Saccade-related activity in monkey superior colliculus. II. Spread of activity during saccades

Munoz, Douglas P.; Wurtz, Robert H.

doi:10.1152/jn.1995.73.6.2334

Cited by 269 publications

(232 citation statements)

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“…By this time, saccade-related SC activity has dropped substantially (Munoz and Wurtz, 1995), suggesting that visual and extraretinal signals during experiments on perisaccadic perception are temporally offset in the SC. Thus, the neuronal correlate of any model based on their interaction is unlikely to reside in the SC.…”

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confidence: 94%

The Geometry of Perisaccadic Visual Perception

Richard¹,

Churan²,

Guitton³

et al. 2009

J. Neurosci.

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Our ability to explore our surroundings requires a combination of high-resolution vision and frequent rotations of the visual axis toward objects of interest. Such gaze shifts are themselves a source of powerful retinal stimulation, and so the visual system appears to have evolved mechanisms to maintain perceptual stability during movements of the eyes in space. The mechanisms underlying this perceptual stability can be probed in the laboratory by briefly presenting a stimulus around the time of a saccadic eye movement and asking subjects to report its position. Under such conditions, there is a systematic misperception of the probes toward the saccade end point. This perisaccadic compression of visual space has been the subject of much research, but few studies have attempted to relate it to specific brain mechanisms. Here, we show that the magnitude of perceptual compression for a wide variety of probe stimuli and saccade amplitudes is quantitatively predicted by a simple heuristic model based on the geometry of retinotopic representations in the primate brain. Specifically, we propose that perisaccadic compression is determined by the distance between the probe and saccade end point on a map that has a logarithmic representation of visual space, similar to those found in numerous cortical and subcortical visual structures. Under this assumption, the psychophysical data on perisaccadic compression can be appreciated intuitively by imagining that, around the time of a saccade, the brain confounds nearby oculomotor and sensory signals while attempting to localize the position of objects in visual space.

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confidence: 94%

The Geometry of Perisaccadic Visual Perception

Richard¹,

Churan²,

Guitton³

et al. 2009

J. Neurosci.

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“…In reaction time experiments, this motor-preparation activity occurs during the foreperiod, or even before, as in the case of the 0-ms interval and contributes to shortening of motor latencies. In fact, using experimental procedures that involve an instructed delay period between a cue and the triggered movement, some studies have documented such motor-preparation activity related to various motor centers: the motor cortex (27), the basal ganglia (28), the spinal interneurons (29) and the superior colliculus (30).…”

Section: Discussionmentioning

confidence: 99%

Looking for the GAP effect in manual responses and the role of contextual influences in reaction time experiments

Jr.

Machado-Pinheiro

2004

Braz J Med Biol Res

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When the offset of a visual stimulus (GAP condition) precedes the onset of a target, saccadic reaction times are reduced in relation to the condition with no offset (overlap condition) -the GAP effect. However, the existence of the GAP effect for manual responses is still controversial. In two experiments using both simple (Experiment 1, N = 18) and choice key-press procedures (Experiment 2, N = 12), we looked for the GAP effect in manual responses and investigated possible contextual influences on it. Participants were asked to respond to the imperative stimulus that would occur under different experimental contexts, created by varying the array of warning-stimulus intervals (0, 300 and 1000 ms) and conditions (GAP and overlap): i) intervals and conditions were randomized throughout the experiment; ii) conditions were run in different blocks and intervals were randomized; iii) intervals were run in different blocks and conditions were randomized. Our data showed that no GAP effect was obtained for any manipulation. The predictability of stimulus occurrence produced the strongest influence on response latencies. In Experiment 1, simple manual responses were shorter when the intervals were blocked (247 ms, P < 0.001) in relation to the other two contexts (274 and 279 ms). Despite the use of choice key-press procedures, Experiment 2 produced a similar pattern of results. A discussion addressing the critical conditions to obtain the GAP effect for distinct motor responses is presented. In short, our data stress the relevance of the temporal allocation of attention for behavioral performance.

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“…In the case of SRTs experiments, preparation would be represented by the increased activity of build-up neurons of superior colliculus during the gap interval (for details about build-up activity in superior colliculus (33)(34)(35)(36) ). For MRTs, this motor preparation can also occur and maybe contribute to a decrease on motor latencies.…”

Section: Discussionmentioning

confidence: 99%