Neural basis of adaptive response time adjustment during saccade countermanding.
about
Production, control, and visual guidance of saccadic eye movementsThe influence of recent decisions on future goal selection.From salience to saccades: multiple-alternative gated stochastic accumulator model of visual searchAlpha- and beta-band oscillations subserve different processes in reactive control of limb movements.Neural Mechanisms of Post-error Adjustments of Decision Policy in Parietal Cortex.Proactive and reactive inhibitory control in rats.Neurally constrained modeling of perceptual decision makingPhasic activation of individual neurons in the locus ceruleus/subceruleus complex of monkeys reflects rewarded decisions to go but not stop.Are accuracy and reaction time affected via different processes?Lateralized readiness potentials reveal properties of a neural mechanism for implementing a decision thresholdMicrosaccade production during saccade cancelation in a stop-signal task.Speed-accuracy tradeoff by a control signal with balanced excitation and inhibition.Inhibitory control in mind and brain 2.0: blocked-input models of saccadic countermanding.Competing basal ganglia pathways determine the difference between stopping and deciding not to goCurrent advances and pressing problems in studies of stoppingMacrocircuits: decision networks.Region-Specific Summation Patterns Inform the Role of Cortical Areas in Selecting Motor Plans.The countermanding task revisited: fast stimulus detection is a key determinant of psychophysical performance.Neural control of visual search by frontal eye field: chronometry of neural events and race model processes.Learning a New Selection Rule in Visual and Frontal CortexInhibitory Control Processes and the Strategies That Support Them during Hand and Eye Movements.Response suppression delays the planning of subsequent stimulus-driven saccades.The importance of decision onsetTowards a unifying mechanism for cancelling movements.Models of inhibitory control.Adaptive proactive inhibitory control for embedded real-time applications.RELATING ACCUMULATOR MODEL PARAMETERS AND NEURAL DYNAMICS.Threshold mechanism for saccade initiation in frontal eye field and superior colliculus.Visual salience of the stop-signal affects movement suppression process.Evidence for spatial tuning of movement inhibition.Alternating between pro- and antisaccades: switch-costs manifest via decoupling the spatial relations between stimulus and response.Corrective response times in a coordinated eye-head-arm countermanding task.Can serial dependencies in choices and neural activity explain choice probabilities?Task-switching effects for visual and auditory pro- and antisaccades: evidence for a task-set inertia.Oculomotor task switching: alternating from a nonstandard to a standard response yields the unidirectional prosaccade switch-cost.Neural mechanisms of speed-accuracy tradeoff: Saccade vigor, the origin of targeting errors, and comparison of superior colliculus and frontal eye field.Ultrafast initiation of a neural race by impending errors.Motor selection dynamics in FEF explain the reaction time variance of saccades to single targets.The dynamics of categorization: Unraveling rapid categorization.Using experience to improve: how errors shape behavior and brain activity in monkeys
P2860
Q24289015-5F600F49-FC77-4423-98AB-4DE976DB869BQ27693222-995C699A-4E57-4FED-8D0A-9635AA386277Q28730194-DB1CB13A-7753-455C-9FD5-8903E90D9E3DQ30596894-29EB08B2-5756-49FB-867D-6963DA06AD3EQ30707041-2F84817F-D267-4770-83FF-D2F68D9296F5Q33611685-F63D17FC-1EA4-4F7D-83DA-9F54436A908CQ34302224-8940FB9C-018F-4F75-9D51-4BDD42E24FB4Q34303214-CB8EBC3C-FAFD-4D3E-8082-B31DA9118888Q35048903-4ECCC229-04CD-4EE3-8F01-5843E796EE59Q35119966-59B96E27-583C-41A2-BC4B-C31CD5E41BCAQ35577917-3B7C5C2F-F054-4738-AEF2-819492409C07Q35881850-D7206364-FC63-4486-A65A-B1D6CE40CEA2Q36015051-EE6A51B2-C371-4435-943D-338C183D3658Q36391331-29383E19-59B4-4D13-9DF1-03013943A2CCQ36395159-115CBA74-3C9E-4192-B16A-4D76AF42E97DQ36710273-4C625482-3BF3-41C3-B093-282E62C876E5Q36794382-9FEA9AC3-0751-471D-BA09-4F0032024B47Q36833325-5E0577FB-349A-4F07-BBAA-852C5A44C135Q36907674-C0D73AB5-350C-4B80-B540-0AE4C29641EAQ37126346-00CD32A5-5750-4C8D-97E7-C7358036ACCDQ37486620-6A9F2F76-AA64-4D82-A803-26A953C4DEC9Q37505730-6B44A89E-3D6A-4FA3-8E10-BE0F5CF8E5D2Q38396050-091091DF-0EB0-46DC-9115-AE2B35466491Q38752579-A2F5F4AD-35F3-4900-AADB-698FCC5BF826Q39153448-6F5B34AB-9846-4D74-9BB5-C2B1051B580FQ41787787-30B657F0-0127-40E4-B347-812EF6219540Q47893641-2DFECCEF-4413-463E-BE76-90E1CDEA0344Q48128638-367E47DE-82C2-4AF0-89AB-A1381C4910C4Q48237238-C1F483E2-EE22-4434-8596-46BBBD47F494Q48869696-0AE3F96D-2512-4B3D-BE34-9A66C264AB16Q49156967-D2C33DF7-5A3D-4618-94A3-1C4CF49682D0Q49714073-00D25A44-78F9-4B93-B36D-C3E8572B8761Q50026119-EFE155AF-0156-4547-98E2-56DF9196EE9BQ50607743-777B2988-EDA0-4BC4-8F1D-C4BE725F7745Q50641653-88F07AFB-C407-4BCF-8724-6011E32FD82DQ53407869-35E2F3DE-17C5-4655-BEF7-B0A2203B0991Q53599333-5C22D3D9-2B17-4C7F-AB90-A7BD63E9DA4AQ55278777-DA5688D5-88BB-4DF0-80DD-777295115A25Q55689438-B3618E9F-C04A-4A0F-B200-4C5664471BDCQ57174448-34875F1C-848B-4956-BD5B-20BA4B166907
P2860
Neural basis of adaptive response time adjustment during saccade countermanding.
description
2011 nî lūn-bûn
@nan
2011年の論文
@ja
2011年論文
@yue
2011年論文
@zh-hant
2011年論文
@zh-hk
2011年論文
@zh-mo
2011年論文
@zh-tw
2011年论文
@wuu
2011年论文
@zh
2011年论文
@zh-cn
name
Neural basis of adaptive response time adjustment during saccade countermanding.
@en
type
label
Neural basis of adaptive response time adjustment during saccade countermanding.
@en
prefLabel
Neural basis of adaptive response time adjustment during saccade countermanding.
@en
P2093
P2860
P1476
Neural basis of adaptive response time adjustment during saccade countermanding
@en
P2093
Gordon D Logan
Jeffrey D Schall
Martin Paré
Pierre Pouget
P2860
P304
12604-12612
P356
10.1523/JNEUROSCI.1868-11.2011
P407
P577
2011-08-01T00:00:00Z