Neurons in V1, V2, and PMLS of Cat Cortex Are Speed Tuned But Not Acceleration Tuned: The Influence of Motion Adaptation

Price, Nicholas S. C.; Crowder, Nathan A.; Hietanen, Markus A.; Ibbotson, M.

doi:10.1152/jn.00890.2005

Cited by 22 publications

(21 citation statements)

References 61 publications

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“…Brains were sectioned in the coronal plane by cryosectioning with a section width of 24 m. Slices were mounted on subbed slides and stained with thionin for Nissl substance Price et al 2006). Images of slices were digitized using 1-4 megapixel cameras attached to a microscope with ϫ4 magnification.…”

Section: Methodsmentioning

confidence: 99%

Spatial phase sensitivity of complex cells in primary visual cortex depends on stimulus contrast

Meffin

Hietanen

Cloherty

et al. 2015

Journal of Neurophysiology

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[3457][3458][3459][3460][3461][3462][3463][3464][3465][3466][3467][3468][3469][3470] 2010). However, drifting gratings confound the influence of spatial and temporal summation, so here we have stimulated complex cells with gratings that are spatially stationary but continuously reverse the polarity of the contrast over time (contrastreversing gratings). By varying the spatial phase and contrast of the gratings we aimed to establish whether the contrast-dependent phase sensitivity of complex cells results from changes in spatial or temporal processing or both. We found that most of the increase in phase sensitivity at low contrasts could be attributed to changes in the spatial phase sensitivities of complex cells. However, at low contrasts the complex cells did not develop the spatiotemporal response characteristics of simple cells, in which paired response peaks occur 180°out of phase in time and space. Complex cells that increased their spatial phase sensitivity at low contrasts were significantly overrepresented in the supragranular layers of cortex. We conclude that complex cells in supragranular layers of cat cortex have dynamic spatial summation properties and that the mechanisms underlying complex cell receptive fields differ between cortical layers. visual system; cat cortex; area 17; complex cell

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Section: Methodsmentioning

confidence: 99%

Spatial phase sensitivity of complex cells in primary visual cortex depends on stimulus contrast

Meffin

Hietanen

Cloherty

et al. 2015

Journal of Neurophysiology

Self Cite

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“…It was previously noted that phasic responses of MSTd neurons are less selective for stimulus motion than tonic responses and that many cells generate sizable excitatory responses to motion in the antipreferred direction (Duffy and Wurtz 1991). Furthermore, 10°saccades induce retinal-slip velocities of 300 -400°/s and these fast speeds may have reduced the direction selectivity of MSTd neurons (although this does not appear to be the case for area MT; Price et al 2005). Figure 1B plots the preferred motion response against the antipreferred response for active motion.…”

Section: Saccadic Influence On Directionalitymentioning

confidence: 99%

“…Visual stimuli comprised random texture patterns formed of 0.8°dark or light squares spanning 77 ϫ 77°. They were rear-projected using a Mirage 2000 digital light projector (DLP; Christie Digital Systems, Cypress, CA) with resolution of 1,024 ϫ 1,024 pixels, frame rate of 96 Hz, and mean luminance 170 cd/m 2 (for issues relating to the DLP, see Price et al 2005). Texture contrast is defined as: Michelson contrast ϭ ([Luminance max Ϫ Luminance min ]/[Luminance max ϩ Luminance min ]) ϫ 100.…”

Section: Behavioral Paradigms and Visual Stimulationmentioning

confidence: 99%

“…The imperceptibility of wide-field motion during saccades has been dubbed saccadic suppression. This phenomenon is not due to poor sensitivity for fast motion because stimuli with saccade-like speed and duration produce a powerful sense of movement during fixation (Ross et al 2001) and drive neurons at various stages in the visual system (e.g., subcortical: Price and Ibbotson 2001;cortical: Price et al 2005;Thiele et al 2002). It has been theorized that the loss of visual sensitivity during saccades is due to active attenuation of components within the visual system.…”

Section: Introductionmentioning

confidence: 99%

“…Another perplexing finding that has arisen from studies of saccadic suppression in MT and MSTd is that response latencies are reduced around the time of saccades (Ibbotson et al 2006(Ibbotson et al , 2008Price et al 2005;Thiele et al 2002). The response latencies to image motion generated during saccades can be as short as 30 ms, compared with around 70 ms in the absence of saccades (median values; Ibbotson et al 2007;Thiele et al 2002).…”

Section: Introductionmentioning

confidence: 99%

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Direction and Contrast Tuning of Macaque MSTd Neurons During Saccades

Crowder

Price

Mustari

et al. 2009

Journal of Neurophysiology

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Crowder NA, Price NSC, Mustari MJ, Ibbotson MR. Direction and contrast tuning of macaque MSTd neurons during saccades. J Neurophysiol 101: 3100 -3107, 2009. First published April 8, 2009 doi:10.1152/jn.91254.2008. Saccades are rapid eye movements that change the direction of gaze, although the full-field image motion associated with these movements is rarely perceived. The attenuation of visual perception during saccades is referred to as saccadic suppression. The mechanisms that produce saccadic suppression are not well understood. We recorded from neurons in the dorsal medial superior temporal area (MSTd) of alert macaque monkeys and compared the neural responses produced by the retinal slip associated with saccades (active motion) to responses evoked by identical motion presented during fixation (passive motion). We provide evidence for a neural correlate of saccadic suppression and expand on two contentious results from previous studies. First, we confirm the finding that some neurons in MSTd reverse their preferred direction during saccades. We quantify this effect by calculating changes in direction tuning index for a large cell population. Second, it has been noted that neural activity associated with saccades can arrive in the parietal cortex Յ30 ms earlier than activity produced by similar visual stimulation during fixation. This led to the question of whether the saccade-related responses were visual in origin or were motor signals arising from saccade-planning areas of the brain. By comparing the responses to saccades made over textured backgrounds of different contrasts, we provide strong evidence that saccade-related responses were visual in origin. Refinements of the possible models of saccadic suppression are discussed.

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Physics of Experiential Now: Effort of Atomic Action

Lubashevsky

Plavinska

2021

Understanding Complex Systems

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Neurons in V1, V2, and PMLS of Cat Cortex Are Speed Tuned But Not Acceleration Tuned: The Influence of Motion Adaptation

Cited by 22 publications

References 61 publications

Spatial phase sensitivity of complex cells in primary visual cortex depends on stimulus contrast

Spatial phase sensitivity of complex cells in primary visual cortex depends on stimulus contrast

Direction and Contrast Tuning of Macaque MSTd Neurons During Saccades

Physics of Experiential Now: Effort of Atomic Action

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