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RESEARCH PRODUCT
Plasticity of brain wave network interactions and evolution across physiologic states
Kang K. L. LiuKang K. L. LiuRonny P. BartschPlamen Ch. IvanovPlamen Ch. IvanovPlamen Ch. IvanovRosario N. MantegnaRosario N. MantegnaAijing LinAijing Linsubject
AdultMaleNerve netCognitive NeuroscienceNeuroscience (miscellaneous)Sensory systemPlasticityCognitive neurosciencelcsh:RC321-571Young AdultCellular and Molecular NeuroscienceNeuroplasticitymedicineHumanslcsh:Neurosciences. Biological psychiatry. NeuropsychiatryOriginal ResearchSlow-wave sleepCerebral CortexNetwork physiologySleep StagesNeuronal PlasticityBrain WaveBrain wave interactions; Network physiology; Neural plasticity; Sleep; Time delay stability; Adult; Brain Waves; Cerebral Cortex; Female; Humans; Male; Nerve Net; Neuronal Plasticity; Sleep; Young Adult; Neuroscience (miscellaneous); Cellular and Molecular Neuroscience; Sensory Systems; Cognitive NeuroscienceNetwork dynamicsBrain WavesSettore FIS/07 - Fisica Applicata(Beni Culturali Ambientali Biol.e Medicin)Sensory Systemsbrain wave interactionsmedicine.anatomical_structureBrain wave interactionFemaletime delay stabilityNerve NetSensory SystemPsychologySleepNeuroscienceHumanNeuroscienceneural plasticitydescription
Neural plasticity transcends a range of spatio-temporal scales and serves as the basis of various brain activities and physiologic functions. At the microscopic level, it enables the emergence of brain waves with complex temporal dynamics. At the macroscopic level, presence and dominance of specific brain waves is associated with important brain functions. The role of neural plasticity at different levels in generating distinct brain rhythms and how brain rhythms communicate with each other across brain areas to generate physiologic states and functions remains not understood. Here we perform an empirical exploration of neural plasticity at the level of brain wave network interactions representing dynamical communications within and between different brain areas in the frequency domain. We introduce the concept of time delay stability (TDS) to quantify coordinated bursts in the activity of brain waves, and we employ a system-wide Network Physiology integrative approach to probe the network of coordinated brain wave activations and its evolution across physiologic states. We find an association between network structure and physiologic states. We uncover a hierarchical reorganization in the brain wave networks in response to changes in physiologic state, indicating new aspects of neural plasticity at the integrated level. Globally, we find that the entire brain network undergoes a pronounced transition from low connectivity in Deep Sleep and REM to high connectivity in Light Sleep and Wake. In contrast, we find that locally, different brain areas exhibit different network dynamics of brain wave interactions to achieve differentiation in function during different sleep stages. Moreover, our analyses indicate that plasticity also emerges in frequency-specific networks, which represent interactions across brain locations mediated through a specific frequency band. Comparing frequency-specific networks within the same physiologic state we find very different degree of network connectivity and link strength, while at the same time each frequency-specific network is characterized by a different signature pattern of sleep-stage stratification, reflecting a remarkable flexibility in response to change in physiologic state. These new aspects of neural plasticity demonstrate that in addition to dominant brain waves, the network of brain wave interactions is a previously unrecognized hallmark of physiologic state and function.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2015-10-26 | Frontiers in Neural Circuits |