Selective Modulation of Auditory Cortical Alpha Activity in an Audiovisual Spatial Attention Task

Frey, Julia; Mainy, Nelly; Lachaux, Jean Philippe; Müller, Nicolai; Bertrand, Olivier; Weisz, Nathan

doi:10.1523/jneurosci.4813-13.2014

Cited by 110 publications

(129 citation statements)

References 48 publications

Supporting

Mentioning

108

Contrasting

Unclassified

Order By: Relevance

“…Two indices of attentional modulation of neural responses were calculated for each time-frequency bin (−2 to 10 s; 1-20 Hz). First, the attentional modulation index [AMI X = (X att_left -X att_right )/(X att_left + X att_right )] revealed a spatially resolved measure of attention effects on intertrial phase coherence (1-5 Hz; AMI ITPC ) and alpha power (8)(9)(10)(11)(12) Hz; AMI α ) at each sensor (X being either ITPC or α power; Fig. 3).…”

Section: Methodsmentioning

confidence: 99%

“…5). Thus, alpha power lateralization not only codes the locus of attention in space (10,11,13) but also the structure of the stimulus in time.…”

Section: Spatial Alpha Power Modulation Reveals Dynamics Of Selectivementioning

confidence: 99%

“…Spatial attention induces increasing and decreasing power of neural alpha oscillations (8)(9)(10)(11)(12) Hz) in brain regions ipsilateral and contralateral to the locus of attention, respectively. This study tested whether the hemispheric lateralization of alpha power codes not just the spatial location but also the temporal structure of the stimulus.…”

mentioning

confidence: 99%

“…The power of alpha oscillations (8)(9)(10)(11)(12) is modulated by the degree of selective attention to a behaviorally relevant stimulus (4)(5)(6). Attentive focusing to one side in auditory, visual, or tactile space leads to a relative decrease in alpha power in contralateral compared with ipsilateral sensory brain regions (7)(8)(9)(10) and governs success of selective attention, that is, of isolating one stimulus at a specific spatial location (11)(12)(13) in the context of other distracting stimuli. In speech, however, spatial selective attention alone does not suffice for successful speech comprehension given the multiple timescales (e.g., syllable and word rate) over which speech varies.…”

mentioning

confidence: 99%

See 3 more Smart Citations

Spatiotemporal dynamics of auditory attention synchronize with speech

Wöstmann

Herrmann

Maess

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

186

229

View full text Add to dashboard Cite

Attention plays a fundamental role in selectively processing stimuli in our environment despite distraction. Spatial attention induces increasing and decreasing power of neural alpha oscillations (8-12 Hz) in brain regions ipsilateral and contralateral to the locus of attention, respectively. This study tested whether the hemispheric lateralization of alpha power codes not just the spatial location but also the temporal structure of the stimulus. Participants attended to spoken digits presented to one ear and ignored tightly synchronized distracting digits presented to the other ear. In the magnetoencephalogram, spatial attention induced lateralization of alpha power in parietal, but notably also in auditory cortical regions. This alpha power lateralization was not maintained steadily but fluctuated in synchrony with the speech rate and lagged the time course of low-frequency (1-5 Hz) sensory synchronization. Higher amplitude of alpha power modulation at the speech rate was predictive of a listener's enhanced performance of stream-specific speech comprehension. Our findings demonstrate that alpha power lateralization is modulated in tune with the sensory input and acts as a spatiotemporal filter controlling the read-out of sensory content.attention | neural oscillations | alpha lateralization | synchronization | speech N eural oscillations are tenable biological substrates to instantiate attentional selection of sensory information from our environment (1-3). The power of alpha oscillations (8-12 Hz) is modulated by the degree of selective attention to a behaviorally relevant stimulus (4-6). Attentive focusing to one side in auditory, visual, or tactile space leads to a relative decrease in alpha power in contralateral compared with ipsilateral sensory brain regions (7-10) and governs success of selective attention, that is, of isolating one stimulus at a specific spatial location (11-13) in the context of other distracting stimuli. In speech, however, spatial selective attention alone does not suffice for successful speech comprehension given the multiple timescales (e.g., syllable and word rate) over which speech varies. Any attentional neural mechanism that respects the temporal structure of auditory sensory inputs must therefore be dynamic over time. Here, we tested the hypothesis that spatial attention to one of two concurrent speech streams induces a lateralization of alpha power that synchronizes with the speech rate over time and enhances speech comprehension.In addition to neural alpha oscillations and their role in selective attention, low-frequency neural oscillations (delta/theta band; 1-5 Hz) in sensory cortices synchronize with the temporal structure of acoustic stimuli (14, 15) such as human speech (16,17), and this synchronization supports perception (18). Furthermore, synchronization of low-frequency neural oscillations with speech is enhanced for speech streams to which participants attend (19,20). Critically, low-frequency oscillations are commonly specified as phase-locked activity (synchroni...

show abstract

Section: Methodsmentioning

confidence: 99%

“…5). Thus, alpha power lateralization not only codes the locus of attention in space (10,11,13) but also the structure of the stimulus in time.…”

Section: Spatial Alpha Power Modulation Reveals Dynamics Of Selectivementioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

See 2 more Smart Citations

Spatiotemporal dynamics of auditory attention synchronize with speech

Wöstmann

Herrmann

Maess

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

186

229

View full text Add to dashboard Cite

show abstract

“…Although the majority of evidence regarding the alpha band comes from the visual and somatosensory systems, there is a suggestion that alpha rhythms signify an inhibitory process in auditory attention as well (Dubé et al, 2013; Banerjee et al, 2011). The difference in alpha power across hemispheres indicates the lateralization of auditory attention (Frey et al, 2014; Ahveninen et al, 2013; Kerlin et al, 2010). The relative increase in alpha power contralateral to unattended stimuli supports the interpretation that alpha activity represents reduced processing.…”

mentioning

confidence: 99%

A right‐ear bias of auditory selective attention is evident in alpha oscillations

et al. 2016

View full text Add to dashboard Cite

Auditory selective attention makes it possible to pick out one speech stream that is embedded in a multi-speaker environment. We adapted a cued dichotic listening task to examine suppression of a speech stream lateralized to the non-attended ear, and to evaluate the effects of attention on the right ear's well-known advantage in the perception of linguistic stimuli. After being cued to attend to input from either their left or right ear, participants heard two different four-word streams presented simultaneously to the separate ears. Following each dichotic presentation, participants judged whether a spoken probe word had been in the attended ear's stream. We used EEG signals to track participants' spatial lateralization of auditory attention, which is marked by inter-hemispheric differences in EEG alpha (8-14 Hz) power. A right-ear advantage (REA) was evident in faster response times and greater sensitivity in distinguishing attended from unattended words. Consistent with the REA, we found strongest parietal and right fronto-temporal alpha modulation during the attend-right condition. These findings provide evidence for a link between selective attention and the REA during directed dichotic listening.

show abstract

Finding tau rhythms in EEG: An independent component analysis approach

Wisniewski,

Joyner,

Zakrzewski

et al. 2024

Human Brain Mapping

View full text Add to dashboard Cite

Tau rhythms are largely defined by sound responsive alpha band (~8–13 Hz) oscillations generated largely within auditory areas of the superior temporal gyri. Studies of tau have mostly employed magnetoencephalography or intracranial recording because of tau's elusiveness in the electroencephalogram. Here, we demonstrate that independent component analysis (ICA) decomposition can be an effective way to identify tau sources and study tau source activities in EEG recordings. Subjects (N = 18) were passively exposed to complex acoustic stimuli while the EEG was recorded from 68 electrodes across the scalp. Subjects' data were split into 60 parallel processing pipelines entailing use of five levels of high‐pass filtering (passbands of 0.1, 0.5, 1, 2, and 4 Hz), three levels of low‐pass filtering (25, 50, and 100 Hz), and four different ICA algorithms (fastICA, infomax, adaptive mixture ICA [AMICA], and multi‐model AMICA [mAMICA]). Tau‐related independent component (IC) processes were identified from this data as being localized near the superior temporal gyri with a spectral peak in the 8–13 Hz alpha band. These “tau ICs” showed alpha suppression during sound presentations that was not seen for other commonly observed IC clusters with spectral peaks in the alpha range (e.g., those associated with somatomotor mu, and parietal or occipital alpha). The choice of analysis parameters impacted the likelihood of obtaining tau ICs from an ICA decomposition. Lower cutoff frequencies for high‐pass filtering resulted in significantly fewer subjects showing a tau IC than more aggressive high‐pass filtering. Decomposition using the fastICA algorithm performed the poorest in this regard, while mAMICA performed best. The best combination of filters and ICA model choice was able to identify at least one tau IC in the data of ~94% of the sample. Altogether, the data reveal close similarities between tau EEG IC dynamics and tau dynamics observed in MEG and intracranial data. Use of relatively aggressive high‐pass filters and mAMICA decomposition should allow researchers to identify and characterize tau rhythms in a majority of their subjects. We believe adopting the ICA decomposition approach to EEG analysis can increase the rate and range of discoveries related to auditory responsive tau rhythms.

show abstract

Selective Modulation of Auditory Cortical Alpha Activity in an Audiovisual Spatial Attention Task

Cited by 110 publications

References 48 publications

Spatiotemporal dynamics of auditory attention synchronize with speech

Spatiotemporal dynamics of auditory attention synchronize with speech

A right‐ear bias of auditory selective attention is evident in alpha oscillations

Finding tau rhythms in EEG: An independent component analysis approach

Contact Info

Product

Resources

About