Figures
Abstract
Detecting early morphological changes in the brain and making early diagnosis are important for Alzheimer’s disease (AD). High resolution magnetic resonance imaging can be used to help diagnosis and prediction of the disease. In this paper, we proposed a machine learning method to discriminate patients with AD or mild cognitive impairment (MCI) from healthy elderly and to predict the AD conversion in MCI patients by computing and analyzing the regional morphological differences of brain between groups. Distance between each pair of subjects was quantified from a symmetric diffeomorphic registration, followed by an embedding algorithm and a learning approach for classification. The proposed method obtained accuracy of 96.5% in differentiating mild AD from healthy elderly with the whole-brain gray matter or temporal lobe as region of interest (ROI), 91.74% in differentiating progressive MCI from healthy elderly and 88.99% in classifying progressive MCI versus stable MCI with amygdala or hippocampus as ROI. This deformation-based method has made full use of the pair-wise macroscopic shape difference between groups and consequently increased the power for discrimination.
Citation: Long X, Chen L, Jiang C, Zhang L, Alzheimer’s Disease Neuroimaging Initiative (2017) Prediction and classification of Alzheimer disease based on quantification of MRI deformation. PLoS ONE 12(3): e0173372. https://doi.org/10.1371/journal.pone.0173372
Editor: Kewei Chen, Banner Alzheimer's Institute, UNITED STATES
Received: September 8, 2016; Accepted: February 20, 2017; Published: March 6, 2017
Copyright: © 2017 Long et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: Data used in this study belong to the Alzheimer’s Disease Neuroimaging Initiative (ADNI). The authors of this manuscript do not have any special access privileges to these data. Researchers may apply to access the data via the official website of the database (http://adni.loni.usc.edu/).
Funding: The study was partly supported by the National Natural Science Foundation of China (Grant No. 81301285 and 81371359) and the Scientific Research Program of the Shenzhen Science and Technology Innovation Committee (JCYJ20150521094519463, JCYJ20140415090443270). Data collection and sharing for this project was funded by the Alzheimer's Disease Neuroimaging Initiative (ADNI) (National Institutes of Health Grant U01 AG024904). ADNI is funded by the National Institute on Aging, the National Institute of Biomedical Imaging and Bioengineering, the Food and Drug Administration, and through generous contributions from the following: Abbott; Alzheimer’s Association; Alzheimer’s Drug Discovery Foundation; Amorfix Life Sciences Ltd.; AstraZeneca; Bayer HealthCare; BioClinica, Inc.; Biogen Idec Inc.; Bristol-Myers Squibb Company; Eisai Inc.; Elan Pharmaceuticals Inc.; Eli Lilly and Company; F. Hoffmann-La Roche Ltd and its affiliated company Genentech, Inc.; GE Healthcare; Innogenetics, N.V.; IXICO Ltd.; Janssen Alzheimer Immunotherapy Research & Development, LLC.; Johnson & Johnson Pharmaceutical Research & Development LLC.; Medpace, Inc.; Merck & Co., Inc.; Meso Scale Diagnostics, LLC.; Novartis Pharmaceuticals Corporation; Pfizer Inc.; Servier; Synarc Inc.; and Takeda Pharmaceutical Company. The Canadian Institutes of Health Research is providing funds to support ADNI clinical sites in Canada. Private sector contributions are facilitated by the Foundation for the National Institutes of Health (www.fnih.org). The grantee organization is the Northern California Institute for Research and Education, and the study is coordinated by the Alzheimer’s Disease Cooperative Study at the University of California San Diego. ADNI data are disseminated by the Laboratory for Neuro Imaging at the University of California Los Angeles. This research was also supported by National Institutes of Health grants P30 AG010129 and K01 AG030514. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: Data used in this study was retrieved from an open-access database, the Alzheimer’s Disease Neuroimaging Initiative (ADNI). Although the database was partly sponsored by a commercial source, the approval for public sharing of the anonymized data was obtained and this does not alter our adherence to PLOS ONE policies on sharing data and materials.
Introduction
Alzheimer disease (AD), the most common form of dementia, is known for the unresolved etiology and pathophysiology. Neurofibrillary tangle, plaque buildup and tissue loss in the brain parenchyma [1, 2] suggest the progressive degenerative nature of the disease. Early detection of AD at the preclinical stage is of great importance in terms of patient management. Since the earliest symptoms of AD, such as short-term memory loss and paranoid suspicion, are often mistaken as related to aging and stress, or are confused with symptoms resulted from other brain disorders, it remains challenging to predict the disease onset and the dynamic of AD in the scenario of dementia till it manifests severe cognitive impairment with typical neuroimaging signs.
AD is usually diagnosed clinically from the patient history and cognitive impairment testing [3]. Interviews with family members and caregivers are also utilized in the assessment of the disease [4]. The diagnosis based on neuropsychological scale requires rich clinical experience of physicians, and as a result it is subjective and less repeatable. Moreover, it is more challenging to identify patients suffering from AD at a prodromal stage, named mild cognitive impairment (MCI), as these subjects have cognitive impairments beyond that expected for their age and education but do not meet neuropathological criteria for AD. Neuroimaging, especially the high resolution magnetic resonance imaging (MRI), was recommended in more precise research criteria for prediction or early diagnosis of AD [5]. The structural MR images provide additional information about abnormal tissue atrophy or other abnormal biomarkers that can be sensitively detected at the early stage of the disease, and therefore automatic image-analysis methods are desired to help diagnose the illness before irreversible neuronal loss has set in, or to help detect brain changes between patients who may convert and may not convert to AD [6].
To this end, many algorithms on distinguishing AD or MCI have been proposed, varying from conceptually simple measurement of volumes or mathematically complex description of shape difference in a priori regions of interest (ROI) [7–13], to voxel-wise modeling of tissue density changes on the whole brain region, e.g. voxel-wise morphometry [11, 14–18]. There has been interest in machine learning and computer-aided diagnostics in the field of medical imaging, where a machine learning algorithm is trained to produce a desired output from a set of input training data such as features obtained from voxel intensity, tissue density or shape descriptor. Machine learning diagnostics can be also divided into ROI based and whole-brain based methods. ROI based algorithms always focus on the medial temporal structures of the brain, including the hippocampus and entorhinal cortex. In the work of Chupin et al. [19], Gutman et al. [20] and Gerardin et al. [21], support vector machine (SVM) were used for classification of AD or MCI subjects with hippocampal volume or shape as features. Another study has compared the linear discriminant analysis (LDA) and SVM for MCI classification and prediction based on hippocampal volume [22]. The entorhinal cortical thickness and modified tissue density in amygdala, parahippocampal gyrus have also been used as features in AD and MCI discrimination [23, 24]. ROI based analyses typically do not make use of all the available information contained in the whole brain, and require a priori decisions concerning which structures to assess. Atrophy in the inferior-lateral temporal lobes, cingulate gyrus, and in the parietal and frontal lobes has also been reported [25, 26]. Whether hippocampus, medial temporal lobe, or other ROIs would be a better choice for discrimination or prediction of AD is still controversial. Algorithms that extracted features from wider or cohort-adaptive brain regions have been proposed [27–32]. Kloppel et al. [33] developed a supervised method using linear SVM to group the gray matter segment of T1-weighted MR images on a high dimensional space, treating voxels as coordinates and intensity value at each voxel as their location. Aguilar et al. [34] explored the classification performance of orthogonal projections to latent structures (OPLS), decision trees, artificial neural networks (ANN), and SVM based on 10 features selected from 23 volumetric and 34 cortical thickness variables. Beheshti et al. [35] combined voxel-based morphometry and Fisher Criterion for feature selection and reduction over the entire brain, followed by SVM for classification. The whole-brain techniques have shown high discriminative power for individual diagnoses.
In this paper, we proposed a deformation-based machine learning method that quantified deformation field between subjects as distance and projected each subject onto a low dimensional Euclidean space in which a machine learning algorithm was applied to classify groups of mild AD versus normal elderly subjects, progressive MCI versus normal elderly, and stable MCI versus progressive MCI, aiming for individual patient diagnosis and predicting the conversion to AD in MCI patients.
Materials and methods
Data and subjects
Data used in the study were obtained from the Alzheimer’s Disease Neuroimaging Initiative (ADNI) database (http://adni.loni.usc.edu/). The ADNI was launched in 2003 by the National Institute on Aging (NIA), the National Institute of Biomedical Imaging and Bioengineering (NIBIB), the Food and Drug Administration (FDA), private pharmaceutical companies and non-profit organizations, as a $60 million, 5-year public-private partnership. The primary goal of 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). ADNI is the result of efforts of many investigators from a broad range of academic institutions and private corporations, and subjects have been recruited from over 50 sites across the U.S. and Canada. The ADNI study was approved by IRB of all participating sites. Written informed consent was provided by all subjects and if applicable, their legal representatives. For up-to-date information, see www.adni-info.org.
Data from a total of 427 subjects was retrieved from the ADNI database for whom preprocessed images and FreeSurfer post-processed images were available. The subjects were categorized into groups of normal elderly controls (NC) (n = 135, aged 76.19±5.48), stable MCI subjects (sMCI) (n = 132, aged 75.25±7.27) who had not converted to AD within 36 months, progressive MCI subjects (pMCI) (n = 95, aged 75.1±7.05) who had converted to AD 36 months after their baseline visit, and mild AD patients (n = 65, aged 75.58±8.39). The criteria used to characterize and to track a patient’s level of impairment were as follows: normal controls had a CDR (Clinical Dementia Rating) of 0 and MMSE (Mini-Mental State Examination) score between 24 and 30, MCI subjects had a CDR of 0.5 and MMSE score between 22 and 30, and mild AD patients had a CDR of 1 and MMSE score between 20 and 26 at the baseline test. Detailed demographic information of the studied population was listed in Table 1.
The baseline 3D T1-weighted image of each subject was used for segmentation and classification using FreeSurfer (http://surfer.nmr.mgh.harvard.edu/). In this study, we have only chosen the subjects with provided FreeSurfer processing in the database to exclude segmentation variance due to different software-related settings and standard of quality control. The FreeSurfer processing in ADNI was performed by the team from Center for Imaging of Neurodegenerative Diseases, UCSF. The analysis was completed using Version 4.3 and quality control was conducted with both global and regional assessment, including the checking of skullstripped brainmask, surface segmentation and generation. The classical pipeline (recon-all) was conducted to each image, including intensity normalization, skull stripping, alignment to a standard space, tissue partition, surface reconstruction and inflation, spherical mapping to standard coordinate system, as well as parcellation of cerebral cortex [36–40]. The whole-brain gray matter (GM), whole-brain white matter (WM), frontal lobe, parietal lobe, occipital lobe, temporal lobe, cingulate cortex, as well as amygdala, hippocampus, caudate, putamen, globus pallidus, and thalamus were selected as regions of interest (ROI) (Fig 1).
(a) Six subcortical structures including caudate, putamen, globus pallidus, hippocampus, amygdala, and thalamus were selected as ROIs. (b) Five cerebral cortical regions including frontal, parietal, occipital, temporal, and cingulate were also selected as ROIs.
Registration and distance metric
Images of each subject were affinely aligned to the MNI space using FSL flirt (https://fsl.fmrib.ox.ac.uk/fsl/fslwiki/FLIRT) prior to deformable registration, to remove differences in subject positioning to detect true differences in shape. The symmetric log-domain diffeomorphic demons algorithm was used for the deformable registration, whose output deformation field is invertible and symmetric with respect to the order of the inputs [41]. The algorithm defines a smooth and continuous mapping ϕ(.) that best aligns two images I0(.) and I1(.). The global energy function of diffeomorphic demons is
(1)
where u is the smooth update field, ϕ denotes a warping operation. The optimization is performed within the space of diffeomorphisms using updates of the form ϕ ∘ exp(u). If ϕ is also represented as an exponential of a smooth velocity field v, i.e. ϕ = exp(v), then the diffeomorphic demons is extended to represent the complete spatial transformation in the log domain. Thus the algorithm is called the log-domain diffeomorphic demons. The algorithm defines the updating rule to be
(2)
where Z(v, u) is a velocity field.
The log-domain diffeomorphic demons registration has a symmetric (or inverse-consistent) extension by symmetrizing the energy function
(3)
After registration, the algorithm provides not only the deformation field ϕ, but also the logarithm of the diffeomorphism, v = log(ϕ), which can be directly used in computational anatomical analysis. More details about the symmetric log-domain diffeomorphic demons registration were introduced in the paper of Vercauteren et al. [41].
To compute the distance between images, the Riemannian distance was defined [42]. For each pair of images {Ij, Ik}, the symmetric log-domain diffeomorphic demons algorithm calculated a mapping ϕ from Ik to Ij, a velocity field v = log(ϕ) (that is, ϕ = exp(v)), and an inverse mapping ϕ−1 = exp(−v) from Ij back to Ik. The following equation was used to compute the Riemannian distance between Ij and Ik:
(4)
where Id denotes an identity transformation. In the above equation, ϕROI can be either a diffeomorphism of the whole brain or a sub-field of any segmented region of the brain.
and
represent the log-domain diffeomorphism of the specific ROI in Ij and Ik, respectively. For example, the specific ROI can be the whole-brain gray matter (GM) or white matter (WM), cortical lobes, hippocampus or other subcortical structures.
Embedding algorithm
A distance matrix was constructed after the distance between each pair of subjects was calculated. The embedding algorithm projected all the labeled images onto a low-dimensional space with this distance matrix and a discrimination hyperplane will be obtained by training the labeled subjects on the embedded space. To classify a new unlabeled image, an out-of-sample extension of embedding algorithms was used to project the new subject onto the constructed embedded space.
The metric multi-dimensional scaling (MDS) algorithm was applied for embedding. The idea of metric MDS is to transform the distance matrix into a cross-product matrix and then to find its eigen-decomposition which gives a principal component analysis (PCA). Let Si be the i-th row sum of the distance matrix D, Si = ΣjDij. The cross-product matrix is obtained by using the “double-centering” formula:
(5)
The embedding eim of subject xi is , m = {1,…,M}, where λm denotes the m-th principal eigenvalue and vim denotes the i-th element of the m-th principal eigenvector.
To calculate the embedding coordinate of a new point, define the kernel function yielding the symmetric matrix
on the dataset
, with xi sampled from an unknown distribution with density p:
(6)
where d(a, b) is the original distance and the expectations E are taken over the training data
. Let (vl, λl) be an (eigenvector, eigenvalue) pair that solves
and el denotes the embedding associated with the new point x. Then
(7)
Readers can refer to the work of Bengio et al. for algorithm details and proof [43]. In this study, subjects were all projected onto an space for classification.
Classification
SVM with a linear kernel which was implemented using matlab ‘libsvm’ toolbox (http://www.csie.ntu.edu.tw/~cjlin/libsvm/), was applied on the embedded space to classify subjects. The C-SVM model was chosen, and the cost parameter C was fixed as 1 in all experiments. The k-fold cross validation was adopted to estimate the classification performance. The subjects were randomly partitioned into k “equal” sized subgroups. In this study, as the number of subjects in each group was unequal and may not be evenly divided by k, some subgroups may have one or two more subjects in practice. Of the k subgroups, a single subgroup was used as the validation data and the remaining k-1 subgroups were used as training data. The process was repeated for k times and k was set as 10 in this study. Classification sensitivity, specificity, and accuracy were then calculated. The receiver operating characteristics (ROC) curve was plotted and areas under ROC curve (AUC) was measured.
Results
No significant differences on age were found between each pair of groups using the Student’s t test. For the baseline MMSE score, no significant difference was found only between sMCI and pMCI subjects.
The deformable registration and distance quantification results of two pairs of subjects were shown in Fig 2, where the same reference was used. Images before and after registration, deformation fields, and quantified ROI-specific Riemannian distances for the two source subjects were shown. It was observed that the reference and source images were considerably well aligned using the symmetric log-domain diffeomorphic demons registration. The deformation from the subject who is more morphologically different from the reference was notably larger than that from the other subject. Consequently, the difference was manifest in the quantified distances.
The symmetric log-domain diffeomorphic demons registration well aligned the reference and source images, providing informative deformation fields that accurately reflect morphological difference between subjects.
Classification results for differentiating normal elderly controls and AD patients were summarized in Table 2 and Fig 3. Using the whole-brain gray matter as ROI, the highest classification accuracy was 96.5% with a sensitivity of 93.85%, specificity of 97.78% and AUC of 0.995. In addition, using the other six ROIs including temporal lobe, whole-brain white matter, hippocampus, parietal lobe, amygdala, and frontal lobe, the algorithm achieved high sensitivity and specificity above 90% (AUCs>0.96). The worst performance resulted from caudate, where the sensitivity was substantially lower in discrimination.
(a) Classification sensitivity (green), specificity (blue), and accuracy (red) of normal elderly controls versus AD patients with different ROIs. The highest accuracy (96.5%) was achieved using the whole-brain gray matter as ROI with 93.85% sensitivity and 97.78% specificity. The algorithm obtained high sensitivity and specificity (>90%) with half of the ROIs. (b) The ROC curve of the prediction accuracy between normal controls versus AD. The AUCs were larger than 0.98 for the whole-brain gray matter and white matter (left), amygdala and hippocampus (middle), parietal and temporal lobes (right).
Classification results for normal elderly controls versus progressive MCI subjects were summarized in Table 3 and Fig 4. Our method obtained accuracy of 91.74% with amygdala (87.37% sensitivity, 94.82% specificity, 0.971 AUC) and hippocampus (88.42% sensitivity, 94.07% specificity, 0.963 AUC) as ROI respectively. The sensitivity and specificity were higher than 80% for the other four ROIs including temporal lobe (84.21% and 93.33%), whole-brain gray matter (83.16% and 92.59%), frontal lobe (83.16% and 90.37%), and parietal lobe (81.05% and 91.85%). The sensitivity values were low for the occipital lobe, putamen, thalamus, and globus pallidus, which resulted in lower classification accuracy from 71.74% to 73.91% for these ROIs.
(a) Classification sensitivity (green), specificity (blue), and accuracy (red) of normal elderly controls versus progressive MCI subjects with different ROIs. Using the amygdala, and hippocampus as ROI, the algorithm obtained classification accuracy of 91.74%. With the other six ROIs (temporal, GM, frontal, parietal, caudate, and cingulate), the accuracy exceeded 80%. (b) The ROC curve of the prediction accuracy between normal controls versus progressive MCI. The AUC reached up to 0.971 for amygdala (middle-blue curve), and was larger than 0.91 for hippocampus (0.963), temporal lobe (0.947), the whole-brain gray matter (0.928), parietal lobe (0.928), and frontal lobe (0.912).
Classification results for stable MCI versus progressive MCI subjects were summarized in Table 4 and Fig 5. As in differentiating normal controls and pMCI subjects, amygdala and hippocampus remained the top two ROIs with which the method obtained the highest classification accuracy of 89% (86.32% sensitivity, 90.91% specificity, 0.932 AUC) and 88.5% (84.21% sensitivity, 91.67% specificity, 0.918 AUC) respectively. The algorithm also performed well when using the whole-brain gray matter, frontal lobe, and cingulate cortex as ROI, achieving accuracy over 85% (AUCs>0.875). For the globus pallidus, thalamus, and putamen, we obtained high specificity but significantly lower sensitivity, resulting in classification accuracy lower than 67%.
(a) Classification sensitivity (green), specificity (blue), and accuracy (red) of stable MCI versus progressive MCI subjects with different ROIs. High ranked ROIs included amygdala, hippocampus, the whole-brain gray matter, frontal lobe, and cingulate cortex, with which classification accuracy exceeded 85%. Sensitivity for globus pallidus, thalamus, and putamen was substantially low which resulted in bad performance in discrimination. (b) The ROC curve of the prediction accuracy between stable MCI versus progressive MCI. The AUC reached up to 0.932 for amygdala (middle-blue curve), and 0.918 for hippocampus (middle-maroon curve).
To summarize and compare the classification performance of each ROI, we calculated the mean accuracy for each ROI over the three experiments (Table 5). Hippocampus and amygdala were ranked the top two ROIs with excellent performance for all testing. Gray matter and its subdivisions also got high rankings except for the occipital lobe, followed by the white matter and other subcortical structures.
Discussion
Classification performance compared with existing algorithms
A lot of algorithms have been proposed for early diagnosis of AD with accuracy ranging from 75% to 96% [44–48]. Kloppel et al. considered the voxels of tissue probability maps of the whole brain or volumes of interest (VOI) as features in the classification, obtaining accuracy of 95.6% to discriminate normal controls and AD [33]. In recent work, Beheshti et al. selected the regions with significant difference between groups as VOIs and considered each voxel in the VOIs as a feature, followed by a feature selection step [35]. They obtained 96.32% accuracy between controls and AD. In this work, we observed a classification rate of 96.5% using the whole-brain gray matter as ROI with an AUC of 0.995. For five ROIs, the classification accuracy exceeded 95% indicating that global morphological changes have occurred in mild AD patients and that mild AD is much distinguishable from healthy controls.
By contrast, the brain shape difference between healthy elderly and MCI subjects is smaller, which therefore increases difficulty for discrimination. Fan et al. proposed a method that considered the tissue density from pathology-adaptive anatomical parcellation as features and obtained classification accuracy of 81.8% [48]. Chupin et al. used hippocampal volume to discriminate between elderly controls and progressive MCI who had developed AD in 18 months and obtained 71% accuracy [19]. Our proposed algorithm manifested outstanding performance in the testing, where 91.74% accuracy (0.971 AUC) was obtained to classify MCI who had developed AD at 36 months follow-up. For the ROIs of amygdala, hippocampus, temporal lobe, the whole-brain gray matter, frontal lobe, and parietal lobe, the algorithm obtained AUC values all higher than 0.9.
To distinguish progressive MCI from stable MCI, which is important for prediction of conversion in MCI subjects, is challenging in the MRI-based classification. An algorithm based on hippocampal volume measurement obtained accuracy of 67% [19]. Normalized thickness index in specific cortical regions was considered as features in another algorithm proposed by Querbes et al. [49], where 76% accuracy was obtained to classify MCI converters for the 24-month period. Lillemark et al. reported an classification accuracy of 76.6% using the region-based surface connectivity as features for grouping MCI subjects who had developed AD at 12-month follow-up [50]. Westman et al. [45] and Aguilar et al. [34] collected multiple surface and volumetric indices via FreeSurfer processing and applied multivariate models for discrimination respectively. Westman et al. obtained 75.9% accuracy for MCIs with conversion at 18 months follow-up while Aguilar et al. obtained 86% accuracy for MCIs with conversion at 12 months follow-up. Using the proposed method, we obtained an overall accuracy of 88.99% (0.932 AUC) to classify MCI patients who had progressed to AD after 36 months of baseline visit. Algorithm comparison was summarized in Table 6.
The proposed algorithm developed a new strategy that quantified the deformation field to represent shape difference between subjects rather than comparing the tissue density or surface/volumetric indices. This deformation-based method characterized the macroscopic differences in brain anatomy which were discarded in most of the existing approaches at the spatial normalization step. The quantified deformation was then used to denote dissimilarity between subjects and a distance matrix was constructed. The MDS algorithm used in the study was guaranteed to recover the true dimensionality and geometric structure of manifolds in which each subject represented as an element [52]. Finally MDS constructed an embedding of the data in a low-dimensional Euclidean space that best preserved the manifold’s estimated intrinsic geometry. The advantage of this algorithm may due to the as much information it used in dimensional reduction for spatially representing the similarity relationships between subjects, by computing the pair-wise registration instead of aligning subjects to an atlas or a constructed template, resulting in more informative embedding and consequently an enhanced power to discriminate between different populations.
Prediction of AD conversion in MCI patients
Identifying MCI patients at high risk for conversion to AD is crucial for the effective treatment of the disease. Over the past decade, numerous biomarkers have been proposed for prediction of AD-conversion in MCI patients [19, 34, 45, 49, 50, 53–58]. Cognitive performance data including the Spatial Pattern of Abnormalities for Recognition of Early AD (SPARE-AD) index, AD Assessment Scale-Cognitive (ADAS-Cog) subscale, or composite cognitive scores were introduced to assess AD conversion. However, the accuracy is not satisfactory with a classification rate around 65% [44]. Combining cognitive measures with MRI and age information, the discrimination rate has risen to 82% [57]. Cerebrospinal fluid (CSF) tau and Aβ42 measures have been also proposed as potential predictors of risk for developing AD [59]. Integrating CSF biomarkers together with MRI patterns resulted in accuracy of 62% [53]. When further including positron emission tomography (PET) data and routine clinical tests, the predicting accuracy has increased to 72% [55].
Compared to previous studies using ADNI database, the proposed algorithm based on quantification of MRI deformation demonstrated a promising strategy for predicting MCI-to-AD conversion 3 years in advance with accuracy of 88.99% and AUC of 0.932, which are the highest rates ever reported to the best of our knowledge. If MRI can provide sufficient information for good prediction using a robust algorithm, the use of CSF and PET biomarkers can be avoided as the former requires lumbar puncture which is invasive and painful for patients and the latter suffers its high cost and radiation exposure [60].
Selection of regions of interest for classification
Global and regional cerebral atrophy has been reported in previous studies. Annual rates of global brain atrophy in AD are about 2–3%, compared with 0.2–0.5% in healthy controls [6, 61]. At early stage of AD progression, prominent atrophy has emerged in the medial temporal regions and the posterior cortical regions including posterior cingulate, retrosplenial, and lateral parietal cortex [62]. Medial temporal lobe atrophy, particularly of the amygdala, hippocampus, entorhinal cortex, and parahippocampal gyrus, can be observed with higher frequency in patients with AD or probable AD [63, 64]. Shape changes have also been demonstrated in the caudate, putamen, globus pallidus, and thalamus in AD [65].
Although remarkable morphological alterations were found in a certain regions in AD or prodromal AD at the group level, individual classification based on different regions in this study yielded substantially distinct results. The whole-brain gray matter and temporal lobe performed the best in distinguishing AD from normal elderly controls, while amygdala and hippocampus worked better in classifying progressive MCI versus either healthy elderly or stable MCI. This result was mostly consistent with the previous finding that significantly increased rates of hippocampal atrophy were observed in presymptomatic and mild AD, while more widespread tissue shrinkage has been shown in mild to moderate AD patients [6, 66]. Evidence have also been documented that increased oxygen extraction capacity and tissue atrophy were observed in basal ganglia and thalamus in patient with AD [65, 67]. These ROIs indeed resulted in a classification accuracy higher than 80% in discriminating AD, nevertheless much lower in classifying progressive MCI, indicating that shape changes of basal ganglia and thalamus were prominent features in AD but not yet in the prodromal stage. By an integrative comparison, we proposed that hippocampus, amygdala, the whole-brain gray matter, temporal lobe, and parietal lobe should be of higher preference for AD or MCI classification, where amygdala and hippocampus could be the leading candidate for predicting AD conversion in MCI, while occipital lobe, thalamus, globus pallidus, and putamen should be non-priority selections for early diagnosis.
Conclusion
In this study, we proposed a deformation-based machine learning method for discrimination of AD and prediction of MCI-to-AD conversion with high resolution MRI. The proposed algorithm showed great performance on both classification and prediction of AD, with 96.5% accuracy discriminating AD from healthy elderly, 91.74% accuracy for progressive MCI versus healthy elderly, and 88.99% accuracy for progressive MCI versus stable MCI. Large deformation in hippocampus and amygdala was advantageous to differentiate progressive MCI patients, while diffusive morphological changes in the whole-brain gray matter were prominent to identify mild or moderate AD patients.
The limitation of the algorithm is that it was computational expensive. A balance between classification accuracy and computational time should be achieved in our future research. In general, MRI-based analysis can be a beneficial supplement to clinical diagnosis and prediction of AD.
Acknowledgments
Data used in preparation of this study were obtained from the Alzheimer's Disease Neuroimaging Initiative (ADNI) database (http://adni.loni.usc.edu/). As such, the investigators within the ADNI contributed to the design and implementation of ADNI and/or provided data but did not participate in analysis or writing of this paper. A complete list of ADNI investigators can be found at: http://adni.loni.usc.edu/wp-content/uploads/how_to_apply/ADNI_Acknowledgement_List.pdf.
Data collection and sharing for this project was funded by the Alzheimer's Disease Neuroimaging Initiative (ADNI). ADNI is funded by the National Institute on Aging, the National Institute of Biomedical Imaging and Bioengineering, and through generous contributions from the following: Abbott; Alzheimer's Association; Alzheimer's Drug Discovery Foundation; Amorfix Life Sciences Ltd.; AstraZeneca; Bayer HealthCare; BioClinica, Inc.; Biogen Idec Inc.; Bristol-Myers Squibb Company; Eisai Inc.; Elan Pharmaceuticals Inc.; Eli Lilly and Company; F. Hoffmann-La Roche Ltd and its affiliated company Genentech, Inc.; GE Healthcare; Innogenetics, N.V.; Janssen Alzheimer Immunotherapy Research & Development, LLC.; Johnson & Johnson Pharmaceutical Research & Development LLC.; Medpace, Inc.; Merck & Co., Inc.; Meso Scale Diagnostics, LLC.; Novartis Pharmaceuticals Corporation; Pfizer Inc.; Servier; Synarc Inc.; and Takeda Pharmaceutical Company. The Canadian Institutes of Health Research is providing funds to support ADNI clinical sites in Canada. Private sector contributions are facilitated by the Foundation for the National Institutes of Health (www.fnih.org).
Author Contributions
- Conceptualization: XL LZ.
- Data curation: XL.
- Formal analysis: XL LC.
- Funding acquisition: XL LC LZ.
- Investigation: XL LC.
- Methodology: XL.
- Project administration: LZ.
- Software: XL CJ.
- Validation: XL LZ.
- Visualization: XL LC.
- Writing – original draft: XL.
- Writing – review & editing: LZ LC.
References
- 1. Braak H, Braak E. Neuropathological stageing of Alzheimer-related changes. Acta neuropathologica. 1991;82(4):239–59. Epub 1991/01/01. pmid:1759558
- 2. Tiraboschi P, Hansen LA, Thal LJ, Corey-Bloom J. The importance of neuritic plaques and tangles to the development and evolution of AD. Neurology. 2004;62(11):1984–9. Epub 2004/06/09. pmid:15184601
- 3. Blennow K, de Leon MJ, Zetterberg H. Alzheimer's disease. Lancet (London, England). 2006;368(9533):387–403. Epub 2006/08/01.
- 4. Harvey PD, Moriarty PJ, Kleinman L, Coyne K, Sadowsky CH, Chen M, et al. The validation of a caregiver assessment of dementia: the Dementia Severity Scale. Alzheimer disease and associated disorders. 2005;19(4):186–94. Epub 2005/12/06. pmid:16327345
- 5. Dubois B, Feldman HH, Jacova C, Dekosky ST, Barberger-Gateau P, Cummings J, et al. Research criteria for the diagnosis of Alzheimer's disease: revising the NINCDS-ADRDA criteria. The Lancet Neurology. 2007;6(8):734–46. Epub 2007/07/10. pmid:17616482
- 6. Fox NC, Schott JM. Imaging cerebral atrophy: normal ageing to Alzheimer's disease. Lancet (London, England). 2004;363(9406):392–4. Epub 2004/04/13.
- 7. Jack CR Jr., Petersen RC, Xu YC, O'Brien PC, Smith GE, Ivnik RJ, et al. Prediction of AD with MRI-based hippocampal volume in mild cognitive impairment. Neurology. 1999;52(7):1397–403. Epub 1999/05/05. pmid:10227624
- 8. Barnes J, Scahill RI, Boyes RG, Frost C, Lewis EB, Rossor CL, et al. Differentiating AD from aging using semiautomated measurement of hippocampal atrophy rates. NeuroImage. 2004;23(2):574–81. Epub 2004/10/19. pmid:15488407
- 9. Colliot O, Chetelat G, Chupin M, Desgranges B, Magnin B, Benali H, et al. Discrimination between Alzheimer disease, mild cognitive impairment, and normal aging by using automated segmentation of the hippocampus. Radiology. 2008;248(1):194–201. Epub 2008/05/07. pmid:18458242
- 10. Good CD, Scahill RI, Fox NC, Ashburner J, Friston KJ, Chan D, et al. Automatic differentiation of anatomical patterns in the human brain: validation with studies of degenerative dementias. NeuroImage. 2002;17(1):29–46. Epub 2002/12/17. pmid:12482066
- 11. Busatto GF, Garrido GE, Almeida OP, Castro CC, Camargo CH, Cid CG, et al. A voxel-based morphometry study of temporal lobe gray matter reductions in Alzheimer's disease. Neurobiology of aging. 2003;24(2):221–31. Epub 2002/12/25. pmid:12498956
- 12. Tapiola T, Pennanen C, Tapiola M, Tervo S, Kivipelto M, Hanninen T, et al. MRI of hippocampus and entorhinal cortex in mild cognitive impairment: a follow-up study. Neurobiology of aging. 2008;29(1):31–8. Epub 2006/11/14. pmid:17097769
- 13. Xu Y, Jack CR Jr., O'Brien PC, Kokmen E, Smith GE, Ivnik RJ, et al. Usefulness of MRI measures of entorhinal cortex versus hippocampus in AD. Neurology. 2000;54(9):1760–7. Epub 2000/05/10. pmid:10802781
- 14. Hirata Y, Matsuda H, Nemoto K, Ohnishi T, Hirao K, Yamashita F, et al. Voxel-based morphometry to discriminate early Alzheimer's disease from controls. Neuroscience letters. 2005;382(3):269–74. Epub 2005/06/01. pmid:15925102
- 15. Bozzali M, Filippi M, Magnani G, Cercignani M, Franceschi M, Schiatti E, et al. The contribution of voxel-based morphometry in staging patients with mild cognitive impairment. Neurology. 2006;67(3):453–60. Epub 2006/08/09. pmid:16894107
- 16. Vemuri P, Gunter JL, Senjem ML, Whitwell JL, Kantarci K, Knopman DS, et al. Alzheimer's disease diagnosis in individual subjects using structural MR images: validation studies. NeuroImage. 2008;39(3):1186–97. Epub 2007/12/07. pmid:18054253
- 17. Chetelat G, Landeau B, Eustache F, Mezenge F, Viader F, de la Sayette V, et al. Using voxel-based morphometry to map the structural changes associated with rapid conversion in MCI: a longitudinal MRI study. NeuroImage. 2005;27(4):934–46. Epub 2005/06/28. pmid:15979341
- 18. Lao Z, Shen D, Xue Z, Karacali B, Resnick SM, Davatzikos C. Morphological classification of brains via high-dimensional shape transformations and machine learning methods. NeuroImage. 2004;21(1):46–57. Epub 2004/01/27. pmid:14741641
- 19. Chupin M, Gerardin E, Cuingnet R, Boutet C, Lemieux L, Lehericy S, et al. Fully automatic hippocampus segmentation and classification in Alzheimer's disease and mild cognitive impairment applied on data from ADNI. Hippocampus. 2009;19(6):579–87. Epub 2009/05/14. pmid:19437497
- 20. Gutman B, Wang Y, Morra J, Toga AW, Thompson PM. Disease classification with hippocampal shape invariants. Hippocampus. 2009;19(6):572–8. Epub 2009/05/14. pmid:19437498
- 21. Gerardin E, Chetelat G, Chupin M, Cuingnet R, Desgranges B, Kim HS, et al. Multidimensional classification of hippocampal shape features discriminates Alzheimer's disease and mild cognitive impairment from normal aging. NeuroImage. 2009;47(4):1476–86. Epub 2009/05/26. pmid:19463957
- 22. Wolz R, Julkunen V, Koikkalainen J, Niskanen E, Zhang DP, Rueckert D, et al. Multi-Method Analysis of MRI Images in Early Diagnostics of Alzheimer's Disease. PLoS One. 2011;6(10):e25446. pmid:22022397
- 23. Ewers M, Walsh C, Trojanowski JQ, Shaw LM, Petersen RC, Jack CR Jr., et al. Prediction of conversion from mild cognitive impairment to Alzheimer's disease dementia based upon biomarkers and neuropsychological test performance. Neurobiology of aging. 2012;33(7):1203–14. Epub 2010/12/17. pmid:21159408
- 24. Duchesne S, Caroli A, Geroldi C, Barillot C, Frisoni GB, Collins DL. MRI-based automated computer classification of probable AD versus normal controls. IEEE transactions on medical imaging. 2008;27(4):509–20. Epub 2008/04/09. pmid:18390347
- 25. Karas GB, Scheltens P, Rombouts SA, Visser PJ, van Schijndel RA, Fox NC, et al. Global and local gray matter loss in mild cognitive impairment and Alzheimer's disease. NeuroImage. 2004;23(2):708–16. Epub 2004/10/19. pmid:15488420
- 26. Lerch JP, Pruessner JC, Zijdenbos A, Hampel H, Teipel SJ, Evans AC. Focal decline of cortical thickness in Alzheimer's disease identified by computational neuroanatomy. Cerebral cortex (New York, NY: 1991). 2005;15(7):995–1001. Epub 2004/11/13.
- 27. Yang W, Lui RL, Gao JH, Chan TF, Yau ST, Sperling RA, et al. Independent component analysis-based classification of Alzheimer's disease MRI data. Journal of Alzheimer's disease: JAD. 2011;24(4):775–83. Epub 2011/02/16. pmid:21321398
- 28. Adaszewski S, Dukart J, Kherif F, Frackowiak R, Draganski B. How early can we predict Alzheimer's disease using computational anatomy? Neurobiology of aging. 2013;34(12):2815–26. Epub 2013/07/31. pmid:23890839
- 29. Varol E, Gaonkar B, Erus G, Schultz R, Davatzikos C. FEATURE RANKING BASED NESTED SUPPORT VECTOR MACHINE ENSEMBLE FOR MEDICAL IMAGE CLASSIFICATION. Proceedings IEEE International Symposium on Biomedical Imaging. 2012:146–9. Epub 2012/01/01. pmid:23873289
- 30. Spulber G, Simmons A, Muehlboeck JS, Mecocci P, Vellas B, Tsolaki M, et al. An MRI-based index to measure the severity of Alzheimer's disease-like structural pattern in subjects with mild cognitive impairment. Journal of internal medicine. 2013;273(4):396–409. Epub 2013/01/03. pmid:23278858
- 31. Koikkalainen J, Lotjonen J, Thurfjell L, Rueckert D, Waldemar G, Soininen H. Multi-template tensor-based morphometry: application to analysis of Alzheimer's disease. NeuroImage. 2011;56(3):1134–44. Epub 2011/03/23. pmid:21419228
- 32. Nho K, Shen L, Kim S, Risacher SL, West JD, Foroud T, et al. Automatic Prediction of Conversion from Mild Cognitive Impairment to Probable Alzheimer's Disease using Structural Magnetic Resonance Imaging. AMIA Annual Symposium proceedings AMIA Symposium. 2010;2010:542–6. Epub 2011/02/25. pmid:21347037
- 33. Kloppel S, Stonnington CM, Chu C, Draganski B, Scahill RI, Rohrer JD, et al. Automatic classification of MR scans in Alzheimer's disease. Brain: a journal of neurology. 2008;131(Pt 3):681–9. Epub 2008/01/19.
- 34. Aguilar C, Westman E, Muehlboeck JS, Mecocci P, Vellas B, Tsolaki M, et al. Different multivariate techniques for automated classification of MRI data in Alzheimer's disease and mild cognitive impairment. Psychiatry research. 2013;212(2):89–98. Epub 2013/04/02. pmid:23541334
- 35. Beheshti I, Demirel H. Feature-ranking-based Alzheimer's disease classification from structural MRI. Magnetic resonance imaging. 2016;34(3):252–63. Epub 2015/12/15. pmid:26657976
- 36. Dale A, Fischl B, Sereno M. Cortical surface-based analysis i: Segmentation and surface reconstruction. NeuroImage. 1999;9(2):179–94. pmid:9931268
- 37. Dale A, Sereno M. Improved localization of cortical activity by combining EEG and MEG with MRI cortical surface reconstruction: a linear approach. J Cogn Neurosci 1993;5:162–76. pmid:23972151
- 38. Fischl B, Sereno M, Dale A. Cortical surface-based analysis-ii: inflation, flatting, and a surface-based coordinate system. NeuroImage. 1999;9:195–207. pmid:9931269
- 39. Desikan R, Segonne F, Fischl B, Quinn B, Dickerson B, Blacker D, et al. An automated labeling system for subdividing the human cerebral cortex on MRI scans into gyral based regions of interest. NeuroImage. 2006;31(3):968–80. pmid:16530430
- 40. Fischl B, van der Kouwe A, Destrieux C, Halgren E, Segonne F, Salat D, et al. Automatically Parcellating the Human Cerebral Cortex. Cerebral cortex (New York, NY: 1991). 2004;14:11–22.
- 41. Vercauteren T, Pennec X, Perchant A, Ayache N. Symmetric log-domain diffeomorphic Registration: a demons-based approach. Medical image computing and computer-assisted intervention: MICCAI International Conference on Medical Image Computing and Computer-Assisted Intervention. 2008;11(Pt 1):754–61. Epub 2008/11/05.
- 42.
Fletcher PT, Lu C, Joshi S, editors. Statistics of shape via principal geodesic analysis on Lie groups. IEEE Computer Society Conference on Computer Vision and Pattern Recognition, vol 1, page I-95–I-101; 2003.
- 43.
Bengio Y, Paiement J, Vincent P, Delalleau O, Roux N, Ouimet M. Out-of-Sample Extensions for LLE, ISPMAP, MDS, Eigenmaps, and Spectral Clustering. Advances in Neural Information Processing Systems. Cambridge, MA, USA: The MIT Press; 2004.
- 44. Casanova R, Whitlow CT, Wagner B, Williamson J, Shumaker SA, Maldjian JA, et al. High dimensional classification of structural MRI Alzheimer’s disease data based on large scale regularization. Frontiers in Neuroinformatics. 2011;5:Article 22.
- 45. Westman E, Muehlboeck JS, Simmons A. Combining MRI and CSF measures for classification of Alzheimer's disease and prediction of mild cognitive impairment conversion. NeuroImage. 2012;62(1):229–38. Epub 2012/05/15. pmid:22580170
- 46. Willette AA, Calhoun VD, Egan JM, Kapogiannis D. Prognostic classification of mild cognitive impairment and Alzheimer's disease: MRI independent component analysis. Psychiatry research. 2014;224(2):81–8. Epub 2014/09/10. pmid:25194437
- 47. Zhou Q, Goryawala M, Cabrerizo M, Wang J, Barker W, Loewenstein DA, et al. An Optimal Decisional Space for the Classification of Alzheimer's Disease and Mild Cognitive Impairment. IEEE Transactions on Biomedical Engineering. 2014;61(8):2245–53. pmid:25051543
- 48. Fan Y, Batmanghelich N, Clark CM, Davatzikos C. Spatial patterns of brain atrophy in MCI patients, identified via high-dimensional pattern classification, predict subsequent cognitive decline. NeuroImage. 2008;39(4):1731–43. Epub 2007/12/07. pmid:18053747
- 49. Querbes O, Aubry F, Pariente J, Lotterie JA, Demonet JF, Duret V, et al. Early diagnosis of Alzheimer's disease using cortical thickness: impact of cognitive reserve. Brain: a journal of neurology. 2009;132(Pt 8):2036–47. Epub 2009/05/15.
- 50. Lillemark L, Sorensen L, Pai A, Dam EB, Nielsen M. Brain region's relative proximity as marker for Alzheimer's disease based on structural MRI. BMC medical imaging. 2014;14:21. Epub 2014/06/04. pmid:24889999
- 51. Magnin B, Mesrob L, Kinkingnehun S, Pelegrini-Issac M, Colliot O, Sarazin M, et al. Support vector machine-based classification of Alzheimer's disease from whole-brain anatomical MRI. Neuroradiology. 2009;51(2):73–83. Epub 2008/10/11. pmid:18846369
- 52. Tenenbaum JB, de Silva V, Langford JC. A global geometric framework for nonlinear dimensionality reduction. Science (New York, NY). 2000;290(5500):2319–23. Epub 2000/12/23.
- 53. Davatzikos C, Bhatt P, Shaw LM, Batmanghelich KN, Trojanowski JQ. Prediction of MCI to AD conversion, via MRI, CSF biomarkers, and pattern classification. Neurobiology of aging. 2011;32(12):2322 e19–27. Epub 2010/07/03.
- 54. Zhang D, Shen D, the AsDNI. Predicting Future Clinical Changes of MCI Patients Using Longitudinal and Multimodal Biomarkers. PLoS One. 2012;7(3):e33182. pmid:22457741
- 55. Shaffer JL, Petrella JR, Sheldon FC, Choudhury KR, Calhoun VD, Coleman RE, et al. Predicting cognitive decline in subjects at risk for Alzheimer disease by using combined cerebrospinal fluid, MR imaging, and PET biomarkers. Radiology. 2013;266(2):583–91. Epub 2012/12/13. pmid:23232293
- 56. C R, H FC, S KM, R SR, W JD, R SM, et al. Alzheimer's disease risk assessment using large-scale machine learning methods. PLoS One. 2013;8(11):e77949. pmid:24250789
- 57. Moradi E, Pepe A, Gaser C, Huttunen H, Tohka J. Machine learning framework for early MRI-based Alzheimer's conversion prediction in MCI subjects. NeuroImage. 2015;104:398–412. Epub 2014/10/15. pmid:25312773
- 58. Misra C, Fan Y, Davatzikos C. Baseline and longitudinal patterns of brain atrophy in MCI patients, and their use in prediction of short-term conversion to AD: results from ADNI. NeuroImage. 2009;44(4):1415–22. Epub 2008/11/26. pmid:19027862
- 59. Shaw LM, Vanderstichele H, Knapik-Czajka M, Clark CM, Aisen PS, Petersen RC, et al. Cerebrospinal fluid biomarker signature in Alzheimer's disease neuroimaging initiative subjects. Annals of neurology. 2009;65(4):403–13. Epub 2009/03/20. pmid:19296504
- 60. Musiek ES, Chen Y, Korczykowski M, Saboury B, Martinez PM, Reddin JS, et al. Direct comparison of fluorodeoxyglucose positron emission tomography and arterial spin labeling magnetic resonance imaging in Alzheimer's disease. Alzheimer's & dementia: the journal of the Alzheimer's Association. 2012;8(1):51–9. Epub 2011/10/25.
- 61. Fox NC, Scahill RI, Crum WR, Rossor MN. Correlation between rates of brain atrophy and cognitive decline in AD. Neurology. 1999;52(8):1687–9. Epub 1999/05/20. pmid:10331700
- 62. Buckner RL, Snyder AZ, Shannon BJ, LaRossa G, Sachs R, Fotenos AF, et al. Molecular, structural, and functional characterization of Alzheimer's disease: evidence for a relationship between default activity, amyloid, and memory. The Journal of neuroscience: the official journal of the Society for Neuroscience. 2005;25(34):7709–17. Epub 2005/08/27.
- 63. Petrella JR, Coleman RE, Doraiswamy PM. Neuroimaging and early diagnosis of Alzheimer disease: a look to the future. Radiology. 2003;226(2):315–36. Epub 2003/02/04. pmid:12563122
- 64. Poulin SP, Dautoff R, Morris JC, Barrett LF, Dickerson BC. Amygdala atrophy is prominent in early Alzheimer's disease and relates to symptom severity. Psychiatry research. 2011;194(1):7–13. Epub 2011/09/17. pmid:21920712
- 65. Cho H, Kim JH, Kim C, Ye BS, Kim HJ, Yoon CW, et al. Shape changes of the basal ganglia and thalamus in Alzheimer's disease: a three-year longitudinal study. Journal of Alzheimer's disease: JAD. 2014;40(2):285–95. Epub 2014/01/15. pmid:24413620
- 66. Scahill RI, Schott JM, Stevens JM, Rossor MN, Fox NC. Mapping the evolution of regional atrophy in Alzheimer's disease: unbiased analysis of fluid-registered serial MRI. Proceedings of the National Academy of Sciences of the United States of America. 2002;99(7):4703–7. Epub 2002/04/04. pmid:11930016
- 67. Eskildsenemail S, Gyldensted L, Nagenthiraja K, Frandsen J, Rodell A, Gyldensted C, et al. Increased oxygen extraction capacity in the basal ganglia and thalamus of people with Alzheimer's disease. Alzheimer's and Dementia. 2013;9(4):Suppl. pp 102.