| review article | Q7318358 |
| scholarly article | Q13442814 |
| P50 | author | Julien Dubois | Q57023885 |
| P2093 | author name string | N A Busch | |
| J Drewes | |||
| R Vanrullen | |||
| P2860 | cites work | The wagon wheel illusion in movies and reality | Q24568294 |
| Evidence against the temporal subsampling account of illusory motion reversal | Q24634250 | ||
| To see or not to see: prestimulus alpha phase predicts visual awareness | Q24653905 | ||
| Temporal binding and the neural correlates of sensory awareness | Q28143658 | ||
| Oscillatory gamma activity in humans and its role in object representation | Q28143833 | ||
| The role of working memory in visual selective attention | Q28161576 | ||
| The brainweb: phase synchronization and large-scale integration | Q28210063 | ||
| The magical number 4 in short-term memory: a reconsideration of mental storage capacity | Q28213950 | ||
| Theta oscillations in the hippocampus | Q28217796 | ||
| The capacity of visual short-term memory is set both by visual information load and by number of objects | Q28240108 | ||
| The phase of ongoing EEG oscillations predicts visual perception | Q28248905 | ||
| On the role of frontal eye field in guiding attention and saccades | Q28254887 | ||
| High-Speed Scanning in Human Memory | Q28257618 | ||
| Prestimulus oscillatory activity in the alpha band predicts visual discrimination ability | Q28269318 | ||
| Human memory strength is predicted by theta-frequency phase-locking of single neurons | Q28277681 | ||
| Saccade target selection and object recognition: evidence for a common attentional mechanism | Q28287057 | ||
| The gamma cycle | Q28305488 | ||
| Phase-of-Firing Coding of Natural Visual Stimuli in Primary Visual Cortex | Q29042219 | ||
| EEG alpha and theta oscillations reflect cognitive and memory performance: a review and analysis | Q29619431 | ||
| The leading sense: supramodal control of neurophysiological context by attention | Q30478965 | ||
| The blinking spotlight of attention. | Q30480884 | ||
| Combining TMS and EEG to study cognitive function and cortico-cortico interactions | Q30485216 | ||
| Attention-driven discrete sampling of motion perception | Q30856838 | ||
| Spontaneous EEG oscillations reveal periodic sampling of visual attention | Q34136582 | ||
| Saccadic eye movements after extremely short reaction times in the monkey | Q34259041 | ||
| Low-frequency neuronal oscillations as instruments of sensory selection | Q34345912 | ||
| Illusory motion reversal is caused by rivalry, not by perceptual snapshots of the visual field | Q34347068 | ||
| Phase relationship between hippocampal place units and the EEG theta rhythm | Q34353002 | ||
| Statistical analysis of membrane potential fluctuations. Relation with presynaptic spike train | Q34355545 | ||
| Theta phase precession in hippocampal neuronal populations and the compression of temporal sequences | Q34396061 | ||
| The capacity of visual working memory for features and conjunctions | Q34447907 | ||
| Control of eye movements and spatial attention | Q34659730 | ||
| Human cortical mechanisms of visual attention during orienting and search | Q35212129 | ||
| Spatial attention changes excitability of human visual cortex to direct stimulation | Q35669595 | ||
| Dissociations in hippocampal and frontal contributions to episodic memory performance | Q35750403 | ||
| Spike times make sense | Q35996895 | ||
| The wagon-wheel illusion in continuous light | Q36145191 | ||
| The role of working memory representations in the control of attention | Q36168590 | ||
| Interactions between attention and working memory. | Q36329415 | ||
| New insights into rhythmic brain activity from TMS-EEG studies | Q37414984 | ||
| Phase-dependent neuronal coding of objects in short-term memory. | Q37426973 | ||
| Dissociation of spatial attention and saccade preparation | Q37593400 | ||
| Is perception discrete or continuous? | Q39220273 | ||
| Excitability cycles and cortical scanning: a review of two hypotheses of central intermittency in perception | Q39963816 | ||
| Alpha-band electroencephalographic activity over occipital cortex indexes visuospatial attention bias and predicts visual target detection. | Q40288636 | ||
| Hippocampus, theta, and spatial memory | Q40722747 | ||
| Reorienting attention across the horizontal and vertical meridians: evidence in favor of a premotor theory of attention | Q41456100 | ||
| Phenomenal simutaneity and the perceptual moment hypothesis | Q41524519 | ||
| Functional anatomy of long-term memory | Q41615951 | ||
| Methodology for combined TMS and EEG. | Q42944952 | ||
| The pairwise phase consistency: a bias-free measure of rhythmic neuronal synchronization. | Q43180156 | ||
| The effect of the phase of prestimulus alpha activity on the averaged visual evoked response | Q43459359 | ||
| Interplay of Electroencephalogram Phase and Auditory-Evoked Neural Activity | Q44898637 | ||
| This is the rhythm of your eyes: the phase of ongoing electroencephalogram oscillations modulates saccadic reaction time. | Q45011835 | ||
| A new device and protocol for combining TMS and online recordings of EEG and evoked potentials | Q45231560 | ||
| Prefrontal phase locking to hippocampal theta oscillations. | Q45933452 | ||
| A quantitative assessment of the dependency of the visual temporal frame upon the cortical rhythm | Q48140726 | ||
| Gamma-phase shifting in awake monkey visual cortex. | Q48331037 | ||
| Integrating TMS with EEG: How and what for? | Q48360476 | ||
| The functional neuroanatomy of episodic memory: the role of the frontal lobes, the hippocampal formation, and other areas | Q48394096 | ||
| Neuronal activity in the frontal eye field of the monkey is modulated while attention is focused on to a stimulus in the peripheral visual field, irrespective of eye movement | Q48647532 | ||
| Visual and auditory evoked phase resetting of the alpha EEG. | Q48694164 | ||
| Dynamic dissociation of visual selection from saccade programming in frontal eye field | Q48718776 | ||
| Spontaneous subthreshold membrane potential fluctuations and action potential variability of rat corticostriatal and striatal neurons in vivo | Q48744222 | ||
| Phase precession of medial prefrontal cortical activity relative to the hippocampal theta rhythm. | Q48783037 | ||
| Rapid feature selective neuronal synchronization through correlated latency shifting | Q49030908 | ||
| PHASE OF ALPHA BRAIN WAVES, REACTION TIME AND VISUALLY EVOKED POTENTIALS. | Q51253405 | ||
| Relation of brain and tremor rhythms to visual reaction time. | Q51325452 | ||
| Entrainment of neuronal oscillations as a mechanism of attentional selection. | Q51960477 | ||
| Interactions between the orbitofrontal cortex and the hippocampal memory system during the storage of long-term memory. | Q51971500 | ||
| Visual discrimination performance is related to decreased alpha amplitude but increased phase locking. | Q51995006 | ||
| The speed of visual attention: what time is it? | Q51997466 | ||
| Visual search remains efficient when visual working memory is full. | Q52018901 | ||
| Overlapping mechanisms of attention and spatial working memory. | Q52021145 | ||
| Exogenous orienting of attention depends upon the ability to execute eye movements. | Q52089821 | ||
| Interactions between visual working memory and selective attention. | Q52139851 | ||
| Relationship between reaction time and electroencephalographic alpha phase. | Q52142566 | ||
| The role of spatial selective attention in working memory for locations: evidence from event-related potentials. | Q52163603 | ||
| Neuroanatomic overlap of working memory and spatial attention networks: a functional MRI comparison within subjects. | Q52172445 | ||
| Storage of 7 +/- 2 short-term memories in oscillatory subcycles. | Q52209502 | ||
| Measuring phase synchrony in brain signals. | Q52893925 | ||
| Human express saccades: extremely short reaction times of goal directed eye movements | Q56096160 | ||
| The Continuous Wagon Wheel Illusion Is Associated with Changes in Electroencephalogram Power at 13 Hz | Q56902894 | ||
| Rescuing stimuli from invisibility: Inducing a momentary release from visual masking with pre-target entrainment | Q61772051 | ||
| Perceptual framing and cortical alpha rhythm | Q71013039 | ||
| The frontal eye field and attention | Q71717009 | ||
| Synaptic noise as a source of variability in the interval between action potentials | Q72204227 | ||
| Visual reaction time and the alpha-rhythm, an investigation of a scanning hypothesis | Q73068434 | ||
| Alpha rhythm of the EEG modulates visual detection performance in humans | Q80370214 | ||
| Prestimulus oscillations predict visual perception performance between and within subjects | Q80812243 | ||
| Illusory motion reversal in tune with motion detectors | Q81445542 | ||
| Contribution of the monkey frontal eye field to covert visual attention | Q83177393 | ||
| How we know universals; the perception of auditory and visual forms | Q83262297 | ||
| P407 | language of work or name | English | Q1860 |
| P921 | main subject | attention | Q6501338 |
| P304 | page(s) | 60 | |
| P577 | publication date | 2011-04-09 | |
| P1433 | published in | Frontiers in Psychology | Q2794477 |
| P1476 | title | Ongoing EEG Phase as a Trial-by-Trial Predictor of Perceptual and Attentional Variability | |
| P478 | volume | 2 |
| Q48394576 | A precluding but not ensuring role of entrained low-frequency oscillations for auditory perception |
| Q38065926 | A precluding role of low-frequency oscillations for auditory perception in a continuous processing mode |
| Q38199888 | Analytical methods and experimental approaches for electrophysiological studies of brain oscillations |
| Q37384801 | Anticipatory alpha phase influences visual working memory performance |
| Q42429877 | Attention Reorients Periodically |
| Q90372052 | Attention strengthens across-trial pre-stimulus phase coherence in visual cortex, enhancing stimulus processing |
| Q36120383 | Beta oscillations define discrete perceptual cycles in the somatosensory domain. |
| Q30842599 | Beyond the Peak - Tactile Temporal Discrimination Does Not Correlate with Individual Peak Frequencies in Somatosensory Cortex. |
| Q48281315 | Characterizing the roles of alpha and theta oscillations in multisensory attention. |
| Q49031186 | Classification of imperfectly time-locked image RSVP events with EEG device |
| Q30519462 | Conscious updating is a rhythmic process. |
| Q37270418 | Consciousness in humans and non-human animals: recent advances and future directions |
| Q30559921 | Cortical brain states and corticospinal synchronization influence TMS-evoked motor potentials. |
| Q52691449 | Decoding English Alphabet Letters Using EEG Phase Information. |
| Q36254604 | Dense sampling reveals behavioral oscillations in rapid visual categorization. |
| Q30454320 | Detection of Near-Threshold Sounds is Independent of EEG Phase in Common Frequency Bands |
| Q37335070 | Differential Visual Processing of Animal Images, with and without Conscious Awareness |
| Q52688895 | Disruption in neural phase synchrony is related to identification of inattentional deafness in real-world setting. |
| Q87057215 | Does illusory flickering result from rhythmic sampling of visual stimuli? |
| Q92131829 | Double Flash Illusions: Current Findings and Future Directions |
| Q36736911 | Dynamic interactions between large-scale brain networks predict behavioral adaptation after perceptual errors |
| Q38403272 | EEG phase patterns reflect the representation of semantic categories of objects. |
| Q88490191 | Endogenously generated gamma-band oscillations in early visual cortex: A neurofeedback study |
| Q30414364 | Entrained neural oscillations in multiple frequency bands comodulate behavior. |
| Q35121061 | Entrainment of neural oscillations as a modifiable substrate of attention |
| Q37910750 | Entrainment of perceptually relevant brain oscillations by non-invasive rhythmic stimulation of the human brain |
| Q30453859 | Frequency modulation entrains slow neural oscillations and optimizes human listening behavior |
| Q35651521 | Gamma activity coupled to alpha phase as a mechanism for top-down controlled gating |
| Q37253526 | How to Evaluate Phase Differences between Trial Groups in Ongoing Electrophysiological Signals |
| Q93198157 | How to test for phasic modulation of neural and behavioural responses |
| Q34606911 | Is transcranial alternating current stimulation effective in modulating brain oscillations? |
| Q37279379 | Long-range neural synchronization supports fast and efficient reading: EEG correlates of processing expected words in sentences. |
| Q36179248 | Modeling the effect of locus coeruleus firing on cortical state dynamics and single-trial sensory processing |
| Q60949974 | Neural Oscillations and the Initiation of Voluntary Movement |
| Q42020159 | Neural variability, or lack thereof |
| Q54943722 | On the Physiological Modulation and Potential Mechanisms Underlying Parieto-Occipital Alpha Oscillations. |
| Q30412723 | On the cyclic nature of perception in vision versus audition |
| Q42287915 | Phase-Dependent Modulation of Signal Transmission in Cortical Networks through tACS-Induced Neural Oscillations. |
| Q48336920 | Power and Phase of Alpha Oscillations Reveal an Interaction between Spatial and Temporal Visual Attention |
| Q46102050 | Pre-stimulus pupil dilation and the preparatory control of attention |
| Q47103237 | Prestimulus EEG Power Predicts Conscious Awareness But Not Objective Visual Performance. |
| Q30383921 | Prestimulus influences on auditory perception from sensory representations and decision processes. |
| Q92728893 | Probing cortical excitability using rapid frequency tagging |
| Q35094746 | Pulsed out of awareness: EEG alpha oscillations represent a pulsed-inhibition of ongoing cortical processing. |
| Q30446338 | Retinal and post-retinal contributions to the quantum efficiency of the human eye revealed by electrical neuroimaging |
| Q53203525 | Rhythmic Influence of Top-Down Perceptual Priors in the Phase of Prestimulus Occipital Alpha Oscillations. |
| Q30410985 | Rhythmic auditory cortex activity at multiple timescales shapes stimulus-response gain and background firing |
| Q34440847 | Saccadic reaction times to audiovisual stimuli show effects of oscillatory phase reset. |
| Q55668972 | Single neurons may encode simultaneous stimuli by switching between activity patterns. |
| Q38979490 | Single-trial analyses: why bother? |
| Q92001300 | Spatial neuronal synchronization and the waveform of oscillations: Implications for EEG and MEG |
| Q42107777 | Spike Pattern Structure Influences Synaptic Efficacy Variability under STDP and Synaptic Homeostasis. II: Spike Shuffling Methods on LIF Networks |
| Q36460720 | Statistical Frequency-Dependent Analysis of Trial-to-Trial Variability in Single Time Series by Recurrence Plots |
| Q30445388 | Stimulus phase locking of cortical oscillation for auditory stream segregation in rats |
| Q37258614 | Temporal metastates are associated with differential patterns of time-resolved connectivity, network topology, and attention |
| Q36437740 | The Effect of Distance on Moral Engagement: Event Related Potentials and Alpha Power are Sensitive to Perspective in a Virtual Shooting Task |
| Q92402496 | The Potential of Trial-by-Trial Variabilities of Ongoing-EEG, Evoked Potentials, Event Related Potentials and fMRI as Diagnostic Markers for Neuropsychiatric Disorders |
| Q27341762 | The Temporal Signature of Memories: Identification of a General Mechanism for Dynamic Memory Replay in Humans |
| Q48199247 | The Triple-Flash Illusion Reveals a Driving Role of Alpha-Band Reverberations in Visual Perception. |
| Q52139070 | The accessory stimulus effect is mediated by phasic arousal: A pupillometry study. |
| Q33763554 | The analytic bilinear discrimination of single-trial EEG signals in rapid image triage |
| Q34707153 | The importance of ignoring: Alpha oscillations protect selectivity |
| Q28596441 | The phase of ongoing EEG oscillations predicts the amplitude of peri-saccadic mislocalization |
| Q37929576 | The psychophysics of brain rhythms |
| Q37681694 | The rhythms of predictive coding? Pre-stimulus phase modulates the influence of shape perception on luminance judgments |
| Q37697621 | The role of alpha-rhythm states in perceptual learning: insights from experiments and computational models. |
| Q58798975 | Theta Rhythmic Neuronal Activity and Reaction Times Arising from Cortical Receptive Field Interactions during Distributed Attention |
| Q48458586 | Theta oscillations modulate attentional search performance periodically |
| Q36077862 | Time for Awareness: The Influence of Temporal Properties of the Mask on Continuous Flash Suppression Effectiveness |
| Q36362966 | Top-down control of cortical gamma-band communication via pulvinar induced phase shifts in the alpha rhythm |
| Q37721265 | Transcranial Magnetic Stimulation Reveals Intrinsic Perceptual and Attentional Rhythms. |
| Q37325862 | Transcranial alternating current stimulation affects the BOLD signal in a frequency and task-dependent manner |
| Q60679762 | Transcranial alternating current stimulation at 10 Hz modulates response bias in the Somatic Signal Detection Task |
| Q48099278 | Trial-by-trial co-variation of pre-stimulus EEG alpha power and visuospatial bias reflects a mixture of stochastic and deterministic effects. |
| Q41823134 | What goes up must come down: EEG phase modulates auditory perception in both directions |
| Q30425848 | α oscillations related to anticipatory attention follow temporal expectations. |
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