Your search keyword '"Mineault, Patrick J."' showing total 6 results

1. Enhanced Spatial Resolution During Locomotion and Heightened Attention in Mouse Primary Visual Cortex

Author

Mineault, Patrick J, Tring, Elaine, Trachtenberg, Joshua T, and Ringach, Dario L

Subjects

Biomedical and Clinical Sciences, Neurosciences, Behavioral and Social Science, Bioengineering, Clinical Research, Eye Disease and Disorders of Vision, Basic Behavioral and Social Science, Underpinning research, 1.1 Normal biological development and functioning, Action Potentials, Animals, Attention, Female, Linear Models, Locomotion, Male, Mice, Mice, Inbred C57BL, Neurons, Orientation, Spatial, Photic Stimulation, Transduction, Genetic, Visual Cortex, alertness, locomotion, neuronal gain, operating point, spatial acuity, visual cortex, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

UnlabelledWe do not fully understand how behavioral state modulates the processing and transmission of sensory signals. Here, we studied the cortical representation of the retinal image in mice that spontaneously switched between a state of rest and a constricted pupil, and one of active locomotion and a dilated pupil, indicative of heightened attention. We measured the selectivity of neurons in primary visual cortex for orientation and spatial frequency, as well as their response gain, in these two behavioral states. Consistent with prior studies, we found that preferred orientation and spatial frequency remained invariant across states, whereas response gain increased during locomotion relative to rest. Surprisingly, relative gain, defined as the ratio between the gain during locomotion and the gain during rest, was not uniform across the population. Cells tuned to high spatial frequencies showed larger relative gain compared with those tuned to lower spatial frequencies. The preferential enhancement of high-spatial-frequency information was also reflected in our ability to decode the stimulus from population activity. Finally, we show that changes in gain originate from shifts in the operating point of neurons along a spiking nonlinearity as a function of behavioral state. Differences in the relative gain experienced by neurons with high and low spatial frequencies are due to corresponding differences in how these cells shift their operating points between behavioral states.Significance statementHow behavioral state modulates the processing and transmission of sensory signals remains poorly understood. Here, we show that the mean firing rate and neuronal gain increase during locomotion as a result in a shift of the operating point of neurons. We define relative gain as the ratio between the gain of neurons during locomotion and rest. Interestingly, relative gain is higher in cells with preferences for higher spatial frequencies than those with low-spatial-frequency selectivity. This means that, during a state of locomotion and heightened attention, the population activity in primary visual cortex can support better spatial acuity, a phenomenon that parallels the improved spatial resolution observed in human subjects during the allocation of spatial attention.

Published

2016

2. Your head is there to move you around: Goal-driven models of the primate dorsal pathway

Author

Mineault, Patrick J, primary, Bhaktiari, Shahab, additional, Richards, Blake A, additional, and Pack, Christopher C, additional

Published

2021

3. The role of phacoemulsification in glaucoma therapy: A systematic review and meta-analysis

Author

Masis, Marisse, primary, Mineault, Patrick J., additional, Phan, Eileen, additional, and Lin, Shan C., additional

Published

2018

4. Spatial clustering of tuning in mouse primary visual cortex

Author

Ringach, Dario L., primary, Mineault, Patrick J., additional, Tring, Elaine, additional, Olivas, Nicholas D., additional, Garcia-Junco-Clemente, Pablo, additional, and Trachtenberg, Joshua T., additional

Published

2016

5. A Sensorimotor Role for Traveling Waves in Primate Visual Cortex

Author

Zanos, Theodoros P., primary, Mineault, Patrick J., additional, Nasiotis, Konstantinos T., additional, Guitton, Daniel, additional, and Pack, Christopher C., additional

Published

2015

6. Mechanisms of Saccadic Suppression in Primate Cortical Area V4.

Author

Zanos, Theodoros P., Mineault, Patrick J., Guitton, Daniel, and Pack, Christopher C.

Subjects

*SACCADIC eye movements, *VISUAL perception, *STIMULUS & response (Biology), *NEURONS, *NEURAL circuitry

Abstract

Psychophysical studies have shown that subjects are often unaware of visual stimuli presented around the time of an eye movement. This saccadic suppression is thought to be a mechanism for maintaining perceptual stability. The brain might accomplish saccadic suppression by reducing the gain of visual responses to specific stimuli or by simply suppressing firing uniformly for all stimuli. Moreover, the suppression might be identical across the visual field or concentrated at specific points. To evaluate these possibilities, we recorded from individual neurons in cortical area V4 of nonhuman primates trained to execute saccadic eye movements. We found that both modes of suppression were evident in the visual responses of these neurons and that the two modes showed different spatial and temporal profiles: while gain changes started earlier and were more widely distributed across visual space, nonspecific suppression was found more often in the peripheral visual field, after the completion of the saccade. Peripheral suppression was also associated with increased noise correlations and stronger local field potential oscillations in the α frequency band. This pattern of results suggests that saccadic suppression shares some of the circuitry responsible for allocating voluntary attention. [ABSTRACT FROM AUTHOR]

Published

2016