Journal
JOURNAL OF NEUROPHYSIOLOGY
Volume 114, Issue 6, Pages 3201-3210Publisher
AMER PHYSIOLOGICAL SOC
DOI: 10.1152/jn.00746.2015
Keywords
frontal eye field; macaque; receptive field; saccades; vision
Categories
Funding
- National Eye Institute (NEI) Fellowship [F32-EY-022529]
- NEI [R01-EY-017592, R00-EY-018894, R01-EY-022928, P30-EY-008098]
- Research to Prevent Blindness Career Development Award
- Eye and Ear Foundation of Pittsburgh
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Neuronal receptive fields (RFs) provide the foundation for understanding systems-level sensory processing. In early visual areas, investigators have mapped RFs in detail using stochastic stimuli and sophisticated analytical approaches. Much less is known about RFs in prefrontal cortex. Visual stimuli used for mapping RFs in prefrontal cortex tend to cover a small range of spatial and temporal parameters, making it difficult to understand their role in visual processing. To address these shortcomings, we implemented a generalized linear model to measure the RFs of neurons in the macaque frontal eye field (FEF) in response to sparse, full-field stimuli. Our high-resolution, probabilistic approach tracked the evolution of RFs during passive fixation, and we validated our results against conventional measures. We found that FEF neurons exhibited a surprising level of sensitivity to stimuli presented as briefly as 10 ms or to multiple dots presented simultaneously, suggesting that FEF visual responses are more precise than previously appreciated. FEF RF spatial structures were largely maintained over time and between stimulus conditions. Our results demonstrate that the application of probabilistic RF mapping to FEF and similar association areas is an important tool for clarifying the neuronal mechanisms of cognition.
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