Cognitive Load Driven Directed Information Flow in Functional Brain Networks

Shovon, Md Hedayetul Islam; Nandagopal, D (Nanda); Vijayalakshmi, Ramasamy; Du, Jia Tina; Cocks, Bernadine

doi:10.1007/978-3-319-26561-2_40

Author(s)

Shovon, Md Hedayetul Islam

Nandagopal, D (Nanda)

Vijayalakshmi, Ramasamy

Du, Jia Tina

Cocks, Bernadine

Publication Date

2015-11-18

Abstract

<p>The human brain connectome analysis describes the patterns of structural and functional brain networks and has become one of the most studied topics in computational neuroscience in recent years. Detailed investigation of functional brain networks based on the direction of information flow has subsequently gained significance. This study identifies changes in information flow direction between different brain regions during cognitive activity compared to baseline state using Normalized Transfer Entropy (NTE) estimated from electroencephalogram (EEG) signals. An algorithm is proposed for finding the cognitive state specific information flow direction patterns (IFDP) among various regions (lobes) of the brain. Results clearly demonstrate that IFDP based analysis is able to detect the changing information flow directional patterns during cognitive activity among four different brain regions: Frontal, Central, Parietal and Occipital. During cognitive activity, noticeable long range interconnections are established in the directed functional brain network from frontal to central, parietal and occipital lobes, and as well as from the central to occipital lobe. This suggests that the IFDP approach may have potential applications in the detection of cognitive impairments as well as in the clinical research e.g., for finding seizure foci in epilepsy.</p>

Citation

Neural Information Processing 22nd International Conference, ICONIP 2015, November 9-12, 2015, Proceedings, Part IV, p. 332–340, p. 332-340

Link

https://hdl.handle.net/1959.11/57053

Language

en

Publisher

Springer

Title

Cognitive Load Driven Directed Information Flow in Functional Brain Networks

Type of document

Conference Publication

Entity Type

Publication

Author(s)	Shovon, Md Hedayetul Islam Nandagopal, D (Nanda) Vijayalakshmi, Ramasamy Du, Jia Tina Cocks, Bernadine
Publication Date	2015-11-18
Abstract	<p>The human brain connectome analysis describes the patterns of structural and functional brain networks and has become one of the most studied topics in computational neuroscience in recent years. Detailed investigation of functional brain networks based on the direction of information flow has subsequently gained significance. This study identifies changes in information flow direction between different brain regions during cognitive activity compared to baseline state using Normalized Transfer Entropy (NTE) estimated from electroencephalogram (EEG) signals. An algorithm is proposed for finding the cognitive state specific information flow direction patterns (IFDP) among various regions (lobes) of the brain. Results clearly demonstrate that IFDP based analysis is able to detect the changing information flow directional patterns during cognitive activity among four different brain regions: Frontal, Central, Parietal and Occipital. During cognitive activity, noticeable long range interconnections are established in the directed functional brain network from frontal to central, parietal and occipital lobes, and as well as from the central to occipital lobe. This suggests that the IFDP approach may have potential applications in the detection of cognitive impairments as well as in the clinical research e.g., for finding seizure foci in epilepsy.</p>
Citation	Neural Information Processing 22nd International Conference, ICONIP 2015, November 9-12, 2015, Proceedings, Part IV, p. 332–340, p. 332-340
Link	https://hdl.handle.net/1959.11/57053
Language	en
Publisher	Springer
Title	Cognitive Load Driven Directed Information Flow in Functional Brain Networks
Type of document	Conference Publication
Entity Type	Publication

Cognitive Load Driven Directed Information Flow in Functional Brain Networks

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