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Cognitive Neurodynamics

15.03.2024 | Research Article

High-altitude exposure leads to increased modularity of brain functional network with the increased occupation of attention resources in early processing of visual working memory

verfasst von: Jing Zhou, Nian-Nian Wang, Xiao-Yan Huang, Rui Su, Hao Li, Hai-Lin Ma, Ming Liu, De-Long Zhang

Erschienen in: Cognitive Neurodynamics

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Abstract

Working memory is a complex cognitive system that temporarily maintains purpose-relevant information during human cognition performance. Working memory performance has also been found to be sensitive to high-altitude exposure. This study used a multilevel change detection task combined with Electroencephalogram data to explore the mechanism of working memory change from high-altitude exposure. When compared with the sea-level population, the performance of the change detection task with 5 memory load levels was measured in the Han population living in high-altitude areas, using the event-related potential analysis and task-related connectivity network analysis. The topological analysis of the brain functional network showed that the normalized modularity of the high-altitude group was higher in the memory maintenance phase. Event-related Potential analysis showed that the peak latencies of P1 and N1 components of the high-altitude group were significantly shorter in the occipital region, which represents a greater attentional bias in visual early processing. Under the condition of high memory loads, the high-altitude group had a larger negative peak in N2 amplitude compared to the low-altitude group, which may imply more conscious processing in visual working memory. The above results revealed that the visual working memory change from high-altitude exposure might be derived from the attentional bias and the more conscious processing in the early processing stage of visual input, which is accompanied by the increase of the modularity of the brain functional network. This may imply that the attentional bias in the early processing stages have been influenced by the increased modularity of the functional brain networks induced by high-altitude exposure.

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Titel: High-altitude exposure leads to increased modularity of brain functional network with the increased occupation of attention resources in early processing of visual working memory
verfasst von: Jing Zhou
Nian-Nian Wang
Xiao-Yan Huang
Rui Su
Hao Li
Hai-Lin Ma
Ming Liu
De-Long Zhang
Publikationsdatum: 15.03.2024
Verlag: Springer Netherlands
Erschienen in: Cognitive Neurodynamics
Print ISSN: 1871-4080
Elektronische ISSN: 1871-4099
DOI: https://doi.org/10.1007/s11571-024-10091-3

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