scholarly article | Q13442814 |
review article | Q7318358 |
P50 | author | Heleen A. Slagter | Q42632537 |
Dirk van Moorselaar | Q91592575 | ||
P2860 | cites work | Habituation revisited: an updated and revised description of the behavioral characteristics of habituation | Q24644850 |
Habituation: a history | Q24646676 | ||
To see or not to see: prestimulus alpha phase predicts visual awareness | Q24653905 | ||
The what, where, and why of priority maps and their interactions with visual working memory | Q28083705 | ||
The phase of ongoing EEG oscillations predicts visual perception | Q28248905 | ||
The hippocampus as a spatial map. Preliminary evidence from unit activity in the freely-moving rat | Q28250476 | ||
A theory of cortical responses | Q28254705 | ||
A feature-integration theory of attention | Q28281952 | ||
Orienting of attention | Q28282162 | ||
Neural mechanisms of selective visual attention | Q28292891 | ||
Distinct Mechanisms for Distractor Suppression and Target Facilitation | Q28601113 | ||
Memory--a century of consolidation | Q29618665 | ||
Predictive coding in the visual cortex: a functional interpretation of some extra-classical receptive-field effects | Q29618746 | ||
On the cyclic nature of perception in vision versus audition | Q30412723 | ||
Alpha-Band Oscillations Enable Spatially and Temporally Resolved Tracking of Covert Spatial Attention | Q30491750 | ||
Causal role of the prefrontal cortex in top-down modulation of visual processing and working memory | Q30499901 | ||
Hippocampal "time cells": time versus path integration | Q30570915 | ||
Visual recognition memory, manifested as long-term habituation, requires synaptic plasticity in V1 | Q30635024 | ||
The neural basis of biased competition in human visual cortex | Q30660923 | ||
Preparatory attention in visual cortex. | Q31169732 | ||
Modulation of gamma and alpha activity during a working memory task engaging the dorsal or ventral stream. | Q33279598 | ||
Top-down facilitation of visual recognition | Q33342000 | ||
A cortical-hippocampal system for declarative memory | Q33938394 | ||
Anticipatory attentional suppression of visual features indexed by oscillatory alpha-band power increases: a high-density electrical mapping study | Q34012497 | ||
Preparatory effects of distractor suppression: evidence from visual cortex | Q34098913 | ||
Top-down modulation: bridging selective attention and working memory | Q34114941 | ||
Signal enhancement and suppression during visual-spatial selective attention | Q34203701 | ||
Experience-dependent attentional tuning of distractor rejection | Q34303704 | ||
Distinct neural mechanisms of distractor suppression in the frontal and parietal lobe | Q34391883 | ||
Probability cueing of distractor locations: both intertrial facilitation and statistical learning mediate interference reduction. | Q34463118 | ||
Increases in alpha oscillatory power reflect an active retinotopic mechanism for distracter suppression during sustained visuospatial attention. | Q34566061 | ||
The medial temporal lobe memory system | Q34599469 | ||
α-Oscillations in the monkey sensorimotor network influence discrimination performance by rhythmical inhibition of neuronal spiking. | Q35585833 | ||
Top-down control of the phase of alpha-band oscillations as a mechanism for temporal prediction. | Q35845911 | ||
A visual salience map in the primate frontal eye field | Q35974505 | ||
Rapid acquisition but slow extinction of an attentional bias in space | Q36055272 | ||
Evidence for negative feature guidance in visual search is explained by spatial recoding | Q36101639 | ||
Do the contents of visual working memory automatically influence attentional selection during visual search? | Q36103104 | ||
Neural correlates of prior expectations of motion in the lateral intraparietal and middle temporal areas | Q36137063 | ||
A common neural mechanism for preventing and terminating the allocation of attention | Q36370205 | ||
Orchestrating Proactive and Reactive Mechanisms for Filtering Distracting Information: Brain-Behavior Relationships Revealed by a Mixed-Design fMRI Study | Q36480293 | ||
Mechanisms of selective inhibition in visual spatial attention are indexed by alpha-band EEG synchronization | Q48281383 | ||
On the electrophysiological evidence for the capture of visual attention. | Q48289066 | ||
The ignoring paradox: cueing distractor features leads first to selection, then to inhibition of to-be-ignored items | Q48409001 | ||
A temporal dependency account of attentional inhibition in oculomotor control | Q48432838 | ||
Attentional preparation for a lateralized visual distractor: behavioral and fMRI evidence | Q48500183 | ||
Region-based shielding of visual search from salient distractors: Target detection is impaired with same- but not different-dimension distractors. | Q48550739 | ||
Causal implication by rhythmic transcranial magnetic stimulation of alpha frequency in feature-based local vs. global attention | Q48627091 | ||
Bayesian inference and attentional modulation in the visual cortex | Q48722848 | ||
Short-term and long-term plasticity in the visual-attention system: Evidence from habituation of attentional capture. | Q48870502 | ||
Taming the White Bear: Initial Costs and Eventual Benefits of Distractor Inhibition | Q48893230 | ||
Spatially Selective Alpha Oscillations Reveal Moment-by-Moment Trade-offs between Working Memory and Attention | Q50079479 | ||
Statistical regularities modulate attentional capture | Q50140114 | ||
How to inhibit a distractor location? Statistical learning versus active, top-down suppression | Q50422074 | ||
Altering spatial priority maps via statistical learning of target selection and distractor filtering. | Q50425206 | ||
Filtering visual onsets via habituation: A context-specific long-term memory of irrelevant stimuli. | Q50582123 | ||
In competition for the attentional template: can multiple items within visual working memory guide attention? | Q50670598 | ||
Suppression of salient objects prevents distraction in visual search. | Q50852927 | ||
Attentional capture in visual search: Capture and post-capture dynamics revealed by EEG. | Q50863577 | ||
Target selection in area V4 during a multidimensional visual search task. | Q51646791 | ||
Attentional capture by salient distractors during visual search is determined by temporal task demands. | Q51856648 | ||
The role of relational information in contingent capture. | Q51898556 | ||
Top-down attentional control for distractor locations: the benefit of precuing distractor locations on target localization and discrimination. | Q51911393 | ||
Visual search for singleton feature targets across dimensions: Stimulus- and expectancy-driven effects in dimensional weighting | Q51946082 | ||
Cueing the location of a distractor: an inhibitory mechanism of spatial attention? | Q51953313 | ||
Concurrent working memory load can facilitate selective attention: evidence for specialized load. | Q51975530 | ||
It's under control: top-down search strategies can override attentional capture. | Q52016820 | ||
Spatial probability as an attentional cue in visual search. | Q52024926 | ||
Top-down control over biased competition during covert spatial orienting. | Q52107236 | ||
The lateral intraparietal area as a salience map: the representation of abrupt onset, stimulus motion, and task relevance. | Q52168764 | ||
Anticipatory biasing of visuospatial attention indexed by retinotopically specific alpha-band electroencephalography increases over occipital cortex. | Q52170403 | ||
Visual search for singleton feature targets within and across feature dimensions. | Q52211231 | ||
Overriding stimulus-driven attentional capture. | Q52217016 | ||
Higher nervous functions; the orienting reflex. | Q52355708 | ||
Cortical mechanisms of prioritizing selection for rejection in visual search. | Q52565535 | ||
Prefrontal Control of Visual Distraction. | Q52708698 | ||
Effects of task relevance and stimulus-driven salience in feature-search mode. | Q53877612 | ||
Guided Search 2.0 A revised model of visual search | Q55982827 | ||
No evidence for enhanced distractor template representation in early visual cortex | Q57602804 | ||
Desensitizing the attention system to distraction while idling: A new latent learning phenomenon in the visual attention domain | Q57787337 | ||
Inhibition as a potential resolution to the attentional capture debate | Q58596689 | ||
No Evidence that Predictions and Attention Modulate the First Feedforward Sweep of Cortical Information Processing | Q64084221 | ||
Attention promotes the neural encoding of prediction errors | Q64097191 | ||
The attentional template is shifted and asymmetrically sharpened by distractor context | Q64228226 | ||
The basal ganglia in human learning | Q36535658 | ||
The topography of alpha-band activity tracks the content of spatial working memory | Q36597919 | ||
LIP responses to a popout stimulus are reduced if it is overtly ignored | Q36656574 | ||
Visual perception and memory: a new view of medial temporal lobe function in primates and rodents | Q36785113 | ||
Capture versus suppression of attention by salient singletons: Electrophysiological evidence for an automatic attend-to-me signal | Q36995653 | ||
Templates for rejection: configuring attention to ignore task-irrelevant features | Q37280569 | ||
Active suppression after involuntary capture of attention | Q37353763 | ||
The normalization model of attention | Q37382989 | ||
Rhythmic pulsing: linking ongoing brain activity with evoked responses | Q37808113 | ||
Shaping functional architecture by oscillatory alpha activity: gating by inhibition | Q37814095 | ||
Different states in visual working memory: when it guides attention and when it does not. | Q37888290 | ||
The Role of Alpha-Band Brain Oscillations as a Sensory Suppression Mechanism during Selective Attention. | Q37903678 | ||
α-band oscillations, attention, and controlled access to stored information | Q38058950 | ||
The neural basis of attentional control in visual search | Q38220305 | ||
'Activity-silent' working memory in prefrontal cortex: a dynamic coding framework | Q38519422 | ||
From Behavior to Neural Dynamics: An Integrated Theory of Attention. | Q38602205 | ||
Is perception discrete or continuous? | Q39220273 | ||
Decoding and Reconstructing the Focus of Spatial Attention from the Topography of Alpha-band Oscillations | Q39898056 | ||
Alpha-band electroencephalographic activity over occipital cortex indexes visuospatial attention bias and predicts visual target detection. | Q40288636 | ||
Alpha Power Predicts Persistence of Bistable Perception | Q40998848 | ||
Encoding of Stimulus Probability in Macaque Inferior Temporal Cortex | Q41081243 | ||
Attention, uncertainty, and free-energy | Q41149680 | ||
The adaptive character of the attentional system: statistical sensitivity in a target localization task | Q41993445 | ||
Alpha oscillations serve to protect working memory maintenance against anticipated distracters | Q44456893 | ||
Attentional capture during visual search is attenuated by target predictability: evidence from the N2pc, Pd, and topographic segmentation | Q44746695 | ||
Event-related potentials reveal the effect of prior knowledge on competition for representation and attentional capture | Q44989624 | ||
The free-energy principle: a rough guide to the brain? | Q45963636 | ||
The role of the pulvinar in distractor processing and visual search. | Q46030349 | ||
Search goal tunes visual features optimally | Q46103356 | ||
Distractor probability changes the shape of the attentional template | Q46170051 | ||
The Role of Inhibition in Avoiding Distraction by Salient Stimuli | Q46199760 | ||
Dissociable Decoding of Spatial Attention and Working Memory from EEG Oscillations and Sustained Potentials. | Q46342783 | ||
Electrophysiological correlates of feature analysis during visual search | Q46607076 | ||
Perceptual selectivity for color and form | Q46660255 | ||
Mixed selectivity morphs population codes in prefrontal cortex | Q47305098 | ||
Less is more: expectation sharpens representations in the primary visual cortex | Q47331344 | ||
Selective inhibition of distracting input | Q48014386 | ||
Tracking target and distractor processing in fixed-feature visual search: evidence from human electrophysiology | Q48111011 | ||
Prior expectations induce prestimulus sensory templates | Q48116136 | ||
The distracting impact of repeated visible and invisible onsets on focused attention. | Q48233065 | ||
Experience-dependent spatial expectations in mouse visual cortex. | Q48265997 | ||
Attention and temporal expectations modulate power, not phase, of ongoing alpha oscillations | Q48278840 | ||
Associative Prediction of Visual Shape in the Hippocampus. | Q64930253 | ||
Combined Electrophysiological and Behavioral Evidence for the Suppression of Salient Distractors. | Q64978964 | ||
Perceptual framing and cortical alpha rhythm | Q71013039 | ||
Top-down search strategies cannot override attentional capture | Q80023193 | ||
Preparatory activity in visual cortex indexes distractor suppression during covert spatial orienting | Q80341187 | ||
Electrophysiological indices of target and distractor processing in visual search | Q81480245 | ||
Expectations Do Not Alter Early Sensory Processing during Perceptual Decision-Making | Q88721505 | ||
Habituation of oculomotor capture by sudden onsets: Stimulus specificity, spontaneous recovery and dishabituation | Q90662165 | ||
Evidence for second-order singleton suppression based on probabilistic expectations | Q90821320 | ||
Template-to-distractor distinctiveness regulates visual search efficiency | Q91456761 | ||
Learning What Is Irrelevant or Relevant: Expectations Facilitate Distractor Inhibition and Target Facilitation through Distinct Neural Mechanisms | Q91592581 | ||
Learning to suppress a distractor is not affected by working memory load | Q91660901 | ||
Feature-based statistical regularities of distractors modulate attentional capture | Q91888120 | ||
The functional role of alpha-band activity in attentional processing: the current zeitgeist and future outlook | Q92117013 | ||
Getting rid of visual distractors: the why, when, how, and where | Q92270628 | ||
Spatial suppression due to statistical regularities is driven by distractor suppression not by target activation | Q92346977 | ||
Probability cueing of singleton-distractor locations in visual search: Priority-map- versus dimension-based inhibition? | Q92396024 | ||
Statistical regularities induce spatial as well as feature-specific suppression | Q92484004 | ||
Anticipatory Distractor Suppression Elicited by Statistical Regularities in Visual Search | Q92627036 | ||
Oscillatory Mechanisms of Preparing for Visual Distraction | Q92655453 | ||
Cueing distraction: electrophysiological evidence for anticipatory active suppression of distractor location | Q92762868 | ||
Prefrontal Cortex Regulates Sensory Filtering through a Basal Ganglia-to-Thalamus Pathway | Q92769671 | ||
Distractor handling via dimension weighting | Q92897140 | ||
Electrical stimulation of alpha oscillations stabilizes performance on visual attention tasks | Q93027951 | ||
The role of alpha oscillations in spatial attention: limited evidence for a suppression account | Q93346440 | ||
P275 | copyright license | Creative Commons Attribution-NonCommercial | Q6936496 |
P433 | issue | 1 | |
P407 | language of work or name | English | Q1860 |
P921 | main subject | brain | Q1073 |
P304 | page(s) | 204-221 | |
P577 | publication date | 2020-01-17 | |
2020-03-01 | |||
P1433 | published in | Annals of the New York Academy of Sciences | Q2431664 |
P1476 | title | Inhibition in selective attention | |
P478 | volume | 1464 |
Q98513658 | A dual mechanism underlying retroactive shifts of auditory spatial attention: dissociating target- and distractor-related modulations of alpha lateralization | cites work | P2860 |
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