Effects of attentional filtering demands on preparatory ERPs elicited in a spatial cueing task

OBJECTIVE We used ERP measures to investigate how attentional filtering requirements affect preparatory attentional control and spatially selective visual processing. METHODS In a spatial cueing experiment, attentional filtering demands were manipulated by presenting task-relevant visual stimuli either in isolation (target-only task) or together with irrelevant adjacent distractors (target-plus-distractors task). ERPs were recorded in response to informative spatial precues, and in response to subsequent visual stimuli at attended and unattended locations. RESULTS The preparatory ADAN component elicited during the cue-target interval was larger and more sustained in the target-plus-distractors task, reflecting the demand of stronger attentional filtering. By contrast, two other preparatory lateralised components (EDAN and LDAP) were unaffected by the attentional filtering demand. Similar enhancements of P1 and N1 components in response to the lateral imperative visual stimuli were observed at cued versus uncued locations, regardless of filtering demand, whereas later attentional-related negativities beyond 200 ms post-stimulus were larger the target-plus-distractor task. CONCLUSIONS Our results implicate that the ADAN component is linked to preparatory top-down control processes involved in the attentional filtering of irrelevant distractors; such filtering also affects later attention-related negativities recorded after the onset of the imperative stimulus. SIGNIFICANCE ERPs can reveal effects of expected attentional filtering of irrelevant distractors on preparatory attentional control processes and spatially selective visual processing.

[1]  J. Serences,et al.  Top-down control over biased competition during covert spatial orienting. , 2003, Journal of experimental psychology. Human perception and performance.

[2]  S. Yantis,et al.  Preparatory activity in visual cortex indexes distractor suppression during covert spatial orienting. , 2004, Journal of neurophysiology.

[3]  R. Verleger,et al.  Spatiotemporal overlap between brain activation related to saccade preparation and attentional orienting , 2006, Brain Research.

[4]  Martin Eimer,et al.  Dissociating effector and movement direction selection during the preparation of manual reaching movements: Evidence from lateralized ERP components , 2007, Clinical Neurophysiology.

[5]  M. Eimer,et al.  Covert manual response preparation triggers attentional modulations of visual but not auditory processing , 2006, Clinical Neurophysiology.

[6]  Martin Eimer,et al.  Covert manual response preparation triggers attentional shifts: ERP evidence for the premotor theory of attention , 2005, Neuropsychologia.

[7]  Peter Praamstra,et al.  Frontoparietal control of spatial attention and motor intention in human EEG. , 2005, Journal of neurophysiology.

[8]  M. Eimer “Sensory gating” as a mechanism for visuospatial orienting: Electrophysiological evidence from trial-by-trial cuing experiments , 1994, Perception & psychophysics.

[9]  G. Rizzolatti,et al.  Space and selective attention , 1994 .

[10]  M. Eimer,et al.  Do ERP components triggered during attentional orienting represent supramodal attentional control? , 2007, Psychophysiology.

[11]  S. Kobayashi,et al.  Electroencephalographic activity associated with shifts of visuospatial attention. , 1994, Brain : a journal of neurology.

[12]  Martin Eimer,et al.  Anterior and posterior attentional control systems use different spatial reference frames: ERP evidence from covert tactile-spatial orienting. , 2003, Psychophysiology.

[13]  M. Corbetta,et al.  Control of goal-directed and stimulus-driven attention in the brain , 2002, Nature Reviews Neuroscience.

[14]  Jon Driver,et al.  Cross-Modal Interactions between Audition, Touch, and Vision in Endogenous Spatial Attention: ERP Evidence on Preparatory States and Sensory Modulations , 2002, Journal of Cognitive Neuroscience.

[15]  Jon Driver,et al.  Shifts of attention in light and in darkness: an ERP study of supramodal attentional control and crossmodal links in spatial attention. , 2003, Brain research. Cognitive brain research.

[16]  Jon Driver,et al.  Attentional Preparation for a Lateralized Visual Distractor: Behavioral and fMRI Evidence , 2006, Journal of Cognitive Neuroscience.

[17]  S. Hillyard,et al.  Modulations of sensory-evoked brain potentials indicate changes in perceptual processing during visual-spatial priming. , 1991, Journal of experimental psychology. Human perception and performance.

[18]  Martin Eimer,et al.  Effects of hand posture on preparatory control processes and sensory modulations in tactile-spatial attention , 2004, Clinical Neurophysiology.

[19]  M. Eimer,et al.  Shifts of attention in the early blind: An ERP study of attentional control processes in the absence of visual spatial information , 2006, Neuropsychologia.

[20]  R. Eason Visual evoked potential correlates of early neural filtering during selective attention , 1981 .

[21]  Steven L. Miller,et al.  Neural Processes Involved in Directing Attention , 1989, Journal of Cognitive Neuroscience.

[22]  G. Mangun Neural mechanisms of visual selective attention. , 1995, Psychophysiology.

[23]  Martin Eimer,et al.  Manual response preparation and saccade programming are linked to attention shifts: ERP evidence for covert attentional orienting and spatially specific modulations of visual processing , 2006, Brain Research.

[24]  A. Nobre,et al.  The dynamics of shifting visuospatial attention revealed by event-related potentials , 2000, Neuropsychologia.

[25]  Martin Eimer,et al.  Early posterior ERP components do not reflect the control of attentional shifts toward expected peripheral events. , 2003, Psychophysiology.

[26]  G. R Mangun,et al.  Shifting visual attention in space: an electrophysiological analysis using high spatial resolution mapping , 2000, Clinical Neurophysiology.

[27]  F. Perrin,et al.  Spherical splines for scalp potential and current density mapping. , 1989, Electroencephalography and clinical neurophysiology.