The Syncytial Mesh Model proposes that astrocytic syncytial organization supplies a continuous mesoscale control field that shapes scale-dependent neuronal coherence and traveling-wave patterns beyond direct synaptic connectivity.
The human brain is intrinsically organized into dynamic, anticorrelated functional networks
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EEG measures of early cortical preconfiguration dynamics distinguish repetitive subconcussion patients from healthy controls and chronic TBI cases.
Bootstrapped multi-level analysis of functional connectivity data reveals reduced DMN connectivity, increased deactivation, and 13 significantly differing regions (mostly frontal) in schizophrenia versus controls.
citing papers explorer
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The Syncytial Mesh Model: A Mesoscale Control-Field Framework for Scale-Dependent Coherence in the Brain
The Syncytial Mesh Model proposes that astrocytic syncytial organization supplies a continuous mesoscale control field that shapes scale-dependent neuronal coherence and traveling-wave patterns beyond direct synaptic connectivity.
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Early Preconfiguration Failure: A Novel Predictor of the Repetitive Subconcussion
EEG measures of early cortical preconfiguration dynamics distinguish repetitive subconcussion patients from healthy controls and chronic TBI cases.
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Diffuse and Localized Functional Dysconnectivity in Schizophrenia: a Bootstrapped Top-Down Approach
Bootstrapped multi-level analysis of functional connectivity data reveals reduced DMN connectivity, increased deactivation, and 13 significantly differing regions (mostly frontal) in schizophrenia versus controls.