Hybrid High-order Functional Connectivity Networks Using Resting-state Functional MRI for Mild Cognitive Impairment Diagnosis

Conventional functional connectivity (FC), referred to as low-order FC, estimates temporal correlation of the resting-state functional magnetic resonance imaging (rs-fMRI) time series between any pair of brain regions, simply ignoring the potentially high-level relationship among these brain regions. A high-order FC based on "correlation's correlation" has emerged as a new approach for abnormality detection of brain disease. However, separate construction of the low- and high-order FC networks overlooks information exchange between the two FC levels. Such a higher-level relationship could be more important for brain diseases study. In this paper, we propose a novel framework, namely "hybrid high-order FC networks" by exploiting the higher-level dynamic interaction among brain regions for early mild cognitive impairment (eMCI) diagnosis. For each sliding window-based rs-fMRI sub-series, we construct a whole-brain associated high-order network, by estimating the correlations between the topographical information of the high-order FC sub-network from one brain region and that of the low-order FC sub-network from another brain region. With multi-kernel learning, complementary features from multiple time-varying FC networks constructed at different levels are fused for eMCI classification. Compared with other state-of-the-art methods, the proposed framework achieves superior diagnosis accuracy, and hence could be promising for understanding pathological changes of brain connectome

Une nouvelle approche pour l’identification des états dynamiques de la parcellisation fonctionnelle cérébrale individuelle

Les parcellations cérébrales sont appliquées en neuroimagerie pour aider les chercheurs à ré- duire la haute dimensionnalité des données d’IRM fonctionnelle. L’objectif principal est une meilleure compréhension de l’organisation fonctionnelle du cerveau tant chez les sujets sains que chez les sujets souffrant de troubles neurologiques, dont la maladie d’Alzheimer. Malgré la vague d’approches de parcellations précédentes, les mesures de performance doivent en- core être améliorées pour générer des parcellations fiables, même avec de longues acquisitions. Autrement dit, une reproductibilité plus élevée qui permet aux chercheurs de reproduire des parcellations et de comparer leurs études. Il est également important de minimiser la perte d’informations entre les données compressées et les données brutes pour représenter avec précision l’organisation d’un cerveau individuel. Dans cette thèse, j’ai développé une nou- velle approche pour parcellaire le cerveau en reconfigurations spatiales distinctes appelées «états dynamiques de parcellations». J’ai utilisé une méthode d’agrégation de cluster simple DYPAC1.0 de parcelles basées sur des semences sur plusieurs fenêtres de temps. J’ai émis l’hypothèse que cette nouvelle façon de formaliser le problème de parcellisation améliorera les mesures de performance par rapport aux parcellations statiques. Le premier chapitre de ce document est une introduction générale au contexte des réseaux à grande échelle du cerveau humain. Je montre également l’importance des parcellations pour une meilleure compréhension du cerveau humain à l’aide de connectomes fonctionnels afin de prédire les schémas de progression de la maladie. Ensuite, j’explique pourquoi le problème de parcelli- sation cérébrale est difficile et les différentes questions de recherche ouvertes associées à ce domaine. Mes contributions à la recherche sont subdivisées en deux articles. Les deuxième et troisième chapitres sont consacrés au premier article principal et à son supplément publié dans Network Neuroscience Journal. Le quatrième chapitre représente le deuxième document en préparation. Le cinquième chapitre conclut mes contributions et ses implications dans le domaine de la neuroimagerie, ainsi que des orientations de recherche ouvertes. En un mot, la principale conclusion de ce travail est l’existence de reconfigurations spatiales distinctes dans tout le cerveau avec des scores de reproductibilité presque parfaits sur les données de test-retest (jusqu’à 0,9 coefficient de corrélation de Pearson). Un algorithme d’agrégation de cluster simple et évolutif appelé DYPAC 1.0 est expliqué pour identifier ces reconfigu- rations ou «états dynamiques de parcellations» pour des sous-réseaux de départ spécifiques (deuxième chapitre). L’analyse de ces états a montré l’existence d’un répertoire plus riche «d’états dynamiques» dans le cas des cortex hétéromodaux (ex: cortex cingulaire posté- rieur et cortex cingulaire antérieur dorsal) par rapport aux cortex unimodaux (ex: cortex visuel). En outre, les résultats de l’analyse de reproductibilité ont montré que DYPAC 1.0 a de meilleurs résultats de reproductibilité (en termes de corrélation de Pearson) par rapport aux parcelles statiques (deuxième chapitre). Plusieurs analyses démontrent que DYPAC 1.0 est robuste au choix de ses paramètres (troisième chapitre). Ces résultats et l’évolutivité de DYPAC 1.0 ont motivé une analyse complète du niveau cérébral. Je présente DYPAC 2.0 comme une approche au niveau cérébral complet pour fragmenter le cerveau en «états dynamiques de parcellations». Des reconfigurations spatiales distinctes et se chevauchant ou «états dynamiques» sont identifiées pour différentes régions du cerveau (quatrième chapitre). Ces états ont des scores de compression prometteurs qui montrent une faible perte d’infor- mations entre les cartes de stabilité d’état réduit et les données d’origine dans les cortex cérébraux, c’est-à-dire jusqu’à seulement 20% de perte de la variance expliquée. Cette thèse présente ainsi de nouvelles contributions dans le domaine de la parcellisation fonctionnelle qui pourraient avoir un impact sur la manière dont les chercheurs modélisent les interactions riches et dynamiques entre les réseaux cérébraux dans la santé et la maladie.Brain parcellations are applied in neuroimaging to help researchers reduce the high dimen- sionality of the functional MRI data. The main objective is a better understanding of the brain functional organization in both healthy subjects and subjects having neurological dis- orders, including Alzheimer disease. Despite the flurry of previous parcellation approaches, the performance measures still need improvement to generate reliable parcellations even with long acquisitions. That is, a higher reproducibility that allows researchers to replicate par- cellations and compare their studies. It is also important to minimize the information loss between the compressed data and the raw data to accurately represent the organization of an individual brain. In this thesis, I developed a new approach to parcellate the brain into distinct spatial reconfigurations called “dynamic states of parcellations”. I used a simple cluster aggregation method DYPAC1.0 of seed based parcels over multiple time windows. I hypothesized this new way to formalize the parcellation problem will improve performance measures over static parcellations. The first chapter of this document is a general context introduction to the human brain large scale networks. I also show the importance of par- cellations for a better understanding of the human brain using functional connectomes in order to predict patterns of disease progression. Then, I explain why the brain parcellation problem is hard and the different open research questions associated with this field. My research contributions are subdivided into two papers. The second and the third chapters are dedicated to the first main paper and its supplementary published in Network Neuro- science Journal. The fourth chapter represents the second paper under preparation. The fifth chapter concludes my contributions and its implications in the neuroimaging field, along with open research directions. In a nutshell, the main finding of this work is the existence of distinct spatial reconfigurations throughout the brain with near perfect reproducibility scores across test-retest data (up to .9 Pearson correlation coefficient). A simple and scalable clus- ter aggregation algorithm called DYPAC 1.0 is explained to identify these reconfigurations or “dynamic states of parcellations” for specific seed subnetworks (second chapter). The analysis of these states showed the existence of a richer repertoire of “dynamic states” in the case of heteromodal cortices (e.g., posterior cingulate cortex and the dorsal anterior cingulate cortex) compared to unimodal cortices (e.g., visual cortex). Also, the reproducibility analysis results showed that DYPAC 1.0 has better reproducibility results (in terms of Pearson corre- lation) compared to static parcels (second chapter). Several analyses demonstrate DYPAC 1.0 is robust to the choice of its parameters (third chapter). These findings and the scalabil- ity of DYPAC 1.0 motivated a full brain level analysis. I present DYPAC 2.0 as the full brain level approach to parcellate the brain into “dynamic states of parcellations”. Distinct and overlapping spatial reconfigurations or “dynamic states” are identified for different regions throughout the brain (fourth chapter). These states have promising compression scores that show low information loss between the reduced state stability maps and the original data throughout the cerebral cortices, i.e. up to only 20% loss in explained variance. This thesis thus presents new contributions in the functional parcellation field that may impact how researchers model the rich and dynamic interactions between brain networks in health and disease

Diagnosis of Brain Diseases via Multi-Scale Time-Series Model

The functional magnetic resonance imaging (fMRI) data and brain network analysis have been widely applied to automated diagnosis of neural diseases or brain diseases. The fMRI time series data not only contains specific numerical information, but also involves rich dynamic temporal information, those previous graph theory approaches focus on local topology structure and lose contextual information and global fluctuation information. Here, we propose a novel multi-scale functional connectivity for identifying the brain disease via fMRI data. We calculate the discrete probability distribution of co-activity between different brain regions with various intervals. Also, we consider nonsynchronous information under different time dimensions, for analyzing the contextual information in the fMRI data. Therefore, our proposed method can be applied to more disease diagnosis and other fMRI data, particularly automated diagnosis of neural diseases or brain diseases. Finally, we adopt Support Vector Machine (SVM) on our proposed time-series features, which can be applied to do the brain disease classification and even deal with all time-series data. Experimental results verify the effectiveness of our proposed method compared with other outstanding approaches on Alzheimer’s Disease Neuroimaging Initiative (ADNI) dataset and Major Depressive Disorder (MDD) dataset. Therefore, we provide an efficient system via a novel perspective to study brain networks

Classifying Cognitive Profiles Using Machine Learning with Privileged Information in Mild Cognitive Impairment

Early diagnosis of dementia is critical for assessing disease progression and potential treatment. State-or-the-art machine learning techniques have been increasingly employed to take on this diagnostic task. In this study, we employed Generalised Matrix Learning Vector Quantization (GMLVQ) classifiers to discriminate patients with Mild Cognitive Impairment (MCI) from healthy controls based on their cognitive skills. Further, we adopted a ``Learning with privileged information'' approach to combine cognitive and fMRI data for the classification task. The resulting classifier operates solely on the cognitive data while it incorporates the fMRI data as privileged information (PI) during training. This novel classifier is of practical use as the collection of brain imaging data is not always possible with patients and older participants.MCI patients and healthy age-matched controls were trained to extract structure from temporal sequences. We ask whether machine learning classifiers can be used to discriminate patients from controls based on the learning performance and whether differences between these groups relate to individual cognitive profiles. To this end, we tested participants in four cognitive tasks: working memory, cognitive inhibition, divided attention, and selective attention. We also collected fMRI data before and after training on the learning task and extracted fMRI responses and connectivity as features for machine learning classifiers. Our results show that the PI guided GMLVQ classifiers outperform the baseline classifier that only used the cognitive data. In addition, we found that for the baseline classifier, divided attention is the only relevant cognitive feature. When PI was incorporated, divided attention remained the most relevant feature while cognitive inhibition became also relevant for the task. Interestingly, this analysis for the fMRI GMLVQ classifier suggests that (1) when overall fMRI signal for structured stimuli is used as inputs to the classifier, the post-training session is most relevant; and (2) when the graph feature reflecting underlying spatiotemporal fMRI pattern is used, the pre-training session is most relevant. Taken together these results suggest that brain connectivity before training and overall fMRI signal after training are both diagnostic of cognitive skills in MCI