Mohamad Khalil scite author profile

The human brain is an inherently complex and dynamic system. Even at rest, functional brain networks dynamically reconfigure in a well-organized way to warrant an efficient communication between brain regions. However, a precise characterization of this reconfiguration at very fast time-scale (hundreds of millisecond) during rest remains elusive. In this study, we used dense electroencephalography data recorded during task-free paradigm to track the fast temporal dynamics of spontaneous brain networks. Results obtained from network-based analysis methods revealed the existence of a functional dynamic core network formed of a set of key brain regions that ensure segregation and integration functions. Brain regions within this functional core share high betweenness centrality, strength and vulnerability (high impact on the network global efficiency) and low clustering coefficient. These regions are mainly located in the cingulate and the medial frontal cortex. In particular, most of the identified hubs were found to belong to the Default Mode Network. Results also revealed that the same central regions may dynamically alternate and play the role of either provincial (local) or connector (global) hubs.

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A new algorithm for spatiotemporal analysis of brain functional connectivity

Mheich

Hassan

Khalil

et al. 2015

Journal of Neuroscience Methods

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Specific networks of interacting neuronal assemblies distributed within and across distinct brain regions underlie brain functions. In most cognitive tasks, these interactions are dynamic and take place at the millisecond time scale. Among neuroimaging techniques, magneto/electroencephalography - M/EEG - allows for detection of very short-duration events and offers the single opportunity to follow, in time, the dynamic properties of cognitive processes (sub-millisecond temporal resolution). In this paper, we propose a new algorithm to track the functional brain connectivity dynamics. During a picture naming task, this algorithm aims at segmenting high-resolution EEG signals (hr-EEG) into functional connectivity microstates. The proposed algorithm is based on the K-means clustering of the connectivity graphs obtained from the phase locking value (PLV) method applied on hr-EEG. Results show that the analyzed evoked responses can be divided into six clusters representing distinct networks sequentially involved during the cognitive task, from the picture presentation and recognition to the motor response.

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Driver stress level detection using HRV analysis

et al. 2015

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Elder Tracking and Fall Detection System Using Smart Tiles

et al. 2017

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Reduced integration and improved segregation of functional brain networks in Alzheimer’s disease

Kabbara¹,

Eid²,

Falou³

et al. 2018

J. Neural Eng.

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Mohamad Khalil

The dynamic functional core network of the human brain at rest

A new algorithm for spatiotemporal analysis of brain functional connectivity

Driver stress level detection using HRV analysis

Elder Tracking and Fall Detection System Using Smart Tiles

Reduced integration and improved segregation of functional brain networks in Alzheimer’s disease

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