Abstract
The default mode network (DMN) is a complex dynamic network that is critical for understanding cognitive function. However, whether dynamic topological reconfiguration of the DMN occurs across different brain states, and whether this potential reorganization is associated with prior learning or experience is unclear. To better understand the temporally changing topology of the DMN, we investigated both nodal and global dynamic DMN-topology metrics across different brain states. We found that DMN topology changes over time and those different patterns are associated with different brain states. Further, the nodal and global topological organization can be rebuilt by different brain states. These results indicate that the post-task, resting-state topology of the brain network is dynamically altered as a function of immediately prior cognitive experience, and that these modulated networks are assembled in the subsequent state. Together, these findings suggest that the changing topology of the DMN may play an important role in characterizing brain states.
Highlights
The default mode network (DMN) is a complex dynamic network that is critical for understanding cognitive function
The DMN can be viewed as being composed of sub-networks[60], including the medial temporal sub-network associated with memory-related nodes and another sub-network associated with the posterior cingulate cortex (PCC)
We investigated the structure of DMN topology across different brain states
Summary
The default mode network (DMN) is a complex dynamic network that is critical for understanding cognitive function. Modulation of learning-dependent spontaneous brain activity has been observed after people perform cognitive tasks involving working memory, emotion, visual perception, and motor training[44,45,47,48,49,50] Such modulation of brain regions associated with a prior task can be understood as reflecting the gradual establishment, or reinforcement, of recent experiences in the offline resting state. Some studies have indicated that the spatial distribution of the DMN appears to persist unchanged across active and resting states, suggesting that the DMN reflects stable properties of brain-network architecture This question cannot be fully answered without knowing how dynamic DMN connectivity changes across different brain states. Characterization of this dynamic DMN activity is critical for understanding brain functional stability and flexibility
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