Abstract

Oscillatory electrical brain activity in the alpha (8-13 Hz) band is a prominent feature of human electroencephalography (EEG) during alert wakefulness, and is commonly thought to arise primarily from the occipital and parietal parts of the cortex. While the thalamus is considered to play a supportive role in the generation and modulation of cortical alpha rhythms, its precise function remains controversial and incompletely understood. To address this, we evaluated the correlation between the blood oxygenation level dependent (BOLD) functional magnetic resonance imaging (fMRI) signals in the thalamus and the spontaneous modulation of posterior alpha rhythms based on EEG-fMRI data acquired concurrently during an eyes-closed task-free condition. We observed both negative and positive correlations in the thalamus. The negative correlations were mostly seen within the visual thalamus, with a preference for the pulvinar over lateral geniculate nuclei. The positive correlations were found at the anterior and medial dorsal nuclei. Through functional connectivity analysis of the fMRI data, the pulvinar was found to be functionally associated with the same widespread cortical visual areas where the fMRI signals were negatively correlated with the posterior alpha modulation. In contrast, the dorsal nuclei were part of a distinct functional network that included brain stem, cingulate cortex and cerebellum. These observations are consistent with previous animal electrophysiology studies and the notion that the visual thalamus, and the pulvinar in particular, is intimately involved in the generation and spontaneous modulation of posterior alpha rhythms, facilitated by its reciprocal and widespread interaction with the cortical visual areas. We further postulate that the anterior and medial dorsal nuclei, being part of the ascending neuromodulatory system, may indirectly modulate cortical alpha rhythms by affecting vigilance and arousal levels.

Highlights

  • In human EEG, alpha activity is most prominent in occipital and parietal regions when the subject is resting wakefully with eyes closed, and is suppressed with opening of the eyes (Berger, 1929) or falling into sleep (Niedermeyer, 1997)

  • The occipital dominance of alpha-band EEG activity is thought to reflect primarily cortical dendritic activity synchronized across a large part of the visual cortex, which is situated in the occipital lobe

  • To find the hemodynamic correlates of posterior alpha EEG, we simultaneously measured EEG and functional magnetic resonance imaging (fMRI) signals from subjects resting with eyes closed

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Summary

Introduction

In human EEG, alpha activity (i.e. electrical activity in the 8–13Hz frequency range) is most prominent in occipital and parietal regions when the subject is resting wakefully with eyes closed, and is suppressed with opening of the eyes (Berger, 1929) or falling into sleep (Niedermeyer, 1997). Invasive electrophysiological recordings from animals have shed light on an important role of the visual thalamus in the generation, modulation and synchronization of alpha rhythms observed from the visual cortex (Hughes and Crunelli, 2005). Like the human posterior alpha rhythm, its amplitude was shown to react in a similar fashion to opening and closing the eyes (Chatila et al, 1992). Comparison between the alpha rhythms recorded from the thalamic and cortical parts of the animal visual system showed a strong degree of phase-locking and covarying amplitudes (Chatila et al, 1993; Lopes da Silva et al, 1973; Lopes da Silva et al, 1980; Lorincz et al, 2009). Coherence analysis after simulated removal of the visual thalamus by parceling out its contributions to thalamo-cortical synchrony showed a significant decrease of intra-cortical alpha coherence (Lopes da Silva et al, 1980)

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