Integration of sensory information precedes the sensation of vection: A combined behavioral and event-related brain potential (ERP) study
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- 作者:Behrang Keshavarz ; Stefan Berti
- 关键词:EEG ; electroencephalogram ; ERP ; event related brain potential ; EOG ; electrooculogram ; MEG ; magnetoencephalogram ; CM ; + ; PS ; center moving with periphery stationary ; CS ; + ; PM ; center stationary with periphery moving ; CPOD ; center and periphery moving in opposite directions ; CPSD ; center and periphery moving in the same direction ; VIMS ; visually induced motion sickness
- 刊名:Behavioural Brain Research
- 出版年:1 February, 2014
- 年:2014
- 卷:259
- 期:Complete
- 页码:131-136
- 全文大小:730 K
文摘
Illusory self-motion (known as vection) describes the sensation of ego-motion in the absence of physical movement. Vection typically occurs in stationary observers being exposed to visual information that suggest self-motion (e.g. simulators, virtual reality). In the present study, we tested whether sensory integration of visual information triggers vection: participants (N = 13) perceived patterns of moving altered black-and-white vertical stripes on a screen that was divided into a central and a surrounding peripheral visual field. In both fields the pattern was either moving or stationary, resulting in four combinations of central and peripheral motions: (1) central and peripheral stripes moved into the same direction, (2) central and peripheral stripes moved in opposite directions, or (3) either the central or (4) the peripheral stripes were stable while the other stripes were in motion. This stimulation induced vection: Results showed significantly higher vection ratings when the stationary center of the pattern was surrounded by a moving periphery. Event-related potentials mirrored this finding: The occipital N2 was largest with stationary central and moving peripheral stripes. Our findings suggest that sensory integration of peripheral and central visual information triggers the perception of vection. Furthermore, we found evidence that neural processes precede the subjective perception of vection strength prior to the actual onset of vection. We will discuss our findings with respect to the role of stimulus eccentricity, stimulus鈥?depth, and neural correlates involved during the genesis of vection.