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Occipital cortex is modulated by transsaccadic changes in spatial frequency: an fMRI study

Bianca R. Baltaretu, Benjamin T. Dunkley, W. Dale Stevens, J. Douglas Crawford

2021Scientific Reports20 citationsDOIOpen Access PDF

Abstract

Previous neuroimaging studies have shown that inferior parietal and ventral occipital cortex are involved in the transsaccadic processing of visual object orientation. Here, we investigated whether the same areas are also involved in transsaccadic processing of a different feature, namely, spatial frequency. We employed a functional magnetic resonance imaging paradigm where participants briefly viewed a grating stimulus with a specific spatial frequency that later reappeared with the same or different frequency, after a saccade or continuous fixation. First, using a whole-brain Saccade > Fixation contrast, we localized two frontal (left precentral sulcus and right medial superior frontal gyrus), four parietal (bilateral superior parietal lobule and precuneus), and four occipital (bilateral cuneus and lingual gyri) regions. Whereas the frontoparietal sites showed task specificity, the occipital sites were also modulated in a saccade control task. Only occipital cortex showed transsaccadic feature modulations, with significant repetition enhancement in right cuneus. These observations (parietal task specificity, occipital enhancement, right lateralization) are consistent with previous transsaccadic studies. However, the specific regions differed (ventrolateral for orientation, dorsomedial for spatial frequency). Overall, this study supports a general role for occipital and parietal cortex in transsaccadic vision, with a specific role for cuneus in spatial frequency processing.

Topics & Concepts

CuneusOccipital lobeNeurosciencePosterior parietal cortexPrecuneusParietal lobeFixation (population genetics)Functional magnetic resonance imagingPsychologyAnatomyMedicinePopulationEnvironmental healthVisual perception and processing mechanismsMultisensory perception and integrationMemory and Neural Mechanisms