scholarly article | Q13442814 |
P50 | author | Jennifer Coull | Q48549743 |
P2093 | author name string | Bruno Nazarian | |
Franck Vidal | |||
Francoise Macar | |||
P433 | issue | 5663 | |
P407 | language of work or name | English | Q1860 |
P921 | main subject | attention | Q6501338 |
P304 | page(s) | 1506-1508 | |
P577 | publication date | 2004-03-01 | |
P1433 | published in | Science | Q192864 |
P1476 | title | Functional anatomy of the attentional modulation of time estimation. | |
P478 | volume | 303 |
Q51915352 | A Cartesian reflex assessment of face processing. |
Q61800177 | A MEG Study on the Processing of Time and Quantity: Parietal Overlap but Functional Divergence |
Q57491527 | A Neuroeconomic Theory of Mental Time Travel |
Q37041140 | A Possible Link between Supra-Second Open-Ended Timing Sensitivity and Obsessive-Compulsive Tendencies |
Q30499727 | A heterogeneous population code for elapsed time in rat medial agranular cortex |
Q33893936 | A neural correlate of the processing of multi-second time intervals in primate prefrontal cortex |
Q31162000 | A new account of the neurocognitive foundations of impairments in space, time and number processing in children with chromosome 22q11.2 deletion syndrome |
Q49137656 | A representation of the hazard rate of elapsed time in macaque area LIP. |
Q90246615 | Abstract goal representation in visual search by neurons in the human pre-supplementary motor area |
Q30474681 | Accumulation of neural activity in the posterior insula encodes the passage of time |
Q35828268 | Acquisition of "Start" and "Stop" response thresholds in peak-interval timing is differentially sensitive to protein synthesis inhibition in the dorsal and ventral striatum |
Q48428822 | Active movement restores veridical event-timing after tactile adaptation |
Q92324011 | Adapting the flow of time with dopamine |
Q41127600 | Against the View that Consciousness and Attention are Fully Dissociable |
Q94561292 | Altered Time Awareness in Dementia |
Q30460740 | An FMRI study of the neural systems involved in visually cued auditory top-down spatial and temporal attention |
Q55359040 | An Intrinsic Role of Beta Oscillations in Memory for Time Estimation. |
Q39272384 | Anatomy of human sensory cortices reflects inter-individual variability in time estimation |
Q92297660 | Anxiety makes time pass quicker while fear has no effect |
Q30432210 | Attention and working memory: two basic mechanisms for constructing temporal experiences |
Q30467318 | Attention regulates the plasticity of multisensory timing |
Q35201954 | Auditory Stimulus Timing Influences Perceived duration of Co-Occurring Visual Stimuli |
Q30454839 | Automatic temporal expectancy: a high-density event-related potential study |
Q42810814 | Behavioral sensitivity of temporally modulated striatal neurons |
Q36651173 | Beyond Neglect: Preliminary Evidence of Retrospective Time Estimation Abnormalities in Non-Neglect Stroke and Transient Ischemic Attack Patients. |
Q48325774 | Brain responses to success and failure: Direct recordings from human cerebral cortex |
Q30448806 | Brain systems for probabilistic and dynamic prediction: computational specificity and integration. |
Q33995464 | Carving the clock at its component joints: neural bases for interval timing |
Q48358841 | Cerebro-cerebellar interactions underlying temporal information processing |
Q64067219 | Chronotopic maps in human supplementary motor area |
Q30483328 | Cognitive timing: neuropsychology and anatomic basis |
Q30565675 | Comparison of interval timing behaviour in mice following dorsal or ventral hippocampal lesions with mice having δ-opioid receptor gene deletion |
Q45849896 | Concurrency benefits in the attentional blink: attentional flexibility and shifts of decision criteria. |
Q50103942 | Consciousness: a unique way of processing information |
Q38830528 | Context-Dependent Neural Modulations in the Perception of Duration |
Q35064879 | Deciphering elapsed time and predicting action timing from neuronal population signals |
Q30418437 | Dedicated and intrinsic models of time perception |
Q47730742 | Deficits in temporal processing in mice prenatally exposed to Valproic Acid. |
Q35541553 | Degradation of cognitive timing mechanisms in behavioural variant frontotemporal dementia |
Q39517827 | Degree of handedness, emotion, and the perceived duration of auditory stimuli |
Q48696097 | Deriving angular displacement from optic flow: a fMRI study |
Q31131379 | Development of time sensitivity and information processing speed |
Q35742528 | Developmental Trajectories of Internally and Externally Driven Temporal Prediction |
Q35805035 | Developmental neuroscience of time and number: implications for autism and other neurodevelopmental disabilities |
Q45934991 | Dichotomy in perceptual learning of interval timing: calibration of mean accuracy and precision differ in specificity and time course. |
Q41023190 | Differential input of the supplementary motor area to a dedicated temporal processing network: functional and clinical implications |
Q34184664 | Dissociable connectivity within human angular gyrus and intraparietal sulcus: evidence from functional and structural connectivity |
Q58785815 | Distinct Dynamics of Striatal and Prefrontal Neural Activity During Temporal Discrimination |
Q28264752 | Distortions of subjective time perception within and across senses |
Q42516540 | Dopamine precursor depletion impairs timing in healthy volunteers by attenuating activity in putamen and supplementary motor area |
Q57145445 | Dopamine, time perception, and future time perspective |
Q42025447 | Effect of 5-HT2A and 5-HT2C receptors on temporal discrimination by mice |
Q46456139 | Effects of caffeine on prospective duration judgements of various intervals depend on task difficulty |
Q31026264 | Emotion effects on timing: attention versus pacemaker accounts |
Q47381380 | Emotional faces influence numerosity estimation without awareness |
Q38773176 | Emotional modulation of interval timing and time perception |
Q50591983 | Emotional time distortions: the fundamental role of arousal. |
Q39889174 | Encoding of temporal probabilities in the human brain. |
Q30386308 | Endogenous neuromagnetic activity for mental hierarchy of timing. |
Q41489268 | Endogenous temporal attention in the absence of stimulus-driven cues emerges in the second year of life |
Q33870771 | Engaging narratives evoke similar neural activity and lead to similar time perception. |
Q42086084 | Everywhere and everything: The power and ubiquity of time |
Q35067704 | Evidence accumulation in the magnitude system |
Q42115240 | Exploring the 4th dimension: hippocampus, time, and memory revisited |
Q28287471 | Facial expressions: what the mirror neuron system can and cannot tell us |
Q30480326 | Feature- and order-based timing representations in the frontal cortex |
Q89026074 | Flexible Sensorimotor Computations through Rapid Reconfiguration of Cortical Dynamics |
Q37709747 | Functional Connectivity of the Pedunculopontine Nucleus and Surrounding Region in Parkinson's Disease |
Q42366198 | Functional hemispheric asymmetries during the planning and manual control of virtual avatar movements. |
Q42597033 | Functional neural circuits for mental timekeeping |
Q37650231 | GABA predicts time perception |
Q48597403 | Hearing, feeling or seeing a beat recruits a supramodal network in the auditory dorsal stream |
Q91803259 | Hippocampal-striatal functional connectivity supports processing of temporal expectations from associative memory |
Q38001099 | How can a Bayesian approach inform neuroscience? |
Q86952054 | How noise contributes to time-scale invariance of interval timing |
Q30488823 | How voluntary actions modulate time perception |
Q24679730 | Impaired time perception and motor timing in stimulant-dependent subjects |
Q33457863 | Impulsiveness as a timing disturbance: neurocognitive abnormalities in attention-deficit hyperactivity disorder during temporal processes and normalization with methylphenidate |
Q37419259 | Inactivation of medial prefrontal cortex impairs time interval discrimination in rats. |
Q34519068 | Increased cerebral blood flow in the right frontal lobe area during sleep precedes self-awakening in humans |
Q39324470 | Individual alerting efficiency modulates time perception |
Q37599171 | Individual differences in the morphometry and activation of time perception networks are influenced by dopamine genotype |
Q36169050 | Influence of Temporal Expectations on Response Priming by Subliminal Faces |
Q37589293 | Interactions of timing and prediction error learning |
Q35649078 | Intersensory selective attention and temporal orienting operate in parallel and are instantiated in spatially distinct sensory and motor cortices |
Q48720177 | Interval time coding by neurons in the presupplementary and supplementary motor areas |
Q37196529 | Investigating the role of visual and auditory search in reading and developmental dyslexia. |
Q37832393 | It's about Time |
Q35534219 | Ketamine perturbs perception of the flow of time in healthy volunteers |
Q30398743 | Levels of attention and task difficulty in the modulation of interval duration mismatch negativity |
Q38682549 | Linguistic asymmetry, egocentric anchoring, and sensory modality as factors for the observed association between time and space perception. |
Q33569242 | Linking motor-related brain potentials and velocity profiles in multi-joint arm reaching movements. |
Q35753404 | Maintaining force control despite changes in emotional context engages dorsomedial prefrontal and premotor cortex |
Q47244296 | Making waves in the stream of consciousness: entraining oscillations in EEG alpha and fluctuations in visual awareness with rhythmic visual stimulation. |
Q30409802 | Measuring time with different neural chronometers during a synchronization-continuation task |
Q27305134 | Meta-Analysis of Functional Neuroimaging and Cognitive Control Studies in Schizophrenia: Preliminary Elucidation of a Core Dysfunctional Timing Network. |
Q58750525 | Metastable States of Multiscale Brain Networks Are Keys to Crack the Timing Problem |
Q36091182 | Microsurgical and Tractographic Anatomy of the Supplementary Motor Area Complex in Humans. |
Q38546261 | Midbrain dopamine neurons control judgment of time. |
Q30480548 | Minding time in an amodal representational space |
Q35689836 | Misremembering future intentions in methamphetamine-dependent individuals |
Q60040749 | Modality-independent role of the primary auditory cortex in time estimation |
Q35228534 | Modeling pharmacological clock and memory patterns of interval timing in a striatal beat-frequency model with realistic, noisy neurons |
Q49979474 | Modulation of neural circuits underlying temporal production by facial expressions of pain |
Q26865864 | Motivation and timing: clues for modeling the reward system |
Q58587080 | Motor Reproduction of Time Interval Depends on Internal Temporal Cues in the Brain: Sensorimotor Imagery in Rhythm |
Q30421498 | Motor commands induce time compression for tactile stimuli. |
Q30352301 | Music, emotion, and time perception: the influence of subjective emotional valence and arousal? |
Q61806995 | Neural Correlates of Interval Timing Deficits in Schizophrenia |
Q55292144 | Neural Mechanisms Underlying Time Perception and Reward Anticipation. |
Q41910410 | Neural Networks for Time Perception and Working Memory. |
Q34559571 | Neural bases for individual differences in the subjective experience of short durations (less than 2 seconds). |
Q36401389 | Neural correlates of time versus money in product evaluation |
Q30454490 | Neural dynamics of attentional cross-modality control |
Q30475258 | Neural modulation of temporal encoding, maintenance, and decision processes |
Q48913559 | Neural network involved in time perception: an fMRI study comparing long and short interval estimation |
Q37504270 | Neural networks engaged in milliseconds and seconds time processing: evidence from transcranial magnetic stimulation and patients with cortical or subcortical dysfunction |
Q37592376 | Neural pattern change during encoding of a narrative predicts retrospective duration estimates. |
Q30491625 | Neural representation of time in cortico-basal ganglia circuits |
Q30474550 | Neural responses to complex auditory rhythms: the role of attending |
Q34048927 | Neural substrates of impaired sensorimotor timing in adult attention-deficit/hyperactivity disorder |
Q35138176 | Neural underpinnings of distortions in the experience of time across senses |
Q24602685 | Neuroanatomical and neurochemical substrates of timing |
Q28082136 | Neuronal oscillations as a mechanistic substrate of auditory temporal prediction |
Q48535094 | Neurophysiology of implicit timing in serial choice reaction-time performance. |
Q59297131 | Neuroscientific Investigations of Musical Rhythm: Recent Advances and Future Challenges |
Q48249574 | Olfaction Warps Visual Time Perception |
Q48144982 | Orienting attention in time activates left intraparietal sulcus for both perceptual and motor task goals. |
Q30831046 | Oxytocin enhances inter-brain synchrony during social coordination in male adults |
Q33958392 | Parallel effects of memory set activation and search on timing and working memory capacity |
Q36378946 | Pathophysiological distortions in time perception and timed performance. |
Q36990624 | Perceived visual time depends on motor preparation and direction of hand movements |
Q27303850 | Perceiving Time Differences When You Should Not: Applying the El Greco Fallacy to Hypnotic Time Distortions |
Q26851481 | Perceiving the passage of time: neural possibilities |
Q36628077 | Perception of the duration of emotional faces in schizophrenic patients |
Q47820223 | Perceptual asymmetries in a time estimation task with emotional sounds |
Q51988156 | Performance of children with attention deficit hyperactivity disorder (ADHD) on a test battery of impulsiveness. |
Q89171708 | Performance-informed EEG analysis reveals mixed evidence for EEG signatures unique to the processing of time |
Q44636401 | Phase resetting and its implications for interval timing with intruders |
Q48274564 | Predicting and memorizing observed action: differential premotor cortex involvement |
Q28080765 | Predictive motor control of sensory dynamics in auditory active sensing |
Q55252125 | Predictive timing disturbance is a precise marker of schizophrenia. |
Q51970998 | Preparatory activity in occipital cortex in early blind humans predicts auditory perceptual performance. |
Q42177728 | Probabilistic model of onset detection explains paradoxes in human time perception. |
Q48567052 | Processing the spatial configuration of complex actions involves right posterior parietal cortex: An fMRI study with clinical implications |
Q35094746 | Pulsed out of awareness: EEG alpha oscillations represent a pulsed-inhibition of ongoing cortical processing. |
Q52599711 | Real-Time Prediction of Observed Action Requires Integrity of the Dorsal Premotor Cortex: Evidence From Repetitive Transcranial Magnetic Stimulation. |
Q34685561 | Reducing bias in auditory duration reproduction by integrating the reproduced signal |
Q37201151 | Relative time sharing: new findings and an extension of the resource allocation model of temporal processing. |
Q59103175 | Right Dorsolateral Prefrontal Cortex Activation during a Time Production Task: A Functional Near-Infrared Spectroscopy Study |
Q58783374 | Robustness of individual differences in temporal interference effects |
Q50719249 | SMA Selectively Codes the Active Accumulation of Temporal, Not Spatial, Magnitude. |
Q51618893 | Sensory acquisition in the cerebellum: an FMRI study of cerebrocerebellar interaction during visual duration discrimination. |
Q42164525 | Sensory-guided motor tasks benefit from mental training based on serial prediction |
Q37273277 | Separate representations of target and timing cue locations in the supplementary eye fields |
Q30427074 | Serotonergic hallucinogens as translational models relevant to schizophrenia |
Q34151328 | Size isn’t all that matters: noticing differences in size and temporal order |
Q39181682 | Sleep-dependent consolidation benefits fast transfer of time interval training. |
Q38387277 | Slow potentials in time estimation: the role of temporal accumulation and habituation |
Q92640862 | Spatial Cues Influence Time Estimations in Deaf Individuals |
Q51956273 | Spatial and temporal acuity of visual perception can be enhanced selectively by attentional set. |
Q57171860 | State-change decisions and dorsomedial prefrontal cortex: the importance of time |
Q37173815 | Studies on time: a proposal on how to get out of circularity |
Q30381464 | Subsecond timing in primates: comparison of interval production between human subjects and rhesus monkeys |
Q42519710 | Supplementary motor area and presupplementary motor area: targets of basal ganglia and cerebellar output. |
Q96685974 | Sustaining temporal attention prevents habit expression during operant learning in rats |
Q30458172 | Switch attention to listen. |
Q46026644 | Tactile temporal processing in the auditory cortex. |
Q30408559 | Temporal and Motor Representation of Rhythm in Fronto-Parietal Cortical Areas: An fMRI Study |
Q35302218 | Temporal discrimination of sub- and suprasecond time intervals: a voxel-based lesion mapping analysis |
Q45396106 | Temporal orienting of attention: An fNIRS study on the illusion of "a watched pot never boils". |
Q30434564 | Temporal processing in schizophrenia: effects of task-difficulty on behavioral discrimination and neuronal responses |
Q60923273 | The BOLD response in primary motor cortex and supplementary motor area during kinesthetic motor imagery based graded fMRI neurofeedback |
Q30390576 | The Clock'N Test as a Possible Measure of Emotions: Normative Data Collected on a Non-clinical Population |
Q41909171 | The SMAs: Neural Substrate of the Temporal Accumulator? |
Q91814150 | The Strength of Alpha-Beta Oscillatory Coupling Predicts Motor Timing Precision |
Q34795695 | The attention modulation on timing: an event-related potential study |
Q80786236 | The cerebellum predicts the timing of perceptual events |
Q47568535 | The common rate control account of prediction motion |
Q47629433 | The dopaminergic system dynamic in the time perception: a review of the evidence. |
Q34093586 | The duration of disgusted and fearful faces is judged longer and shorter than that of neutral faces: the attention-related time distortions as revealed by behavioral and electrophysiological measurements |
Q55035318 | The effect of attention and working memory on the estimation of elapsed time. |
Q36903069 | The functional role of time compression |
Q30480549 | The inner experience of time |
Q43935189 | The neural circuitry of pre-attentive auditory change-detection: an fMRI study of pitch and duration mismatch negativity generators |
Q27324740 | The neuromagnetic dynamics of time perception |
Q37504250 | The parietal cortex and the representation of time, space, number and other magnitudes |
Q37800368 | The posterior parietal cortex and non-spatial cognition |
Q39775165 | The role of cortical beta oscillations in time estimation |
Q30494139 | The role of superior temporal cortex in auditory timing |
Q37111437 | The role of the pre-supplementary motor area in the control of action |
Q42857782 | The sensory representation of time |
Q48549674 | The supplementary motor area in motor and perceptual time processing: fMRI studies |
Q37201138 | The time-emotion paradox |
Q48398343 | Three stages and four neural systems in time estimation. |
Q36072703 | Time Adaptation Shows Duration Selectivity in the Human Parietal Cortex |
Q26748981 | Time Perception Mechanisms at Central Nervous System |
Q34600445 | Time and decision making: differential contribution of the posterior insular cortex and the striatum during a delay discounting task |
Q35480295 | Time and number: the privileged status of small values in the brain |
Q21558406 | Time dysperception perspective for acquired brain injury |
Q44066123 | Time flies when we view a sport action. |
Q51018660 | Time is more than a sensory feature: Attending to duration triggers specific anticipatory activity. |
Q50647004 | Time perception in response to ashamed faces in children and adults. |
Q33308722 | Time processing in Huntington's disease: a group-control study |
Q37521385 | Time to Move Again: Does the Bereitschaftspotential Covary with Demands on Internal Timing? |
Q51946176 | Time, number and length: similarities and differences in discrimination in adults and children. |
Q26999735 | Time-scale invariance as an emergent property in a perceptron with realistic, noisy neurons |
Q37623038 | Timing and anticipation: conceptual and methodological approaches. |
Q36722201 | Timing and executive function: bidirectional interference between concurrent temporal production and randomization tasks |
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Q51957963 | Timing, storage, and comparison of stimulus duration engage discrete anatomical components of a perceptual timing network. |
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Q30378757 | Tuning-in to the beat: Aesthetic appreciation of musical rhythms correlates with a premotor activity boost. |
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Q30484211 | Using time-to-contact information to assess potential collision modulates both visual and temporal prediction networks. |
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Q50628759 | Working memory modulates the association between time and number representation. |
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