Analysis of synchrony demonstrates 'pain networks' defined by rapidly switching, task-specific, functional connectivity between pain-related cortical structures.
about
Functional brain interactions that serve cognitive-affective processing during pain and placebo analgesiaLow-frequency BOLD fluctuations demonstrate altered thalamocortical connectivity in diabetic neuropathic painNeuroimaging chronic pain: what have we learned and where are we going?Altered resting state in diabetic neuropathic pain.Muscular pain in Parkinson's disease and nociceptive processing assessed with CO2 laser-evoked potentials.Attention to painful cutaneous laser stimuli evokes directed functional connectivity between activity recorded directly from human pain-related cortical structures.Painful laser stimuli induce directed functional interactions within and between the human amygdala and hippocampus.Attention to painful cutaneous laser stimuli evokes directed functional interactions between human sensory and modulatory pain-related cortical areas.Studies of properties of "Pain Networks" as predictors of targets of stimulation for treatment of pain.Nociceptive pathway function is normal in cervical dystonia: a study using laser-evoked potentials.Pain and the brain: specificity and plasticity of the brain in clinical chronic pain.EEG analysis reveals widespread directed functional interactions related to a painful cutaneous laser stimulus.Painful cutaneous laser stimuli induce event-related gamma-band activity in the lateral thalamus of humansFear conditioning is associated with dynamic directed functional interactions between and within the human amygdala, hippocampus, and frontal lobePain-related deactivation of medial prefrontal cortical neurons involves mGluR1 and GABA(A) receptors.Characteristics of evoked potential multiple EEG recordings in patients with chronic pain by means of parallel factor analysis.Functional role of induced gamma oscillatory responses in processing noxious and innocuous sensory events in humans.Functional Connectivity of EEG Signals Under Laser Stimulation in Migraine.Quantitative somatic sensory testing and functional imaging of the response to painful stimuli before and after cingulotomy for obsessive-compulsive disorder (OCD).Oscillatory EEG activity induced by conditioning stimuli during fear conditioning reflects Salience and Valence of these stimuli more than Expectancy.Modulation of medial prefrontal cortical activity using in vivo recordings and optogenetics.Towards a theory of chronic pain.Forebrain pain mechanisms.Brain Rhythms of Pain.Pathophysiology of somatosensory abnormalities in Parkinson disease.Altered insula-default mode network connectivity in fibromyalgia: a resting-state magnetoencephalographic study.Insular Cortex is Critical for the Perception, Modulation, and Chronification of Pain.Functional integration within the human pain system as revealed by Granger causality.Network-based activity induced by 4-aminopyridine in rat dorsal horn in vitro is mediated by both chemical and electrical synapses.Closed-Loop Deep Brain Stimulation for Refractory Chronic Pain.Does High Frequency Transcutaneous Electrical Nerve Stimulation (TENS) Affect EEG Gamma Band Activity?
P2860
Q24684111-18D8720E-71C5-4AF5-8D31-0A0E4F1A0DFCQ30920824-58437EC5-D01C-4C58-BC99-F716D802B604Q31159689-7410EE36-F45E-4D44-99CC-CA5A5C0D361BQ33410803-E6FA20A5-FC7C-420D-9B9F-D443A6AE5183Q33523086-4CE78DCF-D393-4CD6-BD07-60644171294BQ33800221-903E29D3-1BC8-4F13-BAE7-4725A664A008Q33800458-DA149A5C-41FF-4BAC-B0E2-B2FA69E7900EQ34060231-ED73FF8B-1381-46E4-8844-5FF91E3DD86FQ34098850-A014170E-329D-4567-9806-CBA9BE31D90AQ34164515-5D4B5C3E-2A47-49A3-AF3C-6F64E74719A3Q34609494-17B75810-4D58-45B0-8973-ADAA0BDBC062Q34941824-510A9CE3-C672-4DFD-8608-D92292B4D42CQ35138397-9652D7C8-48C8-4E32-AA54-3494BBD2655CQ35147911-78F99E7F-D799-40D9-A4C9-7A905C18FE28Q35543943-4962216F-7691-47B7-B5C1-CCD38A851C21Q35779591-43051F32-9DDD-4B24-8210-0B4EE03F0879Q35789252-CA47A954-CA26-4DC6-B4D7-C94662BDE127Q35860682-8F4FE5D9-BA57-4659-B6F3-6DD358F490CAQ35918974-51684C53-1710-4EC2-8E70-94C4902B46B7Q36246803-9A4391AD-C09F-48D6-AA34-F7252D01162CQ36591598-C0FFEBB1-D6FD-4BA7-96D2-12FEC34FB359Q37116414-7A722A96-7897-4FF0-A8DC-C1FF8801D77DQ37238581-28077ECD-B384-47A0-9C25-3519B32197FDQ37731135-3473780E-A7F9-4A21-B3AF-7A3CB3438CDCQ38161787-2532074E-3CB4-4486-A1AA-2ECBD9E79EDBQ38638463-FD67FCAF-9A18-4A06-A3C6-4675A7E2CD6DQ38742554-438EF78A-107E-4EF2-A1F6-22CB6F8D1CD3Q43643550-F25911FD-91A4-445C-AC8F-8ED4CD676720Q44426865-26E5FDB6-C2B2-4401-BDBA-60A851229436Q52327340-30C93573-7B42-4F89-AAB8-C18580427D6AQ57494573-8FEC5DBC-8931-4F56-95FE-F7757D65518C
P2860
Analysis of synchrony demonstrates 'pain networks' defined by rapidly switching, task-specific, functional connectivity between pain-related cortical structures.
description
2006 nî lūn-bûn
@nan
2006 թուականի Մարտին հրատարակուած գիտական յօդուած
@hyw
2006 թվականի մարտին հրատարակված գիտական հոդված
@hy
2006年の論文
@ja
2006年論文
@yue
2006年論文
@zh-hant
2006年論文
@zh-hk
2006年論文
@zh-mo
2006年論文
@zh-tw
2006年论文
@wuu
name
Analysis of synchrony demonstr ...... n-related cortical structures.
@ast
Analysis of synchrony demonstr ...... n-related cortical structures.
@en
type
label
Analysis of synchrony demonstr ...... n-related cortical structures.
@ast
Analysis of synchrony demonstr ...... n-related cortical structures.
@en
prefLabel
Analysis of synchrony demonstr ...... n-related cortical structures.
@ast
Analysis of synchrony demonstr ...... n-related cortical structures.
@en
P2093
P1433
P1476
Analysis of synchrony demonstr ...... n-related cortical structures.
@en
P2093
P304
P356
10.1016/J.PAIN.2006.02.012
P407
P577
2006-03-24T00:00:00Z