Reorganization of Functional Networks in Mild Cognitive Impairment

Buldú, Javier M.; Bajo, Ricardo; Maestú, Fernando; Castellanos, Nazareth P.; Leyva, I.; Gil, Pablo; Sendiña‐Nadal, Irene; Almendral, Juan A.; Nevado, Ángel; del-Pozo, Francisco; Boccaletti, Stefano

doi:10.1371/journal.pone.0019584

Cited by 128 publications

(144 citation statements)

References 39 publications

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“…This increase in functional connectivity is usually interpreted as a compensatory mechanism and is associated with the risk for the progression to AD (Rossini et al 2006). Indeed, it seems to indicate a loss of brain efficiency (Buldú et al 2011). This discrepancy between cognitive task and resting state studies could be due to the differences in the nature of brain state during resting and cognitive tasks.…”

Section: Introductionmentioning

confidence: 98%

Synchronization during an internally directed cognitive state in healthy aging and mild cognitive impairment: a MEG study

López

Garcés

Cuesta

et al. 2014

AGE

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Mild cognitive impairment (MCI) is a stage between healthy aging and dementia. It is known that in this condition the connectivity patterns are altered in the resting state and during cognitive tasks, where an extra effort seems to be necessary to overcome cognitive decline. We aimed to determine the functional connectivity AGE (2014) pattern required to deal with an internally directed cognitive state (IDICS) in healthy aging and MCI. This task differs from the most commonly employed ones in neurophysiology, since inhibition from external stimuli is needed, allowing the study of this control mechanism. To this end, magnetoencephalographic (MEG) signals were acquired from 32 healthy individuals and 38 MCI patients, both in resting state and while performing a subtraction task of two levels of difficulty. Functional connectivity was assessed with phase locking value (PLV) in five frequency bands. Compared to controls, MCIs showed higher PLV values in delta, theta, and gamma bands and an opposite pattern in alpha, beta, and gamma bands in resting state. These changes were associated with poorer neuropsychological performance. During the task, this group exhibited a hypersynchronization in delta, theta, beta, and gamma bands, which was also related to a lower cognitive performance, suggesting an abnormal functioning in this group. Contrary to controls, MCIs presented a lack of synchronization in the alpha band which may denote an inhibition deficit. Additionally, the magnitude of connectivity changes rose with the task difficulty in controls but not in MCIs, in line with the compensation-related utilization of neural circuits hypothesis (CRUNCH) model.

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Section: Introductionmentioning

confidence: 98%

Synchronization during an internally directed cognitive state in healthy aging and mild cognitive impairment: a MEG study

López

Garcés

Cuesta

et al. 2014

AGE

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“…The common linear methods [85,86] mainly include Pearson correlation, partial correlation, and partial coherence. The common nonlinear methods mainly include synchronization likelihood [21,34], mutual information [87], and wavelet correlation [88,89]. For example, the Pearson correlation between brain regional activity time series is calculated as the edges of the brain network of interest, which are weighted and undirected.…”

Section: Edges Based On Functionalmentioning

confidence: 99%

“…The signals recorded by EEG and MEG directly reflect current flows generated by neurons within a brain. EEG/MEG also have been utilized for the studies of brain disorders [33][34][35][36]. Network-based analysis has been widely used in various fields, such as medical image analysis [37][38][39][40] and bioinformatics [41][42][43][44].…”

Section: Introductionmentioning

confidence: 99%

Complex Brain Network Analysis and Its Applications to Brain Disorders: A Survey

et al. 2017

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It is well known that most brain disorders are complex diseases, such as Alzheimer's disease (AD) and schizophrenia (SCZ). In general, brain regions and their interactions can be modeled as complex brain network, which describe highly efficient information transmission in a brain. Therefore, complex brain network analysis plays an important role in the study of complex brain diseases. With the development of noninvasive neuroimaging and electrophysiological techniques, experimental data can be produced for constructing complex brain networks. In recent years, researchers have found that brain networks constructed by using neuroimaging data and electrophysiological data have many important topological properties, such as small-world property, modularity, and rich club. More importantly, many brain disorders have been found to be associated with the abnormal topological structures of brain networks. These findings provide not only a new perspective to explore the pathological mechanisms of brain disorders, but also guidance for early diagnosis and treatment of brain disorders. The purpose of this survey is to provide a comprehensive overview for complex brain network analysis and its applications to brain disorders.

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“…Interestingly, the resting state functional network of AD patients shows a decrease of the clustering coefficient that is associated to an evolution towards a random topology as a consequence of the deterioration of the local synchrony [Supekar et al (2008)]. The increase of randomness, together with a loss of the network modularity, is also reported in mild cognitive impairment [Buldu et al (2011)], a disease with a high rate of conversion into AD. In the case of schizophrenia, similar studies have detected an abnormal configuration of the anatomical network, consisting on a reduction of the hierarchical structure of the network, an enhance of the mean shortest path and a loss of frontal hubs [Basset et al (2008)].…”

Section: From a Healthy To An Impaired Brainmentioning

confidence: 99%

Functional Brain Networks: beyond the small-world paradigm

Buldú

Papo

Pineda

et al. 2012

IFAC Proceedings Volumes

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This contribution reviews the current state of art comprising the application of Complex Networks Theory to the analysis of functional brain networks. We briefly overview the main advances in this field during the last decade and we explain how graph analysis has increased our knowledge about how the brain behaves when performing a specific task or how it fails when a certain pathology arises. We also show the limitations of this kind of analysis, which have been a source of confusion and misunderstanding when interpreting the results obtained. Finally, we discuss about a possible direction to follow in the next years.

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Reorganization of Functional Networks in Mild Cognitive Impairment

Cited by 128 publications

References 39 publications

Synchronization during an internally directed cognitive state in healthy aging and mild cognitive impairment: a MEG study

Synchronization during an internally directed cognitive state in healthy aging and mild cognitive impairment: a MEG study

Complex Brain Network Analysis and Its Applications to Brain Disorders: A Survey

Functional Brain Networks: beyond the small-world paradigm

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