about
Vision, Perception, and Attention through the Lens of Microsaccades: Mechanisms and ImplicationsCell-Type-Specific Activity in Prefrontal Cortex during Goal-Directed Behavior.Dorso-Lateral Frontal Cortex of the Ferret Encodes Perceptual Difficulty during Visual DiscriminationNeurofunctional Abnormalities during Sustained Attention in Severe Childhood AbuseReward Contingencies Improve Goal-Directed Behavior by Enhancing Posterior Brain Attentional Regions and Increasing Corticostriatal Connectivity in Cocaine AddictsElectrocorticography Reveals Enhanced Visual Cortex Responses to Visual Speech.ErbB4 regulation of a thalamic reticular nucleus circuit for sensory selection.The influence of expertise on brain activation of the action observation network during anticipation of tennis and volleyball serves.Changes in perceptual sensitivity related to spatial cues depends on subcortical activity.Selective impairments of alerting and executive control in HIV-infected patients: evidence from attention network test.Attention as an effect not a cause.Increased functional connectivity between dorsal posterior parietal and ventral occipitotemporal cortex during uncertain memory decisionsAttention, reward, and information seeking.Saccades and shifting receptive fields: anticipating consequences or selecting targets?Increased amygdala and visual cortex activity and functional connectivity towards stimulus novelty is associated with state anxiety.Retrieval induces adaptive forgetting of competing memories via cortical pattern suppression.Not all attention orienting is created equal: recognition memory is enhanced when attention orienting involves distractor suppressionCopula regression analysis of simultaneously recorded frontal eye field and inferotemporal spiking activity during object-based working memory.A Multi-Area Stochastic Model for a Covert Visual Search TaskFunctional evolution of new and expanded attention networks in humansA Normalization Framework for Emotional Attention.Spatial Attention and Temporal Expectation Under Timed Uncertainty Predictably Modulate Neuronal Responses in Monkey V1LIP activity in the interstimulus interval of a change detection task biases the behavioral responsePulvinar-Cortex Interactions in Vision and AttentionDistinct relationships of parietal and prefrontal cortices to evidence accumulationA ventral salience network in the macaque brainRemapping, Spatial Stability, and Temporal Continuity: From the Pre-Saccadic to Postsaccadic Representation of Visual Space in LIP.Does the Superior Colliculus Control Perceptual Sensitivity or Choice Bias during Attention? Evidence from a Multialternative Decision FrameworkFeedforward motor information enhances somatosensory responses and sharpens angular tuning of rat S1 barrel cortex neurons.The role of prefrontal catecholamines in attention and working memory.Visual attention mitigates information loss in small- and large-scale neural codes.Prefrontal Cortical Inactivations Decrease Willingness to Expend Cognitive Effort on a Rodent Cost/Benefit Decision-Making Task.Linking ADHD to the Neural Circuitry of Attention.A wireless transmission neural interface system for unconstrained non-human primates.The Influences of Emotion on Learning and MemoryObject-based selection modulates top-down attentional shifts.Communication between Brain Areas Based on Nested Oscillations.Neural signatures of dynamic stimulus selection in Drosophila.Functions and dysfunctions of neocortical inhibitory neuron subtypes.Selective attention. Long-range and local circuits for top-down modulation of visual cortex processing.
P2860
Q26773134-4928FAD8-7483-4DB6-B61D-8B0B0D1B21C4Q27305322-443E4D91-3791-4F5A-A048-5044986C7AD2Q27325708-BB4FA3A6-66CC-42B0-B790-EC2C59395CB8Q28553474-E35394FE-B62E-4B63-A46C-857935B69D9AQ28554647-48A0650C-7977-447B-AF04-B4BF6AE10F81Q30370871-588F7D01-A311-49EE-B5D1-8B95F7AC24ECQ30407979-2DA474B4-52DE-46A2-AA43-E2EDB81363DFQ30585572-D00A9782-23D9-4094-844A-84A704C3CC15Q33790764-E48B409E-9652-4E30-8097-901F4CE969F5Q33836675-2EBF6FE0-AB03-44B0-986C-11FD53D32D09Q34293747-BD3FC0B8-C155-4AAE-8EAF-DB82207A67B0Q34483883-3FA1BFCB-34AD-4F05-AE0F-EF352CCD7FBCQ34491772-966F055F-2324-4CB7-B3AC-CC73A92E1275Q34786127-2743C22E-580C-43A9-B156-E82216B6D256Q35154877-F630E417-CA20-4E92-81D3-F7F627DE1774Q35379274-005FD3BD-DF55-499E-A356-816052D4A744Q35418121-A69E4193-493D-4E0A-99F7-CC85DF7D4D67Q35707842-A46D7EC4-799E-486C-ADE8-D59C6EC44872Q35750054-D5271986-16D2-4E7A-A4B9-2C7DA2980C01Q35910258-3750E83E-99FD-485B-A806-82904BF47B21Q36199618-D682ABBD-10E0-46DB-85AC-B43FCB73EFA3Q36255678-EA34614C-FB97-4557-9F70-2F219BFFD068Q36275049-516F4410-2F0F-4068-99FD-1EDFCE6F09F7Q36492306-57CC5642-A0FB-44E4-A2FF-9E61721547F7Q36808357-43877A9B-79CC-49F6-AA5F-270A8DAA02DEQ36854079-346C80FD-E13F-426A-93DA-BE2F3FD83FF6Q36982901-14804117-796E-4058-BB78-D3A47F738673Q37592157-30D0398F-D168-4153-BF25-DFFBCC698E93Q37610622-3FC1A958-1707-4187-A2A0-0709946F4E1DQ38208293-104AADCF-C172-4866-88A0-F9316E67CB8AQ38376977-CC1F07EE-A401-47B1-A913-2CF20F3C2E13Q38902705-477D93FB-761B-40CC-B1B6-52A527B620BBQ39292105-EE88116A-0D7D-4B4B-B8D6-2617B6B5C75FQ40304930-5EB09FA6-56D6-4991-8E3E-B1EAE8740D40Q41537461-DEEB0992-1708-474C-95D8-8AC487A29627Q41969606-BDD239B0-9B2E-470B-84C9-83B689DD0794Q42227274-91BCFD6E-0C76-4D7E-8B31-50CB3295D573Q45061192-C631E2FB-6BFE-4C5A-8AC6-ACD95BA38562Q45939687-F0EAF41F-06F1-408B-B2A9-643CA21E1363Q46356853-4D0320D4-59A0-4895-BF80-B34DE4417B4B
P2860
description
article científic
@ca
article scientifique
@fr
articol științific
@ro
articolo scientifico
@it
artigo científico
@gl
artigo científico
@pt
artigo científico
@pt-br
artikel ilmiah
@id
artikull shkencor
@sq
artículo científico
@es
name
Prefrontal contributions to visual selective attention.
@en
type
label
Prefrontal contributions to visual selective attention.
@en
prefLabel
Prefrontal contributions to visual selective attention.
@en
P2093
P1476
Prefrontal contributions to visual selective attention
@en
P2093
Behrad Noudoost
Ryan F Squire
Tirin Moore
P304
P356
10.1146/ANNUREV-NEURO-062111-150439
P577
2013-07-01T00:00:00Z