How does transcranial magnetic stimulation modify neuronal activity in the brain? Implications for studies of cognition - Wikidata - awgldk - TriplyDB

How does transcranial magnetic stimulation modify neuronal activity in the brain? Implications for studies of cognition

How does transcranial magnetic stimulation modify neuronal activity in the brain? Implications for studies of cognition

http://www.wikidata.org/entity/Q41193886

about

Adaptive Plasticity in the Healthy Language Network: Implications for Language Recovery after Stroke The impact of early visual cortex transcranial magnetic stimulation on visual working memory precision and guess rate.Mapping the after-effects of theta burst stimulation on the human auditory cortex with functional imaging.Attention fine-tunes auditory-motor processing of speech sounds.Short-term plasticity of visuo-haptic object recognition.Left dorsal premotor cortex and supramarginal gyrus complement each other during rapid action reprogramming.Auditory-motor processing of speech sounds.Using TMS to study the role of the articulatory motor system in speech perception.Repetitive TMS suggests a role of the human dorsal premotor cortex in action prediction.The right posterior inferior frontal gyrus contributes to phonological word decisions in the healthy brain: evidence from dual-site TMS Phonological decisions require both the left and right supramarginal gyri.What have We Learned from "Perturbing" the Human Cortical Motor System with Transcranial Magnetic Stimulation?Using transcranial magnetic stimulation of the undamaged brain to identify lesion sites that predict language outcome after stroke.Combining functional neuroimaging with off-line brain stimulation: modulation of task-related activity in language areas.The dorsomedial prefrontal cortex mediates the interaction between moral and aesthetic valuation: a TMS study on the beauty-is-good stereotype.Priming pharyngeal motor cortex by repeated paired associative stimulation: implications for dysphagia neurorehabilitation Modular processes in mind and brain.Stochastic resonance effects reveal the neural mechanisms of transcranial magnetic stimulation.Continuous theta-burst stimulation modulates tactile synchronization.TMS suppression of right pars triangularis, but not pars opercularis, improves naming in aphasia.Transcranial Magnetic Stimulation to Address Mild Cognitive Impairment in the Elderly: A Randomized Controlled Study.Single pulse TMS-induced modulations of resting brain neurodynamics encoded in EEG phase.Imaging the neural mechanisms of TMS neglect-like bias in healthy volunteers with the interleaved TMS/fMRI technique: preliminary evidence Triple-site rTMS for the treatment of chronic tinnitus: a randomized controlled trial Transcranial magnetic stimulation (TMS) inhibits cortical dendrites.Transcranial magnetic stimulation-electroencephalography responses in recovered and symptomatic mild traumatic brain injury.Neural pathways mediating cross education of motor function.Virtual lesion of angular gyrus disrupts the relationship between visuoproprioceptive weighting and realignment.Dopaminergic neurotransmission in the human brain: new lessons from perturbation and imaging.Behavioural facilitation following brain stimulation: implications for neurorehabilitation.Uncovering Multisensory Processing through Non-Invasive Brain Stimulation Modulation of cortical inhibition by rTMS - findings obtained from animal models.Effects of transcranial magnetic stimulation on the cognitive event-related potential p300: a literature review.Vicarious motor activation during action perception: beyond correlational evidence.Patterned Brain Stimulation, What a Framework with Rhythmic and Noisy Components Might Tell Us about Recovery Maximization Modulation of human corticospinal excitability by paired associative stimulation.Current and potential utility of transcranial magnetic stimulation in the diagnostics before brain tumor surgery.Noninvasive Neuromodulation in Poststroke Gait Disorders: Rationale, Feasibility, and State of the Art.TMS as a Tool for Examining Cognitive Processing.Transcranial Electrical Stimulation: What We Know and Do Not Know About Mechanisms.

P2860

Q28076757-4BD5C4AA-44B0-4DE2-93A0-CCE0CEEE5982 Q30357372-923DBFE5-5D51-4594-981C-409BD1FB9DF4 Q30421598-148BF287-6A72-4C6E-8AAD-19F8C7E4B982 Q30430941-288AC80C-D594-4951-AE9C-5A2AE4D20DD3 Q30439705-7C46FBB8-4EE4-4939-81B1-70CF86068B5E Q30454637-0B977165-1D72-404E-A213-EAB7C5790C3B Q30455676-91A080A8-F33A-4CC9-A3A0-36EE25DF14E4 Q30464333-46916E5D-681A-4BA0-B3D3-AFD8FAF0D8A6 Q30470280-2F2F0306-9ACC-47C3-8F05-BA948746E986 Q30471926-B1481D55-E10C-4761-B98E-B74DF56F7272 Q30476293-A3F65EDE-DA10-45EC-A7CD-B247523D105B Q30478753-B8D5B1EC-C486-4FEB-A9F2-D8C967072D02 Q30853553-A4E8E599-5EF0-4FD3-ABB9-A584637E1D26 Q33530526-233938A9-1276-4F03-908D-7E22041D59AE Q33766830-F19362F5-FC6F-4879-B31E-745962DAA1B5 Q33939815-EE3B0006-974F-46BC-960B-0742FB908B30 Q34106701-B730167A-F16D-4B3D-9AD7-50171E245B22 Q34690996-E85ED991-88F9-4A60-B8F2-8111574E3191 Q34966713-DAA9FAE3-3FF4-4296-9966-0F2025968257 Q35375058-20606659-9F9F-45DE-A97C-3C7DCBEE3C3B Q35805693-D8E9620E-43F7-4C4C-A951-22225B5E2F76 Q36466013-7A1EF84B-185B-411A-8B91-3AADC136BB93 Q36469487-813496F8-D6FC-46A6-8166-5B633297F209 Q36635533-FCAEE2B0-85F9-4263-BFF4-B0FC541D7812 Q36739743-6566F54B-786E-41FC-9E04-A04B953C9B50 Q37019241-75E9B6E6-75C5-4548-82E1-20A69292ED2F Q37050571-B976763D-348F-456C-9D36-B0F7134E8581 Q37112570-EDE863B7-C548-4BD1-8F4B-5E5DC8FBEF7E Q37871233-C7C3C4D6-6F5E-4388-8119-A42580D2FFCF Q37878432-576F4668-853E-4066-B357-288437E0BA81 Q37895940-FA8E476F-1A02-4F2C-8E84-4D3C4754A32C Q37902391-BE66AC58-C035-4AFF-926B-291F4A0B9AC8 Q38062909-A9FB7B22-D356-4CD4-953E-E068C8AD17C1 Q38106975-66ABB0FE-24C5-48E2-89B0-DD9A5C916C12 Q38119212-02418042-28C9-46F3-8557-14C4074512AE Q38172122-FFC49A1F-95A9-4496-B76D-746228D8FC61 Q38257044-F3165666-8318-405E-A882-A1980B96FADE Q38476216-2C77BAC6-3D6A-419E-8033-96B65087646F Q38532565-E262B766-3A7D-41F5-8D14-DD0043268BBA Q38732093-CCAA0F1C-F9ED-4A94-B72A-7019FBAFDD3D

P2860

How does transcranial magnetic stimulation modify neuronal activity in the brain? Implications for studies of cognition

http://www.wikidata.org/entity/Q41193886

description

2009 nî lūn-bûn

@nan

2009年の論文

@ja

2009年論文

@yue

2009年論文

@zh-hant

2009年論文

@zh-hk

2009年論文

@zh-mo

2009年論文

@zh-tw

2009年论文

@wuu

2009年论文

@zh

2009年论文

@zh-cn

name

How does transcranial magnetic ...... tions for studies of cognition

@en

type

label

How does transcranial magnetic ...... tions for studies of cognition

@en

prefLabel

How does transcranial magnetic ...... tions for studies of cognition

@en

P1433

Q41193886-ED85387A-0BA5-423B-9E68-94CA5C25B7B8

P1476

Q41193886-B5FA9BAC-3EA2-4CFB-9197-7D48984DCC9F

P2860

Q41193886-0031B7B9-EDF9-4E20-A5E8-90380BEEA050

Q41193886-023870DE-04C6-4619-B21A-A626C672B8A3

Q41193886-061EE9BD-C951-4A00-B856-F41C292BE755

Q41193886-0FB01BCC-2361-4205-8073-D89941BE7F34

Q41193886-1C041BF3-BA92-43DB-BD39-1564038B2D74

Q41193886-1C80B0B1-4F78-4327-965B-F0CF2E31E67C

Q41193886-1F2654BF-E730-4D11-8195-89BB0331EFBF

Q41193886-220CE45D-2353-4119-9173-525DFD6C75D9

Q41193886-27DA9E82-72B5-43B3-901F-3D9E06F1AB7E

Q41193886-2E6CA4A4-7F20-432B-940E-ABE5FFD31124

P304

Q41193886-6F65A5C9-DBC2-47FF-906B-3380F8FAB947

P31

Q41193886-82F9B22D-3E63-4465-8968-51E38A04E751

P356

Q41193886-1C3359BF-6243-41DE-86B4-85267239B2E7

P433

Q41193886-683F0A3D-B664-400E-B0BD-B72C5D5B93E2

P478

Q41193886-3164A4DA-D293-4CD9-9208-4186F863BD00

P50

Q41193886-2C53E022-BE59-4077-AA79-C73323861170

Q41193886-8E725C17-DB73-4A31-A4B0-6C21F248EEF8

Q41193886-982873E5-83A3-4DAF-8317-564AB26127D7

Q41193886-9B4595DF-C3D2-485A-9C35-20BDA6CC7BEC

P577

Q41193886-626ECA44-CCE4-4290-AD89-75727EE187C3

P5875

Q41193886-5908FBE4-A149-47CC-A35B-91A798310410

P698

Q41193886-D7989244-04D4-4FBE-B386-E808593FDDA7

P932

Q41193886-F10692D4-B0E2-4B8E-B21D-12C76872A89A

P356

J.CORTEX.2009.02.007

P1433

P1476

How does transcranial magnetic ...... tions for studies of cognition

@en

P2860

Dorsal premotor cortex exerts state-dependent causal influences on activity in contralateral primary motor and dorsal premotor cortex.

A cortico-cortical mechanism mediating object-driven grasp in humans.

Transcranial magnetic stimulation: new insights into representational cortical plasticity.

Transcranial magnetic stimulation in cognitive neuroscience--virtual lesion, chronometry, and functional connectivity.

Neural adaptation reveals state-dependent effects of transcranial magnetic stimulation.

The physiological basis of transcranial motor cortex stimulation in conscious humans.

Spatial attention changes excitability of human visual cortex to direct stimulation.

Motor evoked potentials.

Spontaneous fluctuations in posterior alpha-band EEG activity reflect variability in excitability of human visual areas

Transcranial magnetic stimulation and synaptic plasticity: experimental framework and human models.

P304

1035-1042

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

P31

scholarly article

P356

10.1016/J.CORTEX.2009.02.007

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

P433

9

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

P478

45

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

P50

Hartwig R. Siebner

Gesa Hartwigsen

P577

2009-03-03T00:00:00Z

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

P5875

24282741

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

P698

19371866

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

P932

2997692

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