| scholarly article | Q13442814 |
| P50 | author | Christof Koch | Q1084303 |
| Jorge Jovicich | Q37384998 | ||
| P2093 | author name string | Chang L | |
| Ernst T | |||
| Braun J | |||
| Peters RJ | |||
| P2860 | cites work | Parietal neglect and visual awareness. | Q33589388 |
| Visual attention: insights from brain imaging | Q33938402 | ||
| The primate premotor cortex: past, present, and preparatory | Q34195165 | ||
| Strategies and models of selective attention | Q34221661 | ||
| Modulating irrelevant motion perception by varying attentional load in an unrelated task | Q34446949 | ||
| Anterior cingulate cortex, error detection, and the online monitoring of performance | Q34465841 | ||
| Spatial attention affects brain activity in human primary visual cortex | Q35072335 | ||
| Frontoparietal cortical networks for directing attention and the eye to visual locations: identical, independent, or overlapping neural systems? | Q36050507 | ||
| Parametric analysis of fMRI data using linear systems methods. | Q36882945 | ||
| The functional anatomy of attention to visual motion. A functional MRI study | Q38839154 | ||
| Distributed modular architectures linking basal ganglia, cerebellum, and cerebral cortex: their role in planning and controlling action. | Q40450223 | ||
| Location and function of the human frontal eye-field: a selective review | Q40938349 | ||
| Reorienting attention across the horizontal and vertical meridians: evidence in favor of a premotor theory of attention | Q41456100 | ||
| The generality of parietal involvement in visual attention | Q41689795 | ||
| A direct quantitative relationship between the functional properties of human and macaque V5. | Q41742716 | ||
| Robust multimodality registration for brain mapping. | Q45988530 | ||
| Motion-responsive regions of the human brain | Q48116880 | ||
| Graded functional activation in the visuospatial system with the amount of task demand | Q48288692 | ||
| Characterizing stimulus-response functions using nonlinear regressors in parametric fMRI experiments | Q48394129 | ||
| The kinetic occipital (KO) region in man: an fMRI study. | Q48579123 | ||
| The kinetic occipital region in human visual cortex | Q48738547 | ||
| Voluntary attention modulates fMRI activity in human MT-MST. | Q48739381 | ||
| A parametric study of prefrontal cortex involvement in human working memory | Q48808924 | ||
| Attentional modulation of neural processing of shape, color, and velocity in humans | Q48949876 | ||
| How Many Subjects Constitute a Study? | Q57004102 | ||
| Spatial registration and normalization of images | Q57004421 | ||
| Area V5 of the Human Brain: Evidence from a Combined Study Using Positron Emission Tomography and Magnetic Resonance Imaging | Q57700772 | ||
| P433 | issue | 8 | |
| P921 | main subject | attention | Q6501338 |
| P304 | page(s) | 1048-1058 | |
| P577 | publication date | 2001-11-01 | |
| P1433 | published in | Journal of Cognitive Neuroscience | Q6294976 |
| P1476 | title | Brain areas specific for attentional load in a motion-tracking task | |
| P478 | volume | 13 |
| Q41845347 | A bilateral advantage for storage in visual working memory |
| Q44671469 | A higher order motion region in human inferior parietal lobule: evidence from fMRI. |
| Q36005710 | A relational structure of voluntary visual-attention abilities |
| Q38405019 | Abstract grammatical processing of nouns and verbs in Broca's area: evidence from fMRI. |
| Q39188072 | Age-related differences in brain network activation and co-activation during multiple object tracking |
| Q37349780 | Antiretroviral treatment is associated with increased attentional load-dependent brain activation in HIV patients |
| Q37349857 | Association between striatal dopamine D2/D3 receptors and brain activation during visual attention: effects of sleep deprivation |
| Q37254295 | Attention induced neural response trade-off in retinotopic cortex under load |
| Q48930460 | Attentional selection of moving objects by a serial process |
| Q35560112 | Attentional trade-offs maintain the tracking of moving objects across saccades |
| Q43093264 | Attentive Tracking Disrupts Feature Binding in Visual Working Memory |
| Q34257136 | Atypical functional brain activation during a multiple object tracking task in girls with Turner syndrome: neurocorrelates of reduced spatiotemporal resolution |
| Q35762474 | Behavioral dynamics and neural grounding of a dynamic field theory of multi-object tracking |
| Q35877384 | Brain Activation of Identity Switching in Multiple Identity Tracking Task |
| Q90746521 | Brain activity during time to contact estimation: an EEG study |
| Q44412092 | Can Limitations of Visuospatial Attention Be Circumvented? A Review |
| Q87948005 | Characterization of the hemodynamic response function across the majority of human cerebral cortex |
| Q37712599 | Cholinergic Potentiation Improves Perceptual-Cognitive Training of Healthy Young Adults in Three Dimensional Multiple Object Tracking |
| Q30494218 | Common deactivation patterns during working memory and visual attention tasks: an intra-subject fMRI study at 4 Tesla |
| Q44913936 | Configural processing of biological motion in human superior temporal sulcus. |
| Q48408050 | Cortical Circuit for Binding Object Identity and Location During Multiple-Object Tracking. |
| Q44796559 | Cortical mechanisms of smooth pursuit eye movements with target blanking. An fMRI study. |
| Q48477616 | Cortical response to task-relevant stimuli presented outside the primary focus of attention. |
| Q48240238 | Cross-Modal Attention Effects in the Vestibular Cortex during Attentive Tracking of Moving Objects. |
| Q37325321 | Declined neural efficiency in cognitively stable human immunodeficiency virus patients |
| Q35800510 | Delineating the neural signatures of tracking spatial position and working memory during attentive tracking |
| Q61811065 | Demonstrating Brain-Level Interactions Between Visuospatial Attentional Demands and Working Memory Load While Driving Using Functional Near-Infrared Spectroscopy |
| Q35982005 | Designing rehabilitation programs for neglect: could 2 be more than 1+1? |
| Q34080999 | Developmental profiles for multiple object tracking and spatial memory: typically developing preschoolers and people with Williams syndrome |
| Q30499431 | Different activation patterns for working memory load and visual attention load |
| Q42094394 | Direction information in multiple object tracking is limited by a graded resource |
| Q48763518 | Discrete object representation, attention switching, and task difficulty in the parietal lobe |
| Q30488704 | Dopamine transporters in striatum correlate with deactivation in the default mode network during visuospatial attention |
| Q33983343 | EEG correlates of attentional load during multiple object tracking |
| Q48529174 | EEG source imaging during two Qigong meditations |
| Q48712878 | Effects of attention and perceptual uncertainty on cerebellar activity during visual motion perception |
| Q30486545 | Effects of attention to auditory motion on cortical activations during smooth pursuit eye tracking |
| Q52532519 | Engagement of the motor system in position monitoring: reduced distractor suppression and effects of internal representation quality on motor kinematics. |
| Q41953203 | Enhancing multiple object tracking performance with noninvasive brain stimulation: a causal role for the anterior intraparietal sulcus |
| Q83390907 | Feature-based attention modulates direction-selective hemodynamic activity within human MT |
| Q33307474 | Flexible, capacity-limited activity of posterior parietal cortex in perceptual as well as visual short-term memory tasks |
| Q40132762 | Functional connectivity supporting the selective maintenance of feature-location binding in visual working memory |
| Q47829217 | How do we select multiple features? Transient costs for selecting two colors rather than one, persistent costs for color-location conjunctions. |
| Q64240516 | I See Your Effort: Force-Related BOLD Effects in an Extended Action Execution-Observation Network Involving the Cerebellum |
| Q37089885 | Impairment of attentional networks after 1 night of sleep deprivation |
| Q36208125 | Induced and Evoked Human Electrophysiological Correlates of Visual Working Memory Set-Size Effects at Encoding |
| Q57067507 | Influence of sports expertise level on attention in multiple object tracking |
| Q29012827 | Lightening the load: Perceptual load impairs visual detection in typical adults but not in autism. |
| Q43833687 | Load dependence of β and γ oscillations predicts individual capacity of visual attention |
| Q30440212 | Lower cognitive reserve in the aging human immunodeficiency virus-infected brain |
| Q48595167 | Marijuana use is associated with a reorganized visual-attention network and cerebellar hypoactivation |
| Q36636643 | Multiple object tracking in autism spectrum disorders |
| Q50615471 | Multiple-object tracking while driving: the multiple-vehicle tracking task. |
| Q34794934 | Neural activity changes associated with impulsive responding in the sustained attention to response task |
| Q37009697 | Neural basis for priming of pop-out during visual search revealed with fMRI. |
| Q48807109 | Neural correlates of the multiple-object tracking deficit in amblyopia |
| Q30391907 | Neural correlates of working memory training in HIV patients: study protocol for a randomized controlled trial |
| Q36943543 | Neural measures of individual differences in selecting and tracking multiple moving objects |
| Q37403702 | Prediction processes during multiple object tracking (MOT): involvement of dorsal and ventral premotor cortices |
| Q34797129 | Reading minds versus following rules: dissociating theory of mind and executive control in the brain |
| Q42137481 | Remapping attention in multiple object tracking |
| Q58779199 | Response of the multiple-demand network during simple stimulus discriminations |
| Q36789970 | Saccade landing point selection and the competition account of pro- and antisaccade generation: the involvement of visual attention--a review |
| Q38564469 | Selecting and tracking multiple objects |
| Q30496718 | Sex differences in sensory gating of the thalamus during auditory interference of visual attention tasks |
| Q33565559 | Shared processing in multiple object tracking and visual working memory in the absence of response order and task order confounds |
| Q50669949 | Spatial and visuospatial working memory tests predict performance in classic multiple-object tracking in young adults, but nonspatial measures of the executive do not. |
| Q48715402 | Spatio-temporal patterns of brain activity distinguish strategies of multiple-object tracking. |
| Q39353592 | Studying visual attention using the multiple object tracking paradigm: A tutorial review |
| Q45815082 | Sustained multifocal attentional enhancement of stimulus processing in early visual areas predicts tracking performance. |
| Q30496711 | Thalamo-cortical dysfunction in cocaine abusers: implications in attention and perception |
| Q35995608 | The Focus of Attention in Visual Working Memory: Protection of Focused Representations and Its Individual Variation. |
| Q36929724 | The attentive cerebellum - myth or reality? |
| Q34401709 | The coordinate systems used in visual tracking |
| Q48666508 | The effect of occlusion therapy on motion perception deficits in amblyopia. |
| Q64233484 | The neural correlations of spatial attention and working memory deficits in adults with ADHD |
| Q33854759 | The number of attentional foci and their precision are dissociated in the posterior parietal cortex |
| Q36690210 | Trace but not delay fear conditioning requires attention and the anterior cingulate cortex |
| Q46688128 | Tracking the changing features of multiple objects: progressively poorer perceptual precision and progressively greater perceptual lag. |
| Q48909216 | Tracking unique objects |
| Q31041827 | Unified structural equation modeling approach for the analysis of multisubject, multivariate functional MRI data |
| Q33642150 | Using fMRI to distinguish components of the multiple object tracking task |
| Q46006533 | Visually tracking and localizing expanding and contracting objects. |
| Q34091127 | Within-hemifield competition in early visual areas limits the ability to track multiple objects with attention |
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