| scholarly article | Q13442814 |
| P50 | author | J J Clark | Q77793091 |
| P2093 | author name string | Ziad M Hafed | |
| P2860 | cites work | Covert visual spatial orienting and saccades: overlapping neural systems | Q28145610 |
| Microsaccadic eye movements and firing of single cells in the striate cortex of macaque monkeys | Q28145775 | ||
| Orienting of attention | Q28282162 | ||
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| Orienting of attention and eye movements | Q29040437 | ||
| Executive frontal functions | Q33995910 | ||
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| Spatial covert attention increases contrast sensitivity across the CSF: support for signal enhancement | Q37302146 | ||
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| Square-wave jerks: A disorder of microsaccades? | Q48310975 | ||
| Frontal eye field neurons orthodromically activated from the superior colliculus. | Q48323416 | ||
| Microsaccades differentially modulate neural activity in the striate and extrastriate visual cortex | Q48324995 | ||
| Lateral inhibitory interactions in the intermediate layers of the monkey superior colliculus | Q48481966 | ||
| Comparison of the discharge characteristics of brain stem omnipause neurons and superior colliculus fixation neurons in monkey: implications for control of fixation and saccade behavior | Q48490113 | ||
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| The lateral intraparietal area as a salience map: the representation of abrupt onset, stimulus motion, and task relevance. | Q52168764 | ||
| Facilitation and inhibition arising from the exogenous orienting of covert attention depends on the temporal properties of spatial cues and targets. | Q52176095 | ||
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| Small saccades serve no useful purpose: reply to a letter by R. W. Ditchburn | Q71226926 | ||
| The role of microsaccades in high acuity observational tasks | Q71457369 | ||
| Voluntary control of microsaccades during maintained monocular fixation | Q72210307 | ||
| Microsaccades and the Velocity-Amplitude Relationship for Saccadic Eye Movements | Q72626673 | ||
| The characteristics of dynamic overshoots in square-wave jerks, and in congenital and manifest latent nystagmus | Q74228820 | ||
| Determination of the stimuli for involuntary drifts and saccadic eye movements | Q74257987 | ||
| Eye movements during fixation | Q76177187 | ||
| Stabilized images on the retina | Q78980762 | ||
| P433 | issue | 22 | |
| P921 | main subject | attention | Q6501338 |
| P304 | page(s) | 2533-2545 | |
| P577 | publication date | 2002-10-01 | |
| P1433 | published in | Vision Research | Q1307852 |
| P1476 | title | Microsaccades as an overt measure of covert attention shifts | |
| P478 | volume | 42 |
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| Q34211320 | An integrated model of fixational eye movements and microsaccades |
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| Q28298532 | Attention and awareness in stage magic: turning tricks into research |
| Q44528862 | Attention and scintillation |
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| Q37578477 | Dissociation between neural signatures of stimulus and choice in population activity of human V1 during perceptual decision-making. |
| Q30500965 | Distinctive features of saccadic intrusions and microsaccades in progressive supranuclear palsy |
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| Q37394286 | Event-related functional MRI of cortical activity evoked by microsaccades, small visually-guided saccades, and eyeblinks in human visual cortex |
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| Q30466293 | Eye movements: the past 25 years |
| Q36090327 | Fall prevention modulates decisional saccadic behavior in aging. |
| Q64092384 | Familiarity revealed by involuntary eye movements on the fringe of awareness |
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| Q28271268 | Fixational eye movements and perception |
| Q51987386 | Fixational eye movements are not an index of covert attention. |
| Q36607892 | Fixational eye movements in normal and pathological vision |
| Q51002377 | Fixational eye movements predict visual sensitivity. |
| Q48765300 | Fixational saccade-related activity of pedunculopontine tegmental nucleus neurons in behaving monkeys |
| Q52648774 | Fixational saccades alter the gap effect. |
| Q87068776 | Fixational saccades during grating detection and discrimination |
| Q39426555 | Fixational saccades reflect volitional action preparation. |
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| Q57899367 | Human Strategies for Multitasking, Search, and Control Improved via Real-Time Memory Aid for Gaze Location |
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| Q48445866 | Human microsaccade-related visual brain responses |
| Q45292841 | Individuals exhibit idiosyncratic eye-movement behavior profiles across tasks |
| Q37634682 | Informative Cues Facilitate Saccadic Localization in Blindsight Monkeys |
| Q51986793 | Inhibition of return in microsaccades. |
| Q36275057 | Interactions between target location and reward size modulate the rate of microsaccades in monkeys |
| Q41058999 | Looking for symmetry: fixational eye movements are biased by image mirror symmetry |
| Q37885422 | Mechanisms for generating and compensating for the smallest possible saccades |
| Q92668737 | Memory-guided microsaccades |
| Q48141828 | Micro and regular saccades across the lifespan during a visual search of "Where's Waldo" puzzles |
| Q44905430 | Microsaccade and drift dynamics reflect mental fatigue. |
| Q38938389 | Microsaccade direction reflects the economic value of potential saccade goals and predicts saccade choice |
| Q48436874 | Microsaccade directions do not predict directionality of illusory brightness changes of overlapping transparent surfaces |
| Q51931418 | Microsaccade directions do not predict directionality of illusory brightness changes of overlapping transparent surfaces. |
| Q52971708 | Microsaccade dynamics during covert attention. |
| Q91569045 | Microsaccade dynamics in the attentional repulsion effect |
| Q55354768 | Microsaccade-rhythmic modulation of neural synchronization and coding within and across cortical areas V1 and V2. |
| Q48252627 | Microsaccades Are Coupled to Heartbeat. |
| Q48330395 | Microsaccades and interest areas during free-viewing sport task |
| Q48394954 | Microsaccades and preparatory set: a comparison between delayed and immediate, exogenous and endogenous pro- and anti-saccades. |
| Q51987383 | Microsaccades are an index of covert attention: commentary on Horowitz, Fine, Fencsik, Yurgenson, and Wolfe (2007). |
| Q33822450 | Microsaccades are sensitive to word structure: A novel approach to study language processing |
| Q34598718 | Microsaccades are triggered by low retinal image slip |
| Q42362137 | Microsaccades during reading. |
| Q36607897 | Microsaccades: A microcosm for research on oculomotor control, attention, and visual perception |
| Q28256803 | Microsaccades: a neurophysiological analysis |
| Q28255149 | Microsaccades: small steps on a long way |
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| Q80820381 | Microsaccadic responses in a bimodal oddball task |
| Q36555536 | Model predictions of features in microsaccade-related neural responses in a feedforward network with short-term synaptic depression |
| Q36440513 | Modeling orienting behavior and its disorders with "ecological" neural networks |
| Q79972107 | Modelling the effect of microsaccades on retinal responses to stationary contrast patterns |
| Q35590233 | Modulation of microsaccades in monkey during a covert visual attention task. |
| Q48267365 | Modulation of saccadic intrusions by exogenous and endogenous attention |
| Q37675868 | Neuronal control of fixation and fixational eye movements. |
| Q58763440 | No supplementary evidence of attention to a spatial cue when saccadic facilitation is absent |
| Q37033449 | Ocular-motor profile and effects of memantine in a familial form of adult cerebellar ataxia with slow saccades and square wave saccadic intrusions |
| Q39014734 | Oculomotor behavior of blind patients seeing with a subretinal visual implant |
| Q41457786 | On computational modeling of visual saliency: Examining what's right, and what's left |
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| Q27311208 | Opposite effects of perceptual and working memory load on perceptual filling-in of an artificial scotoma |
| Q50455732 | Peripheral target identification performance modulates eye movements |
| Q46318520 | Postmicrosaccadic enhancement of slow eye movements. |
| Q36372716 | Precision of sustained fixation in trained and untrained observers |
| Q50437662 | Prestimulus Inhibition of Saccades in Adults With and Without Attention-Deficit/Hyperactivity Disorder as an Index of Temporal Expectations |
| Q86779900 | Probing perceptual performance after microsaccades |
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| Q92482067 | Rapid Ocular Responses Are Modulated by Bottom-up-Driven Auditory Salience |
| Q98216106 | Rapid stimulus-driven modulation of slow ocular position drifts |
| Q51910899 | Rare but precious: microsaccades are highly informative about attentional allocation. |
| Q52850406 | Revealing the time course of signals influencing the generation of secondary saccades using Aalen's additive hazards model. |
| Q38978213 | Revising the link between microsaccades and the spatial cueing of voluntary attention |
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| Q52974422 | Saccadic instabilities and voluntary saccadic behaviour. |
| Q48880745 | Secondary (micro-)saccades: the influence of primary saccade end point and target eccentricity on the process of postsaccadic fixation |
| Q48160025 | Sequential hemifield gating of α- and β-behavioral performance oscillations after microsaccades. |
| Q35902603 | Similarity of superior colliculus involvement in microsaccade and saccade generation |
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| Q46930356 | Spatial and temporal attention revealed by microsaccades. |
| Q34303228 | Spontaneous microsaccades reflect shifts in covert attention |
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| Q33668552 | Superior colliculus inactivation alters the relationship between covert visual attention and microsaccades |
| Q30659562 | Suppressive interactions underlying visually evoked fixational saccades |
| Q103002144 | Sustained spatial attention accounts for the direction bias of human microsaccades |
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| Q61448900 | Unilateral neglect post stroke: Eye movement frequencies indicate directional hypokinesia while fixation distributions suggest compensational mechanism |
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| Q36985347 | Variability and Correlations in Primary Visual Cortical Neurons Driven by Fixational Eye Movements. |
| Q36186992 | Visibility states modulate microsaccade rate and direction |
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| Q44194040 | What is the best fixation target? The effect of target shape on stability of fixational eye movements |
| Q44569292 | When do microsaccades follow spatial attention? |
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