Immersive Scene Representation in Human Visual Cortex with Ultra-wide-angle Neuroimaging

Overview

Journal Nat Commun

Specialty Biology

Date 2024 Jun 28

PMID 38942766

Authors

Jeongho Park

Edward Soucy

Jennifer Segawa

Ross Mair

Talia Konkle

Affiliations

Soon will be listed here.

Abstract

While human vision spans 220°, traditional functional MRI setups display images only up to central 10-15°. Thus, it remains unknown how the brain represents a scene perceived across the full visual field. Here, we introduce a method for ultra-wide angle display and probe signatures of immersive scene representation. An unobstructed view of 175° is achieved by bouncing the projected image off angled-mirrors onto a custom-built curved screen. To avoid perceptual distortion, scenes are created with wide field-of-view from custom virtual environments. We find that immersive scene representation drives medial cortex with far-peripheral preferences, but shows minimal modulation in classic scene regions. Further, scene and face-selective regions maintain their content preferences even with extreme far-periphery stimulation, highlighting that not all far-peripheral information is automatically integrated into scene regions computations. This work provides clarifying evidence on content vs. peripheral preferences in scene representation and opens new avenues to research immersive vision.

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