The prefrontal cortex achieves inhibitory control by facilitating subcortical motor pathway connectivity.
about
The Striatum and Subthalamic Nucleus as Independent and Collaborative Structures in Motor ControlExecutive Dysfunctions: The Role in Attention Deficit Hyperactivity and Post-traumatic Stress Neuropsychiatric DisordersAnticipating conflict: Neural correlates of a Bayesian belief and its motor consequenceWhite matter microstructure between the pre-SMA and the cingulum bundle is related to response conflict in healthy subjects.Abnormal dopaminergic modulation of striato-cortical networks underlies levodopa-induced dyskinesias in humans.Brain Events Underlying Episodic Memory Changes in Aging: A Longitudinal Investigation of Structural and Functional Connectivity.Atomoxetine Enhances Connectivity of Prefrontal Networks in Parkinson's Disease.Tuning the Brake While Raising the Stake: Network Dynamics during Sequential Decision-MakingHigh post-movement parietal low-beta power during rhythmic tapping facilitates performance in a stop task.Frontosubthalamic Circuits for Control of Action and CognitionResponse Inhibition Is Facilitated by a Change to Red Over Green in the Stop Signal Paradigm.Inhibitory dysfunction contributes to some of the motor and non-motor symptoms of movement disorders and psychiatric disorders.Separate neural systems for behavioral change and for emotional responses to failure during behavioral inhibition.Atomoxetine restores the response inhibition network in Parkinson's disease.Memory-reliant Post-error Slowing Is Associated with Successful Learning and Fronto-occipital Activity.A test-retest reliability analysis of diffusion measures of white matter tracts relevant for cognitive control.On the Globality of Motor Suppression: Unexpected Events and Their Influence on Behavior and Cognition.Fractionating impulsivity: neuropsychiatric implications.Temporal Uncertainty and Temporal Estimation Errors Affect Insular Activity and the Frontostriatal Indirect Pathway during Action Update: A Predictive Coding Study.Speed of saccade execution and inhibition associated with fractional anisotropy in distinct fronto-frontal and fronto-striatal white matter pathways.Subthalamic nucleus gamma activity increases not only during movement but also during movement inhibition.Association Between Baseline Corticothalamic-Mediated Inhibitory Control and Smoking Relapse Vulnerability.Identification of Two Heritable Cross-Disorder Endophenotypes for Tourette Syndrome.PreSMA stimulation changes task-free functional connectivity in the fronto-basal-ganglia that correlates with response inhibition efficiency.Topography and timing of activity in right inferior frontal cortex and anterior insula for stopping movement.Prefrontal AMPA receptors are involved in the effect of methylphenidate on response inhibition in rats.White matter integrity mediates decline in age-related inhibitory control.Altered functional connectivity of the subthalamus and the bed nucleus of the stria terminalis in obsessive-compulsive disorder.A proactive task set influences how response inhibition is implemented in the basal ganglia.Is better preservation of eccentric strength after stroke due to altered prefrontal function?Evidence for parallel activation of the pre-supplementary motor area and inferior frontal cortex during response inhibition: a combined MEG and TMS study.The Disconnected Brain and Executive Function Decline in Aging.Ready for change: Oscillatory mechanisms of proactive motor control.Right Fronto-Subcortical White Matter Microstructure Predicts Cognitive Control Ability on the Go/No-go Task in a Community Sample.Oscillatory motor patterning is impaired in neurofibromatosis type 1: a behavioural, EEG and fMRI study.Convergence Analysis of Micro-Lesions (CAML): An approach to mapping of diffuse lesions from carotid revascularization.The site of stimulation moderates neuropsychiatric symptoms after subthalamic deep brain stimulation for Parkinson's disease.Response inhibition on the stop signal task improves during cardiac contraction.Activity and Connectivity Differences Underlying Inhibitory Control Across the Adult Life SpanResponse Inhibition Deficits in Insomnia Disorder: An Event-Related Potential Study With the Stop-Signal Task
P2860
Q26766029-ACBAC3B0-C240-4DC2-90C2-C3A6AE3245F9Q28073484-42256843-86F1-433B-A5B5-D9EA6EDABC1BQ36042358-924EC32B-0DA8-4B38-A749-999A99AEBDB3Q36186514-1C864B8C-7841-4774-9F33-A174734A41CAQ36186759-D49D5844-9FAB-4227-933E-430FC69EBA56Q36533839-EC0A9605-327C-4F1D-AF7C-765CCA99F939Q36870256-E58BA3AF-4458-47C2-BD11-846ABBAB33CBQ36889645-DBF80425-057B-4FFB-AC4E-CF4E041FCB68Q37238148-CA88FE40-68B1-48CD-B673-FD2A6A759131Q37444977-4B825E63-E6E2-4B7F-87E0-2A0F8EBFBC56Q37553373-AD5B1A0E-5464-4D5E-ADF1-6DC03B2224A2Q38752575-4A3125C3-5FF5-4BC3-BC47-D5466905DD78Q38827305-2DE99648-EA4D-4094-856F-086EC6AE676CQ38848619-E396FDAE-48ED-4FB7-92B2-D67F1400E11BQ38860459-6EEBD937-DA0E-4CCC-BC47-74258F094F57Q39079130-CDE7E9B5-35B6-47E3-B0D0-392A4EDB0222Q39095212-8CEEF434-1582-4EA7-9B76-9E671EC72767Q39139768-524AB0CD-C654-4517-8F10-5F2B21851539Q39572772-518C8720-4991-4DAF-836F-16978743E892Q39841082-A709F299-0358-4796-A4D3-794E125FF994Q41121794-A26E874C-8DDE-4BB5-83DE-615F62C7DEC9Q41455875-466FFB24-B331-47E7-A4E9-02BDA2618B52Q41630924-5E41378A-84B1-40BA-A37C-A36769E444B6Q42024576-E4A2549C-36FE-41D4-A9A0-BF96968CE487Q46199975-8E9809F2-B65B-4767-9BA1-A7CFE8A91CC1Q47267151-04EC8195-A503-4D96-B6FD-D314EF35B049Q47615833-666A8E8D-4036-4E09-B787-D478875DD02EQ48146276-F092AC4B-8C48-4440-B78F-315D2C0259B8Q48588782-0E162DC6-C1AE-45F1-9B9C-3BDFB620AC2EQ49018577-06B134AF-3AC0-4D2B-AD73-382C076EE127Q49265228-75063738-4787-47FB-A695-73F149FAA122Q50532688-181B8459-27ED-46A0-99FA-ED64C0775364Q54965542-EDA9F0B4-25BC-4971-B9E3-E5D311DA9611Q55043088-B8F67B7C-08FB-4093-978E-88624C44385BQ55068922-AC50EABD-790B-4DF1-811E-664EA063EB3DQ55228807-F05D4A7F-BEBE-4552-9900-58279AF175F5Q55286663-1E2DE887-5970-4169-BB55-6BBAEE45CA02Q55300108-8226A641-9F4A-472E-973A-3D3D963E0E28Q58763317-72B39CC8-75AD-49B1-B412-8F548EE0D3FAQ58797157-2268553C-86D2-4B40-896F-27CF6C012418
P2860
The prefrontal cortex achieves inhibitory control by facilitating subcortical motor pathway connectivity.
description
2015 nî lūn-bûn
@nan
2015 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
2015 թվականի հունվարին հրատարակված գիտական հոդված
@hy
2015年の論文
@ja
2015年論文
@yue
2015年論文
@zh-hant
2015年論文
@zh-hk
2015年論文
@zh-mo
2015年論文
@zh-tw
2015年论文
@wuu
name
The prefrontal cortex achieves ...... al motor pathway connectivity.
@ast
The prefrontal cortex achieves ...... al motor pathway connectivity.
@en
The prefrontal cortex achieves ...... al motor pathway connectivity.
@nl
type
label
The prefrontal cortex achieves ...... al motor pathway connectivity.
@ast
The prefrontal cortex achieves ...... al motor pathway connectivity.
@en
The prefrontal cortex achieves ...... al motor pathway connectivity.
@nl
prefLabel
The prefrontal cortex achieves ...... al motor pathway connectivity.
@ast
The prefrontal cortex achieves ...... al motor pathway connectivity.
@en
The prefrontal cortex achieves ...... al motor pathway connectivity.
@nl
P2860
P50
P1476
The prefrontal cortex achieves ...... cal motor pathway connectivity
@en
P2093
Michael C Anderson
P2860
P304
P356
10.1523/JNEUROSCI.3093-13.2015
P407
P577
2015-01-01T00:00:00Z