1994;17:489–517.

Larner

. The cerebellum in Alzheimer’s disease. Dement Geriatr Cogn Disord 1997;8:203–209.

Nenadic

Dietzek

Schönfeld

, et al. Brain structure in people at ultra-high risk of psychosis, patients with first-episode schizophrenia, and healthy controls: a VBM study. Schizophr Res 2015;161:169–176.

Nickl-Jockschat

Habel

Michel

, et al. Brain structure anomalies in autism spectrum disorder–a meta-analysis of VBM studies using anatomic likelihood estimation. Hum Brain Mapp 2012;33:1470–1489.

Fischl

. Freesurfer. Neuroimage 2012;62:774–781.

Suk

Shen

. Deep learning-based feature representation for AD/MCI classification. Med Image Comput Comput Assist Interv 2013;16:583–590.

Hojjati

Ebrahimzadeh

Khazaee

, et al. Alzheimer’s disease neuroimaging I. Predicting conversion from MCI to AD using resting-state fMRI, graph theoretical approach and SVM. J Neurosci Methods 2017;282:69–80.

Oliveira

Jr Nitrini

Busatto

, et al. Use of SVM methods with surface-based cortical and volumetric subcortical measurements to detect Alzheimer’s disease. J Alzheimers Dis 2010;19:1263–1272.

10.

Wyman

Harvey

Crawford

, et al. Alzheimer’s disease neuroimaging initiative. Standardization of analysis sets for reporting results from ADNI MRI data. Alzheimers Dement 2013;9:332–337.

11.

Stoltzfus

. Logistic regression: a brief primer. Acad Emerg Med 2011;18:1099–1104.

12.

Huang

Cai

Pacheco

, et al. Applications of support vector machine (SVM) learning in cancer genomics. Cancer Genomics Proteomics 2018;15:41–51.

13.

Chan

Samala

Hadjiiski

, et al. Deep learning in medical image analysis. Adv Exp Med Biol 2020;1213:3–21.

14.

Qureshi

MNI

Lee

. 3D-CNN based discrimination of schizophrenia using resting-state fMRI. Artif Intell Med 2019;98:10–17.

15.

Jung

. A K-fold averaging cross-validation procedure. J Nonparametr Stat 2015;27:167–179.

16.

de Flores

La Joie

Landeau

, et al. Effects of age and Alzheimer’s disease on hippocampal subfields: comparison between manual and FreeSurfer volumetry. Hum Brain Mapp 2015;36:463–474.

17.

Liu

Yan

, et al. A multi-model deep convolutional neural network for automatic hippocampus segmentation and classification in Alzheimer’s disease. Neuroimage 2020;208:116459.

18.

Nho

Saykin

. Deep learning in Alzheimer’s disease: diagnostic classification and prognostic prediction using neuroimaging data. Front Aging Neurosci 2019;11:220.

19.

Patel

Sarraf

Tsai

. The curse of dimensionality. Anesthesiology 2018;129:614–615.

20.

Jolliffe

Cadima

. Principal component analysis: a review and recent developments. Philos Trans A Math Phys Eng Sci 2016;374:20150202.

21.

Gomez-Isla

Price

McKeel

Jr , et al. Profound loss of layer II entorhinal cortex neurons occurs in very mild Alzheimer’s disease. J Neurosci 1996;16:4491–4500.

22.

Meinen

Bouvy

Mendrik

, et al. Robustness of automated methods for brain volume measurements across different MRI field strengths. PLoS One 2016;11:e0165719.

23.

Reuter

Tisdall