Disruption of frontal-parietal communication by ketamine, propofol, and sevoflurane.
about
Inferring the Dysconnection Syndrome in Schizophrenia: Interpretational Considerations on Methods for the Network Analyses of fMRI DataClinical Electroencephalography for Anesthesiologists: Part I: Background and Basic SignaturesModeling the dynamical effects of anesthesia on brain circuitsTop-down mechanisms of anesthetic-induced unconsciousnessNeurophysiological correlates of sevoflurane-induced unconsciousness.Common Internal Allosteric Network Links Anesthetic Binding Sites in a Pentameric Ligand-Gated Ion ChannelKetamine: 50 Years of Modulating the MindElectroencephalographic variation during end maintenance and emergence from surgical anesthesiaBrain Connectivity Dissociates Responsiveness from Drug Exposure during Propofol-Induced Transitions of ConsciousnessArousal transitions in sleep, wakefulness, and anesthesia are characterized by an orderly sequence of cortical eventsAwake vs. anesthetized: layer-specific sensory processing in visual cortex and functional connectivity between cortical areas.Acute Sleep Deprivation Induces a Local Brain Transfer Information Increase in the Frontal Cortex in a Widespread Decrease Context.Preferential effect of isoflurane on top-down vs. bottom-up pathways in sensory cortex.Large scale screening of neural signatures of consciousness in patients in a vegetative or minimally conscious state.Brain Mechanisms during Course of Anesthesia: What We Know from EEG Changes during Induction and Recovery.Lack of Responsiveness during the Onset and Offset of Sevoflurane Anesthesia Is Associated with Decreased Awake-Alpha Oscillation Power.Breakdown of local information processing may underlie isoflurane anesthesia effectsProtocol for the Reconstructing Consciousness and Cognition (ReCCognition) Study.Propofol, Sevoflurane, and Ketamine Induce a Reversible Increase in Delta-Gamma and Theta-Gamma Phase-Amplitude Coupling in Frontal Cortex of Rat.Bottom-Up and Top-Down Mechanisms of General Anesthetics Modulate Different Dimensions of Consciousness.Relationship of Topology, Multiscale Phase Synchronization, and State Transitions in Human Brain NetworksDistinctive recruitment of endogenous sleep-promoting neurons by volatile anesthetics and a nonimmobilizer.Effects of sevoflurane and propofol on frontal electroencephalogram power and coherence.Assessing directionality and strength of coupling through symbolic analysis: an application to epilepsy patients.Dynamic repertoire of intrinsic brain states is reduced in propofol-induced unconsciousness.General relationship of global topology, local dynamics, and directionality in large-scale brain networks.Electroencephalographic coherence and cortical acetylcholine during ketamine-induced unconsciousness.Prospective Pilot Investigation: Presurgical Depressive Symptom Severity and Anesthesia Response in Women Undergoing Surgery for Gynecologic Mass Removal.Age-dependency of sevoflurane-induced electroencephalogram dynamics in children.Resting-state Functional Magnetic Resonance Imaging Correlates of Sevoflurane-induced Unconsciousness.Evidence that Subanesthetic Doses of Ketamine Cause Sustained Disruptions of NMDA and AMPA-Mediated Frontoparietal Connectivity in HumansLow-dose sevoflurane promotes hippocampal neurogenesis and facilitates the development of dentate gyrus-dependent learning in neonatal rats.Functional and Topological Conditions for Explosive Synchronization Develop in Human Brain Networks with the Onset of Anesthetic-Induced Unconsciousness.Alerting thresholds for the prevention of intraoperative awareness with explicit recall: a secondary analysis of the Michigan Awareness Control StudyOrthopedic Surgery and Post-Operative Cognitive Decline in Idiopathic Parkinson's Disease: Considerations from a Pilot Study.Electroencephalogram signatures of ketamine anesthesia-induced unconsciousness.Anesthetic Suppression of Thalamic High-Frequency Oscillations: Evidence that the Thalamus Is More Than Just a Gateway to Consciousness?Disruption of corticocortical information transfer during ketamine anesthesia in the primate brainLocal Versus Global Effects of Isoflurane Anesthesia on Visual Processing in the Fly Brain.Consciousness and the 21st century operating room.
P2860
Q26740618-B8C487C9-0578-4E70-A86F-A067B35E00BEQ26798123-D184567D-D722-4559-9DF2-C09204525166Q26824341-DED18DC5-50FB-4A5C-909B-53CFE6B50F69Q27007480-FD9207B6-ED14-4154-971C-5EFF0B1C325DQ27318425-F8337BD6-DADB-43B8-B98F-180767392E32Q27335033-B4A759DA-7163-4396-9881-705E58A3C4DCQ28077524-65CF5E38-9C7C-42A7-8474-77116D9EC964Q28543357-590CC823-3DAB-41D3-83A2-62B9D0C82DBCQ28552461-1F2AB3AB-6793-4A2E-9539-3FE2E6905EFCQ28648447-3CB3F554-A598-4C02-9D3F-F442BCD19DA6Q30382442-98FEE9B9-E314-48DA-AF86-0102D73751CEQ30384288-411F1C66-1527-4FB5-A5DE-25D304974D10Q30427982-25EB75AB-3501-4CF6-BCE1-341E6D908667Q30669116-308B074D-CD7B-4C98-BCFC-14D72098D365Q33734582-1E08698C-EEA3-4B70-AC69-F1696F6BA3C5Q33736474-C6285299-B84E-4621-B013-647F69757487Q33751599-A6AE271F-9DAC-4361-95C9-66CFF198A990Q33770143-4F353479-0889-4EC6-A4F4-5D5EEA451E16Q33790034-93155268-5076-49F5-9ECA-2E8982C258D6Q33813042-EAE9D0B3-EEF1-4D8A-A702-ADAF65AE83B6Q33858193-E72069AE-A20A-426C-A4AB-7E8D5FFBF7CEQ34389010-9D812C40-C734-43E6-AFBE-597CDACBE9ECQ34389233-EFEF68A5-BDBE-4FD5-B92C-3F0CC2055C2CQ34802692-F975079A-7A28-4802-9C6C-E0C9B2A0D11CQ35036582-5BABE8A9-0662-4CDA-944D-90EB7E73C7E9Q35417040-A2DBDEAA-C417-4DCD-A5BC-1FC7EEC40CF5Q35622231-3358D168-1C40-46EE-8D9F-5B055FC64881Q35642447-C0E402F4-8F3A-4DAE-B5C2-0F6EBE5F059CQ35850632-5A78EA03-4DC1-4D8C-9F0B-5FA82DF33B81Q35875963-80A76092-D2BC-49D7-A18B-22CF68A27ACFQ35968145-AD217D41-5D98-42C2-8CD6-FCB18AC3706FQ36482811-EB600792-61D7-47C0-BB64-ECBF744A0824Q36484808-E66E40C6-C783-489B-8F3F-4B8872A8CDE2Q36533661-6EA9E285-5B8A-409D-870C-516E5D6C44BEQ36736147-AD4EF056-3438-4455-80D0-3FFB8E9CA75FQ36913201-B1EB5561-41E1-47AC-A9B5-D77570876C3FQ36921269-0BEEB159-E373-4CF1-9D6E-35F3CB9AF9EDQ37018343-6F3BAFAA-A01B-4AA5-AF34-FF5E6EC81D58Q37141003-58A32513-E8B6-4614-92F6-E6CD06BD110AQ37297181-51B472C9-FC4F-4DE4-9A20-6E7AAB0539E8
P2860
Disruption of frontal-parietal communication by ketamine, propofol, and sevoflurane.
description
2013 nî lūn-bûn
@nan
2013 թուականի Յունիսին հրատարակուած գիտական յօդուած
@hyw
2013 թվականի հունիսին հրատարակված գիտական հոդված
@hy
2013年の論文
@ja
2013年論文
@yue
2013年論文
@zh-hant
2013年論文
@zh-hk
2013年論文
@zh-mo
2013年論文
@zh-tw
2013年论文
@wuu
name
Disruption of frontal-parietal communication by ketamine, propofol, and sevoflurane.
@ast
Disruption of frontal-parietal communication by ketamine, propofol, and sevoflurane.
@en
type
label
Disruption of frontal-parietal communication by ketamine, propofol, and sevoflurane.
@ast
Disruption of frontal-parietal communication by ketamine, propofol, and sevoflurane.
@en
prefLabel
Disruption of frontal-parietal communication by ketamine, propofol, and sevoflurane.
@ast
Disruption of frontal-parietal communication by ketamine, propofol, and sevoflurane.
@en
P2093
P2860
P1433
P1476
Disruption of frontal-parietal communication by ketamine, propofol, and sevoflurane.
@en
P2093
ByungMoon Choi
George A Mashour
GyuJeong Noh
SeungHye Baek
SeungWoo Ku
UnCheol Lee
P2860
P304
P356
10.1097/ALN.0B013E31829103F5
P407
P577
2013-06-01T00:00:00Z