Paradox Lost? Exploring the Role of Alpha Oscillations During Externally Vs. Internally Directed Attention and the Implications for Idling and Inhibition Hypotheses

Overview

Journal Int J Psychophysiol

Publisher Elsevier

Specialty Psychiatry

Date 2003 Jan 25

PMID 12543447

Citations 178

Authors

Nicholas R Cooper

Rodney J Croft

Samuel J J Dominey

Adrian P Burgess

John H Gruzelier

Affiliations

Soon will be listed here.

Abstract

Although slow waves of the electroencephalogram (EEG) have been associated with attentional processes, the functional significance of the alpha component in the EEG (8.1-12 Hz) remains uncertain. Conventionally, synchronisation in the alpha frequency range is taken to be a marker of cognitive inactivity, i.e. 'cortical idling'. However, it has been suggested that alpha may index the active inhibition of sensory information during internally directed attentional tasks such as mental imagery. More recently, this idea has been amended to encompass the notion of alpha synchronisation as a means of inhibition of non-task relevant cortical areas irrespective of the direction of attention. Here we test the adequacy of the one idling and two inhibition hypotheses about alpha. In two experiments we investigated the relation between alpha and internally vs. externally directed attention using mental imagery vs. sensory-intake paradigms. Results from both experiments showed a clear relationship between alpha and both attentional factors and increased task demands. At various scalp sites alpha amplitudes were greater during internally directed attention and during increased load, results incompatible with alpha reflecting cortical idling and more in keeping with suggestions of active inhibition necessary for internally driven mental operations.

Citing Articles

Electroencephalographic markers in Major Depressive Disorder: insights from absolute, relative power, and asymmetry analyses.

Ozcoban M, Tan O Front Psychiatry. 2025; 15:1480228.

PMID: 39872429 PMC: 11770048. DOI: 10.3389/fpsyt.2024.1480228.

Precision data-driven modeling of cortical dynamics reveals person-specific mechanisms underpinning brain electrophysiology.

Singh M, Braver T, Cole M, Ching S Proc Natl Acad Sci U S A. 2025; 122(3):e2409577121.

PMID: 39823302 PMC: 11761305. DOI: 10.1073/pnas.2409577121.

Strength of Low-Frequency EEG Phase Entrainment to External Stimuli Is Associated with Fluctuations in the Brain's Internal State.

Maki-Marttunen V, Velinov A, Nieuwenhuis S eNeuro. 2025; 12(1).

PMID: 39779324 PMC: 11772043. DOI: 10.1523/ENEURO.0064-24.2024.

Predicting attentional focus: Heartbeat-evoked responses and brain dynamics during interoceptive and exteroceptive processing.

Flo E, Belloli L, Cabana A, Ruyant-Belabbas A, Jodaitis L, Valente M PNAS Nexus. 2024; 3(12):pgae531.

PMID: 39677366 PMC: 11645458. DOI: 10.1093/pnasnexus/pgae531.

Neurological Evidence of Diverse Self-Help Breathing Training With Virtual Reality and Biofeedback Assistance: Extensive Exploration Study of Electroencephalography Markers.

Ng H, Wu C, Hsu H, Huang C, Hsu A, Chao Y JMIR Form Res. 2024; 8:e55478.

PMID: 39642375 PMC: 11662191. DOI: 10.2196/55478.