Auditory stimulus intensity effects on components of the late positive complex

Prominent theories of attention claim that visual search is guided through attentional templates stored in working memory. Recently, the contralateral delay activity (CDA), an electrophysiological index of working memory storage, has been found to rapidly decrease when participants repeatedly search for the same target, suggesting that, with learning, the template moves out of working memory. However, this has only been investigated with pop-out search for distinct targets, for which a strong attentional template may not be necessary. More effortful search tasks might rely more on an active attentional template in working memory, leading to a slower handoff to long-term memory and thus a slower decline of the CDA. Using ERPs, we compared the rate of learning of attentional templates in pop-out and effortful search tasks. In two experiments, the rate of decrease in the CDA was the same for both search tasks. Similar results were found for a second component indexing working memory effort, the late positive complex. However, the late positive complex was also sensitive to anticipated search difficulty, as was expressed in a greater amplitude before the harder search task. We conclude that the amount of working memory effort invested in maintaining an attentional template, but not the rate of learning, depends on search difficulty.

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Disinhibition and the processing of auditory stimulus intensity: An ERP-study

Personality and Individual Differences ◽

10.1016/0191-8869(89)90008-1 ◽

1989 ◽

Vol 10 (4) ◽

pp. 445-451 ◽

Cited By ~ 30

Author(s):

J.F. Orlebeke ◽

A. Kok ◽

C.W. Zeillemaker

Keyword(s):

Auditory Stimulus ◽

Stimulus Intensity

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Event-related Potential Signatures of Relational Memory

Journal of Cognitive Neuroscience ◽

10.1162/jocn.2006.18.11.1863 ◽

2006 ◽

Vol 18 (11) ◽

pp. 1863-1876 ◽

Cited By ~ 20

Author(s):

Deborah E. Hannula ◽

Kara D. Federmeier ◽

Neal J. Cohen

Keyword(s):

Eye Movement ◽

Memory Effects ◽

Event Related Potential ◽

Movement Behavior ◽

Sequential Presentation ◽

Relational Memory ◽

Early Processing ◽

Late Positive Complex ◽

Positive Complex ◽

Lines Of Evidence

Various lines of evidence suggest that memory for the relations among arbitrarily paired items acquired prior to testing can influence early processing of a probe stimulus. The event-related potential experiment reported here was designed to explore how early in time memory for a previously established face-scene relationship begins to influence processing of faces, under sequential presentation conditions in which a preview of the scene can promote expectancies about the to-be-presented face. Prior to the current work, the earliest component documented to be sensitive to memory for the relations among arbitrarily paired items was the late positive complex (LPC), but here relational memory effects were evident as early as 270–350 msec after face onset. The latency of these relational memory effects suggests that they may be the precursor to similar effects observed in eye movement behavior. As expected, LPC amplitude was also affected by memory for face-scene relationships, and N400 amplitude reflected some combination of memory for items and memory for the relations among items.

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Responses to Loud Acoustic Stimuli: Short and Long Timescale Effects on Cortical and Sub-Cortical Preparation Reflect Conditional Probability

10.1101/2020.08.19.258327 ◽

2020 ◽

Author(s):

An T. Nguyen ◽

James R. Tresilian ◽

Ottmar V. Lipp ◽

Dayse Tavora-Vieira ◽

Welber Marinovic

Keyword(s):

Conditional Probability ◽

Auditory Stimulus ◽

Stimulus Intensity ◽

Cortical Excitability ◽

Movement Preparation ◽

Movement Onset ◽

Eeg Activity ◽

Motor Responses ◽

Acoustic Stimuli ◽

Startreact Effect

AbstractLoud acoustic stimuli (LAS) can trigger prepared motor responses at very short latencies: the StartReact effect. In this study, we tested the proposal that responses to LAS in the StartReact effect could be explained by stimulus intensity effects combined with movement-related preparation changes on nervous system excitability. Using a simple auditory reaction time task, we induced different levels of preparation by systematically manipulating the conditional probability and temporal location of the auditory stimulus (LAS or non-intense tone). We then examined how preparation-levels influenced motor responses to LAS and non-intense tones, as well as cortical and sub-cortical excitability — reflected by electroencephalographic (EEG) activity before the onset of the auditory stimulus, and the eye-blink startle reflex.On both tone and LAS trials, higher preparation conditions were accompanied with reductions in movement onset time, increased force, as well as enhanced cortical (in auditory and motor areas) and sub-cortical excitability. At the trial-level, we found that enhanced pre-stimulus EEG activity in sensory and motor areas was associated with earlier movement onset on tone trials, and shorter blink onset latencies were associated with earlier movement onset on LAS trials. The results show that movement preparation is associated with wide-spread changes in cortical and sub-cortical excitability, and that movement preparation (combined with stimulus-intensity effects) plays a critical role in shaping responses to both non-intense tones and LAS.

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