Theoretical electroencephalogram stationary spectrum for a white-noise-driven cortex: evidence for a general anesthetic-induced phase transition. - Wikidata - awgldk - TriplyDB

Theoretical electroencephalogram stationary spectrum for a white-noise-driven cortex: evidence for a general anesthetic-induced phase transition.

Theoretical electroencephalogram stationary spectrum for a white-noise-driven cortex: evidence for a general anesthetic-induced phase transition.

http://www.wikidata.org/entity/Q48624327

about

Ongoing spontaneous activity controls access to consciousness: a neuronal model for inattentional blindness Nonlinear analysis of EEG signals at different mental states Dynamic causal models and physiological inference: a validation study using isoflurane anaesthesia in rodents A Pharmacokinetics-Neural Mass Model (PK-NMM) for the Simulation of EEG Activity during Propofol Anesthesia Theoretical predictions for spatial covariance of the electroencephalographic signal during the anesthetic-induced phase transition: Increased correlation length and emergence of spatial self-organization.Fractional Diffusion Based Modelling and Prediction of Human Brain Response to External Stimuli.Neural masses and fields in dynamic causal modeling.Anesthetic action on extra-synaptic receptors: effects in neural population models of EEG activity.Axonal velocity distributions in neural field equations.Effects of the anesthetic agent propofol on neural populations.Relationship of Topology, Multiscale Phase Synchronization, and State Transitions in Human Brain Networks A model of feedback control for the charge-balanced suppression of epileptic seizures.Emergence from general anesthesia and the sleep-manifold.Spin-glass model predicts metastable brain states that diminish in anesthesia.A continuous mapping of sleep states through association of EEG with a mesoscale cortical model Pathological pattern formation and cortical propagation of epileptic seizures.Integrating neuroinformatics tools in TheVirtualBrain.A Mechanistic Neural Field Theory of How Anesthesia Suppresses Consciousness: Synaptic Drive Dynamics, Bifurcations, Attractors, and Partial State Equipartitioning.The sleep cycle modelled as a cortical phase transition.Anesthetic action on the transmission delay between cortex and thalamus explains the beta-buzz observed under propofol anesthesia Functional and Topological Conditions for Explosive Synchronization Develop in Human Brain Networks with the Onset of Anesthetic-Induced Unconsciousness.Extensions to a manifold learning framework for time-series analysis on dynamic manifolds in bioelectric signals Computational modeling of epilepsy for an experimental neurologist.The electrocortical effects of enflurane: experiment and theory.Calcium dependent plasticity applied to repetitive transcranial magnetic stimulation with a neural field model.Noise-induced precursors of state transitions in the stochastic Wilson-cowan model.Comparison of spectral analysis methods for characterizing brain oscillations.Modeling the effects of anesthesia on the electroencephalogram.Emergence of spatially heterogeneous burst suppression in a neural field model of electrocortical activity.Metastability of Neuronal Dynamics during General Anesthesia: Time for a Change in Our Assumptions?The anesthetic propofol shifts the frequency of maximum spectral power in EEG during general anesthesia: analytical insights from a linear model.Pattern recognition of spectral entropy features for detection of alcoholic and control visual ERP's in multichannel EEGs.The population firing rate in the presence of GABAergic tonic inhibition in single neurons and application to general anaesthesia.Gap junctions modulate seizures in a mean-field model of general anesthesia for the cortex.EEG generator--a model of potentials in a volume conductor.Critical role for resource constraints in neural models.A neural mass model of spectral responses in electrophysiology.Anesthetic-induced transitions by propofol modeled by nonlocal neural populations involving two neuron types.Population based models of cortical drug response: insights from anaesthesia.A probabilistic framework for a physiological representation of dynamically evolving sleep state.

P2860

Q21146362-4D638A73-0B00-4890-8E61-A2DC043D1AA5 Q24792733-7D0A6191-69E4-4497-9D8A-8D5C599F5D49 Q28476412-ECDEC4E7-3165-4AF5-9909-60D7D3BA7D14 Q28551917-68834CD5-40BE-4C74-A955-71526CDA3323 Q30336136-C05B00AD-AEDA-45B6-AE31-AD48CB228CA3 Q30408979-C60715C3-CF84-4032-BE88-3AB3BB9F10A0 Q30453655-5A7B7A36-A2AB-4A12-8F31-59194D802F7B Q30606986-DF9B33F7-1781-469B-A078-01FAD6DEAF16 Q33529038-E722CD31-5730-49D1-9457-8CD74EB8D60B Q33723470-18DE7F9C-9A68-4810-819D-B8CD975C5CA0 Q33858193-B67DEE37-2B0A-4FE1-A35D-EF9AEC059A6A Q33894002-FC7EA5EE-993B-4854-B7CD-3C8E03713013 Q34040048-DDF54BF7-045A-48E0-99FB-01D884794257 Q34677407-B300B791-02B8-417C-9C5F-FC41C004253B Q34680288-9D6A181F-36BE-4DA3-8367-C78ED166D156 Q35051764-3C442E7D-7F80-4A90-91BC-C5868CE1DFCB Q35162797-AAC131FC-F728-480F-90F1-99B067D5B6FE Q36123363-D6AA75F5-F4A3-4C4F-B0C0-48F982F694C3 Q36273781-274A021D-7EA2-4720-AF49-8F3F560D9740 Q36407393-72D4C4B7-E37D-4553-9BFB-41BEDA96C29B Q36484808-FE0EBED5-CED4-4934-99B9-A9B8625B2FC8 Q36899888-ABE00DED-FF3F-4D02-A406-A4A99F3220DF Q37160650-B6135739-4353-4CFE-BBB4-9A4CAFAF29BE Q37353960-898D27FB-B751-4FE2-A439-30451545274C Q38858459-41480F6F-E245-40B5-BC06-7B9162346B32 Q39333053-21D1DBF7-6445-43B8-82AD-CC5C7B4C492F Q39645054-0BFA8866-F612-4911-AED2-F137DFF28D82 Q40421328-6FD28B14-4850-486C-8DE3-868C663A5821 Q41231137-E163ABF0-0C3E-466B-988C-8C7D992B80B8 Q41547248-383ADC7A-64AE-4BA5-AAB5-73AB8D2F78E9 Q41762534-A1EC7402-5EE9-4CC7-9942-5D3FAC7A1F53 Q41980521-6E626E27-5838-4528-9449-33D3BE9D0655 Q42184644-CFA00863-5B8B-4D17-829D-723B76D2D6D2 Q42184649-76299FE2-345C-4413-AE62-E8E1D0B15D0A Q42459057-C232762A-9EE5-4A3B-A24E-0D196570B1B5 Q42876030-767F6179-B2FA-4FE3-A464-89E87116037D Q43179082-5A8379C4-A220-4BBF-8FF1-0C7542CC1657 Q43240948-323031F6-2094-4AFE-B058-87274DEA460B Q43240958-6A571A52-87EA-49BC-9E03-3FFCFCE6E106 Q43867915-92E2F157-DB51-4F85-AF79-96E2BAA32686

P2860

Theoretical electroencephalogram stationary spectrum for a white-noise-driven cortex: evidence for a general anesthetic-induced phase transition.

http://www.wikidata.org/entity/Q48624327

description

1999 nî lūn-bûn

@nan

1999年の論文

@ja

1999年学术文章

@wuu

1999年学术文章

@zh

1999年学术文章

@zh-cn

1999年学术文章

@zh-hans

1999年学术文章

@zh-my

1999年学术文章

@zh-sg

1999年學術文章

@yue

1999年學術文章

@zh-hant

name

Theoretical electroencephalogr ...... etic-induced phase transition.

@en

Theoretical electroencephalogr ...... etic-induced phase transition.

@nl

type

label

Theoretical electroencephalogr ...... etic-induced phase transition.

@en

Theoretical electroencephalogr ...... etic-induced phase transition.

@nl

prefLabel

Theoretical electroencephalogr ...... etic-induced phase transition.

@en

Theoretical electroencephalogr ...... etic-induced phase transition.

@nl

P1433

Q48624327-83B3DCC3-B12D-4ECE-BD29-157018929D61

P1476

Q48624327-571AF91B-31CC-4D66-BB47-7A4F4AB1E33A

P2093

Q48624327-1FE2735D-22C6-4803-8A53-A2143183523A

Q48624327-28E5EDB2-C32A-4430-8C21-DB7E10BE2BC6

Q48624327-8F98EEA3-34C3-4C0B-89BD-4EA33421E1BD

Q48624327-E67848F4-CEB3-4B36-890A-7350D8A7ACB5

P2860

Q48624327-02BF7DB6-172C-4EE7-B398-2E3AF3F4AEE0

Q48624327-05525EF0-7BAF-4962-8F31-7B91AC0B45AB

Q48624327-156DA314-2591-4DF9-930C-A02EC4CB6F89

Q48624327-222A0959-EB4C-471D-B86A-D8C6BBA40B0B

Q48624327-23B2AF97-AC82-40E8-91D1-7376BB312F17

Q48624327-2BF1DBF9-0AAA-42DF-A21E-6FE33D93DB39

Q48624327-63CC1913-178F-4D1A-BF57-9357D71DD5A8

Q48624327-8039641F-65CD-496B-9027-493511488BB0

Q48624327-81119ADE-6AB1-40E9-BF80-79494BE2F4A3

Q48624327-8E404E2B-65EB-40EC-9790-1D8181FD4FDD

P304

Q48624327-71CB4642-F033-491A-9021-8A771653E83A

P31

Q48624327-3D0C6170-D1DF-42F1-B7FA-70D359010FB9

P356

Q48624327-F01FED33-59DF-43A5-A340-069BDC787B41

P407

Q48624327-BE529D86-815E-48A1-AB47-D8B2A0403F4B

P433

Q48624327-DD0460DC-3FCF-4EFE-886E-6C17CD8C78D3

P478

Q48624327-9AABE350-0D2E-4B86-A6BF-427C7944A172

P577

Q48624327-C0C1C33A-FFEA-4A92-817E-7253BC23F741

P698

Q48624327-DA10BDD5-D845-496F-A4D6-328C416AF365

P356

PHYSREVE.60.7299

P1433

Physical Review E

P1476

Theoretical electroencephalogr ...... etic-induced phase transition.

@en

P2093

Liley DT

http://www.w3.org/2001/XMLSchema#string

Sleigh JW

http://www.w3.org/2001/XMLSchema#string

Steyn-Ross DA

http://www.w3.org/2001/XMLSchema#string

Steyn-Ross ML

http://www.w3.org/2001/XMLSchema#string

P2860

A mathematical theory of the functional dynamics of cortical and thalamic nervous tissue.

Convulsant potencies of tetrazoles are highly correlated with actions on GABA/benzodiazepine/picrotoxin receptor complexes in brain.

Molecular and cellular mechanisms of general anaesthesia.

A brief history of time (constants).

Excitatory and inhibitory interactions in localized populations of model neurons.

Thiopental uncouples hippocampal and cortical synchronized electroencephalographic activity.

Isoflurane hyperpolarizes neurones in rat and human cerebral cortex.

Effects of small concentrations of volatile anesthetics on action potential firing of neocortical neurons in vitro.

Pharmacodynamics of thiopentone: nocifensive reflex threshold changes correlate with hippocampal electroencephalography.

Cellular mechanisms of gamma rhythms in rat neocortical brain slices probed by the volatile anaesthetic isoflurane.

P304

7299-7311

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1103/PHYSREVE.60.7299

http://www.w3.org/2001/XMLSchema#string

P407

P433

6 Pt B

http://www.w3.org/2001/XMLSchema#string

P478

60

http://www.w3.org/2001/XMLSchema#string

P577

1999-12-01T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P698

11970675

http://www.w3.org/2001/XMLSchema#string