Dynamic Configuration of Coactive Micropatterns in the Default Mode Network during Wakefulness and Sleep

Cui, Yan; Li, Min; Biswal, Bharat B.; Wei, Jing; Zhou, Changsong; Liu, Huixiao; Guo, Daqing; Yang, Xiaobo; Yao, Dezhong

doi:10.1101/2020.07.29.226647

Cited by 2 publications

(2 citation statements)

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“…Accordingly, we recorded the local field potentials (LFPs) from the rat DMN during wakefulness and sleep. To derive the FC networks from rat DMN dynamics, we proposed a novel coactive micropattern network (CAMP network) method to construct the FCs among DMN regions based on the coactive micropatterns (CAMPs) from DMN dynamics described in our previous work [29]. Our results illustrated more robust functional structures of the CAMP networks than the original DMN structure, and different CAMP networks played distinct roles in specific levels of consciousness.…”

Section: Introductionmentioning

confidence: 77%

“…Electrophysiological gamma activity is believed to be strongly correlated with the blood oxygen level-dependent (BOLD) signals, and the deactivation of gamma activity in DMN regions has been observed during external tasks. The description of the CAMP algorithm as well as its functional roles in different conscious states during the sleep-wake sleep has been systematically presented in our prior work [29]. Briefly, the original DMN activity was bandpass filtered into gamma oscillation, and the Hilbert transform was then applied to obtain the envelope activity of gamma oscillation.…”

Section: Experiments and Datamentioning

confidence: 99%

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Altered Coactive Micropattern Connectivity in the Default-Mode Network during the Sleep-Wake Cycle

et al. 2020

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The default-mode network (DMN) is believed to be associated with levels of consciousness, but how the functional connectivity (FC) of the DMN changes across different states of consciousness is still unclear. In the current work, we addressed this issue by exploring the coactive micropattern (CAMP) networks of the DMN according to the CAMPs of rat DMN activity during the sleep-wake cycle and tracking their topological alterations among different states of consciousness. Three CAMP networks were observed in DMN activity, and they displayed greater FC and higher efficiency than the original DMN structure in all states of consciousness, implying more efficient information processing in the CAMP networks. Furthermore, no significant differences in FC or network properties were found among the three CAMP networks in the waking state. However, the three networks were distinct in their characteristics in two sleep states, indicating that different CAMP networks played specific roles in distinct sleep states. In addition, we found that the changes in the FC and network properties of the CAMP networks were similar to those in the original DMN structure, suggesting intrinsic effects of various states of consciousness on DMN dynamics. Our findings revealed three underlying CAMP networks within the DMN dynamics and deepened the current knowledge concerning FC alterations in the DMN during conscious changes in the sleep-wake cycle.

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Section: Introductionmentioning

confidence: 77%

Section: Experiments and Datamentioning

confidence: 99%

Altered Coactive Micropattern Connectivity in the Default-Mode Network during the Sleep-Wake Cycle

et al. 2020

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Flexible Brain Transitions Between Hierarchical Network Segregation and Integration Predict Human Behavior

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Chang

et al. 2020

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Cognition involves locally segregated and globally integrated processing. This process is hierarchically organized, linking to evidence from hierarchical modules in brain networks. However, it remains a mystery how flexible transitions between these hierarchical processes are associated with human behavior. Here, we used a multisource interference task and measured hierarchical segregation and integration across multiple levels. Our results show more flexible transitions between segregated and integrated brain states in the task state. Crucially, brain flexibility in resting and task states was associated with human behavior. To achieve a better performance, the resting brain is optimized to be more flexible, such that it is prepared to more efficiently switch into a task state where the brain needs less flexibility to stably perform the task. Our hierarchical modular analysis was more effective in detecting the alterations in functional organization and the phenotype of human behavior than graph-based network measures at a single level.

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Dynamic Configuration of Coactive Micropatterns in the Default Mode Network during Wakefulness and Sleep

Cited by 2 publications

References 65 publications

Altered Coactive Micropattern Connectivity in the Default-Mode Network during the Sleep-Wake Cycle

Altered Coactive Micropattern Connectivity in the Default-Mode Network during the Sleep-Wake Cycle

Flexible Brain Transitions Between Hierarchical Network Segregation and Integration Predict Human Behavior

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