How does one know what to look at in a scene? Imagine a "Where's Waldo" game - it's challenging to find Waldo because there are many 'salient' locations in the picture, each vying for one's attention. One can only attend to a small location on the picture at a given moment, so to find Waldo, one needs to direct their attention to different locations. One prominent theory about how one accomplishes this claims that important locations are identified based on distinct feature types (for example, motion or color), with locations most unique compared to the background most likely to be attended. An important component of this theory is that individual feature dimensions (again, color or motion) are computed within their own 'feature maps', which are thought to be implemented in specific brain regions. However, whether and how specific brain regions contribute to these feature maps remains unknown. The goal of this study is to determine how brain regions that respond strongly to different feature types (color and motion) and which encode spatial locations of visual stimuli transform 'feature dimension maps' based on stimulus properties as a function of task instructions. The investigators hypothesize that feature-selective brain regions act as neural feature dimension maps, and thus encode representations of relevant location(s) based on their preferred feature dimension, such that the stimulus representation in the most relevant feature map is up-regulated to support adaptive behavior. The investigators will scan healthy human participants using functional MRI (fMRI) in a repeated-measures design while they view visual stimuli made relevant based on a cued feature dimension (e.g., color or motion). The investigators will employ state-of-the-art multivariate analysis techniques that allow them to reconstruct an 'image' of the stimulus representation encoded by each brain region to dissect how neural tissue identifies salient locations. Each participant will perform a challenging discrimination task based on the cued feature (report motion direction or color of stimulus dots) of either a single stimulus presented in the periphery, which are identical across trial types, or multiple simultaneously-presented stimuli. Across trials the investigators will manipulate the attended feature value (color, motion, or fixation point) and number of attended stimuli (attend 1 stimulus, attend 2 stimuli). These manipulations will help the investigators fully understand these critical relevance computations in the healthy human visual system.
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Strength of stimulus representation quantified by map activation at stimulus location(s) derived from multivariate analysis of functional MRI data
Timeframe: During each fMRI scanning session throughout enrollment (sessions will be scheduled to occur within 1-2 weeks of enrollment).
Discrimination accuracy derived from behavioral performance during fMRI scanning, acquired using fMRI button box
Timeframe: During each fMRI scanning session throughout enrollment (sessions will be scheduled to occur within 1-2 weeks of enrollment).
Response time derived from behavioral performance during fMRI scanning, acquired using fMRI button box
Timeframe: During each fMRI scanning session throughout enrollment (sessions will be scheduled to occur within 1-2 weeks of enrollment).
Discrimination thresholds derived from behavioral performance during fMRI scanning, acquired using fMRI button box
Timeframe: During each fMRI scanning session throughout enrollment (sessions will be scheduled to occur within 1-2 weeks of enrollment).