Consensus paper: combining transcranial stimulation with neuroimaging.
about
Noninvasive techniques for probing neurocircuitry and treating illness: vagus nerve stimulation (VNS), transcranial magnetic stimulation (TMS) and transcranial direct current stimulation (tDCS).Safety, ethical considerations, and application guidelines for the use of transcranial magnetic stimulation in clinical practice and research.Multi-Dimensional Dynamics of Human Electromagnetic Brain ActivityCortical inhibition, excitation, and connectivity in schizophrenia: a review of insights from transcranial magnetic stimulationClinical utility of brain stimulation modalities following traumatic brain injury: current evidenceCombined neurostimulation and neuroimaging in cognitive neuroscience: past, present, and futurePrimary somatosensory contribution to action observation brain activity-combining fMRI and cTBSEfficacy of transcranial magnetic stimulation targets for depression is related to intrinsic functional connectivity with the subgenual cingulateUnderstanding the role of the primary somatosensory cortex: Opportunities for rehabilitation.The Role of Right Inferior Parietal Cortex in Auditory Spatial Attention: A Repetitive Transcranial Magnetic Stimulation Study.Transcranial magnetic stimulation reveals two functionally distinct stages of motor cortex involvement during perception of emotional body language.Short-term plasticity of visuo-haptic object recognition.Low-frequency transcranial magnetic stimulation over left dorsal premotor cortex improves the dynamic control of visuospatially cued actions.Effects of navigated TMS on object and action naming.Brain connectivity studies in schizophrenia: unravelling the effects of antipsychotics.Concurrent application of TMS and near-infrared optical imaging: methodological considerations and potential artifacts.Transcranial brain stimulation to promote functional recovery after stroke.New approaches to the study of human brain networks underlying spatial attention and related processes.Static field influences on transcranial magnetic stimulation: considerations for TMS in the scanner environmentBrain topological correlates of motor performance changes after repetitive transcranial magnetic stimulation.Transcranial Direct Current Stimulation in Post-stroke Chronic Aphasia: The Impact of Baseline Severity and Task Specificity in a Pilot Sample.Promoting motor function by exercising the brainNon-invasive brain stimulation in neurorehabilitation: local and distant effects for motor recovery.Transcranial magnetic stimulation: a neuroscientific probe of cortical function in schizophrenia.Transcranial magnetic stimulation for the treatment of depression.Measuring and manipulating brain connectivity with resting state functional connectivity magnetic resonance imaging (fcMRI) and transcranial magnetic stimulation (TMS).Voltage-sensitive dye imaging of transcranial magnetic stimulation-induced intracortical dynamics.Combining functional imaging with brain stimulation in Parkinson's disease.A pilot study to investigate the induction and manipulation of learned helplessness in healthy adults.Resting-state networks link invasive and noninvasive brain stimulation across diverse psychiatric and neurological diseases.Vegetative versus minimally conscious states: a study using TMS-EEG, sensory and event-related potentials.Optimal coil orientation for transcranial magnetic stimulation.Excitatory repetitive transcranial magnetic stimulation induces improvements in chronic post-stroke aphasia.Functional neuroimaging of the baboon during concurrent image-guided transcranial magnetic stimulation.The cognitive neuroscience toolkit for the neuroeconomist: A functional overview.A contemporary research topic: manipulative approaches to human brain dynamics.Extracting visual evoked potentials from EEG data recorded during fMRI-guided transcranial magnetic stimulation.Role of functional imaging in the development and refinement of invasive neuromodulation for psychiatric disorders.Opportunities for concurrent transcranial magnetic stimulation and electroencephalography to characterize cortical activity in stroke.Combining transcranial direct current stimulation and neuroimaging: novel insights in understanding neuroplasticity.
P2860
Q24602982-FCD6709A-7457-459C-B5F4-FAE6968A3762Q24606718-48DFF606-7A37-4524-B0F6-C139CDA846CBQ26772811-DEE77978-76EA-48CE-847A-092C2AC81CDCQ26853430-B34F2912-E169-45ED-BF94-0E2EA9A1C954Q26991644-FAE65A08-2185-4624-B7FC-80ABBC2B6221Q27023680-CB83450D-0E3F-4F2C-85EA-FB9626B7BC67Q27320545-D002CE24-836F-43A3-B799-3425F2CFF523Q28267905-79951659-21F5-49B9-A65D-B3458B62975EQ30368868-735C486A-D0DE-4175-8611-24C48EC935C5Q30396500-9411098B-5268-439C-B6F7-D560EED8E4E0Q30404324-5778F709-6E52-4D26-913C-7C561C28A92CQ30439705-49119686-C6AA-42ED-924B-11D87E35E17CQ30451981-2203B0E0-560C-4553-A16D-BDFEF9C2F2E0Q30586735-092A1C16-7274-41D6-B878-F03DA820F3D7Q30596256-6A4A37BD-7759-45EE-A9A8-1E55A3584BB5Q30669965-87924677-7429-4CA6-9B62-3F93BA345559Q30705609-FACC94DC-CDA6-4754-BC41-F3C8442A28D2Q33547799-A95810BD-6925-42E6-9F82-B52957B0BCEDQ33573852-B4E78C2A-3E20-4A62-94B5-E9D7DD8EAC34Q33637718-A45DFFB3-50CC-42D3-B855-22089BB368BBQ33734732-C26D2073-A681-4028-B01E-2A0F9CCAC90BQ33772100-C1FBE84E-2194-440F-AAB1-36D2627A557CQ33813339-39032861-7FD0-483D-B3D2-D03D8F23A667Q33899682-36FB1E5D-521D-47B6-BA9F-58B432FBBA85Q34145856-6876C8F5-C1FE-4038-B20B-3664F1855FA0Q34215644-E2257D2B-59E1-429B-837E-8B4FD542CB9DQ34218188-3D3D0233-64CB-4605-8189-DA7C0BB16FCAQ34243081-062B788F-F28D-45C2-99EF-F1487DF8E12DQ34293686-6C6FA020-7843-408F-BDAC-A2E00A6F4AC2Q34384076-BA51344D-9D03-4257-B54B-401DA151D796Q34608414-BA1EB4E0-CD54-4870-A9F3-20C3FD374F1EQ34672995-4DBA7592-9F3C-4DE7-BA7E-A953A991B3CEQ34676860-1739587E-55FE-4077-8D59-22343BD85886Q35114780-278942B0-0244-43B1-9D32-C505663B6131Q35124835-4A8EB37F-0454-4F46-A4F6-9DC4A984D606Q35153605-66D46042-869E-4E89-8DCD-A13A2E79136CQ35180951-51F4368A-6FE1-49D8-A66E-EA29C9196C0AQ35370603-75A7361F-6A21-454A-8918-74E4F43C20B3Q35569580-CDE7E388-B024-40CA-B088-039167E90C7EQ35951369-BEE60545-89BB-408C-B38B-157024E9DC72
P2860
Consensus paper: combining transcranial stimulation with neuroimaging.
description
2009 nî lūn-bûn
@nan
2009 թուականի Փետրուարին հրատարակուած գիտական յօդուած
@hyw
2009 թվականի փետրվարին հրատարակված գիտական հոդված
@hy
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
name
Consensus paper: combining transcranial stimulation with neuroimaging.
@ast
Consensus paper: combining transcranial stimulation with neuroimaging.
@en
type
label
Consensus paper: combining transcranial stimulation with neuroimaging.
@ast
Consensus paper: combining transcranial stimulation with neuroimaging.
@en
prefLabel
Consensus paper: combining transcranial stimulation with neuroimaging.
@ast
Consensus paper: combining transcranial stimulation with neuroimaging.
@en
P2093
P50
P1433
P1476
Consensus paper: combining transcranial stimulation with neuroimaging.
@en
P2093
Daryl E Bohning
Erie D Boorman
Hitoshi Mochizuki
Jürgen Baudewig
Leonardo G Cohen
Mark S George
Paolo M Rossini
Paul C J Taylor
Reto Huber
Seppo Kähkönen
P356
10.1016/J.BRS.2008.11.002
P50
P577
2009-02-28T00:00:00Z