about
Transient neuronal coactivations embedded in globally propagating waves underlie resting-state functional connectivityBrain Genomics Superstruct Project initial data release with structural, functional, and behavioral measures.Human cortical-hippocampal dialogue in wake and slow-wave sleepHow networks communicate: propagation patterns in spontaneous brain activityTemporal dynamics in fMRI resting-state activityEstimation of Directed Effective Connectivity from fMRI Functional Connectivity Hints at Asymmetries of Cortical ConnectomePropagated infra-slow intrinsic brain activity reorganizes across wake and slow wave sleep.Frequency-phase analysis of resting-state functional MRI.Brain Rhythms of Pain.Modeling and interpreting mesoscale network dynamics.Initial Validation for the Estimation of Resting-State fMRI Effective Connectivity by a Generalization of the Correlation Approach.Towards a fourth spatial dimension of brain activityBold-Independent Computational Entropy Assesses Functional Donut-Like Structures in Brain fMRI Images.From connectome to cognition: The search for mechanism in human functional brain networks.Whole-brain analytic measures of network communication reveal increased structure-function correlation in right temporal lobe epilepsy.Resting-state fMRI in sleeping infants more closely resembles adult sleep than adult wakefulness.Beyond excitation/inhibition imbalance in multidimensional models of neural circuit changes in brain disorders.Functional connectivity structure of cortical calcium dynamics in anesthetized and awake mice.Detection of synchronous brain activity in white matter tracts at rest and under functional loading.Visual experience sculpts whole-cortex spontaneous infraslow activity patterns through an Arc-dependent mechanism.Identifying and characterizing systematic temporally-lagged BOLD artifacts.Time-Resolved Resting-State Functional Magnetic Resonance Imaging Analysis: Current Status, Challenges, and New Directions.On the Stability of BOLD fMRI Correlations.Principles of cross-network communication in human resting state fMRI.The Lag Structure of Intrinsic Activity is Focally Altered in High Functioning Adults with Autism.Neural and metabolic basis of dynamic resting state fMRI.Stomach-brain synchrony reveals a novel, delayed-connectivity resting-state network in humans.Temporal transitions of spontaneous brain activity.The Temporal Propagation of Intrinsic Brain Activity Associate With the Occurrence of PTSD.Modular co-organization of functional connectivity and scale-free dynamics in the human brain.Classification of Spatiotemporal Neural Activity Patterns in Brain Imaging Data.An Autonomic Network: Synchrony Between Slow Rhythms of Pulse and Brain Resting State Is Associated with Personality and EmotionsA multi-scale layer-resolved spiking network model of resting-state dynamics in macaque visual cortical areasCharacterizing directed functional pathways in the visual system by multivariate nonlinear coherence of fMRI data
P2860
Q27317143-CF91F285-A4C3-4547-B3BE-8FD7BC36FC56Q28647439-D2FA7426-DC0E-41B2-9302-3A80468FB6D2Q30827801-579B8D42-344C-489F-A0ED-B9D15B6F5744Q31125461-9DA75307-82E0-41F2-81A6-E158AA259EBEQ35567156-104F136F-B437-490A-830A-59D6771FFB13Q35959303-2B33CD2B-3BA1-4FEE-92B6-E433387D1E25Q36534000-DA91C320-84F1-4B94-B2D9-F3FCAAA85D53Q37685823-943BDF5F-FA4E-4892-A221-7E564A2C0E32Q37731135-2C3AB620-D105-443D-AC54-0248F08527CBQ38667383-70BFFC4F-C564-48E8-B74E-B91EF27086B2Q38755368-8E00DC8C-2F39-4EB8-8499-0EB12680A166Q38856446-24132094-5948-447A-8E43-60A012D826CEQ38959139-3D087843-9D2C-4A62-979F-8AB46A0F6165Q39107958-817F7108-6F4C-4E8E-9B47-FAA15835B408Q39664648-6BE367DD-C82A-4EC5-B0C4-F3DD04E35B0EQ44709442-3418038B-CD7F-4EB6-9FBE-EDFF65C76BB3Q46128640-642275C3-7B25-4C73-BE64-8A4610641652Q47135747-70830023-FAC5-4472-8653-2219626662C2Q47215479-8045B42B-ACE6-4FEE-A8F0-45EE80ECEDF5Q47395982-5E62B651-8904-48DC-9AD9-78B9AACA3CC4Q47668115-17979D22-FA3C-47F0-AD69-53F943CD7F93Q47713919-29BFE991-6722-491B-B451-8436CCAFA64DQ47819664-D9576DB5-53F3-43B9-8160-96EB34CC1D99Q47848115-47D6736B-35EF-4FA3-9462-4AA47CB38382Q49162553-8BF744F9-B205-422B-97B8-47C7C9B980A3Q50128472-2A8A23E7-3296-47B2-A256-2A32FF6CE346Q52645337-699DA723-4372-4907-9C3B-8226639BD071Q52666870-1A4D6A04-F358-468F-803C-D326EF1A82A1Q55035808-80B3F32A-B33C-4C18-A0A2-FF4FFC6EB42EQ55339651-34A8D0C1-F65A-497D-B623-928F0F79CE70Q55387776-6FF1906E-AB2D-46E8-9B89-A741B6671805Q57307747-9DF85E45-7154-4046-A8B0-8663F9973BB3Q58601368-AFAA21DA-84BE-4FE4-A093-7ABC83A4845DQ58612361-C857F112-5934-44C2-BA7F-A575754BFEE3
P2860
description
2015 nî lūn-bûn
@nan
2015年の論文
@ja
2015年論文
@yue
2015年論文
@zh-hant
2015年論文
@zh-hk
2015年論文
@zh-mo
2015年論文
@zh-tw
2015年论文
@wuu
2015年论文
@zh
2015年论文
@zh-cn
name
Lag threads organize the brain's intrinsic activity.
@ast
Lag threads organize the brain's intrinsic activity.
@en
type
label
Lag threads organize the brain's intrinsic activity.
@ast
Lag threads organize the brain's intrinsic activity.
@en
prefLabel
Lag threads organize the brain's intrinsic activity.
@ast
Lag threads organize the brain's intrinsic activity.
@en
P2860
P50
P356
P1476
Lag threads organize the brain's intrinsic activity.
@en
P2093
Tyler Blazey
P2860
P304
P356
10.1073/PNAS.1503960112
P407
P577
2015-03-30T00:00:00Z