2019
DOI: 10.1101/571307
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Time-course of population activity along the dorsoventral extent of the superior colliculus during delayed saccade tasks

Abstract: 20The superior colliculus (SC) is an excellent substrate to study functional organization of 21 sensorimotor transformations. We used linear multi-contact array recordings to analyze the spatial and 22 temporal properties of population activity along the SC dorsoventral axis during delayed saccade tasks. 23During the visual epoch, information appeared first in dorsal layers and systematically later in ventral layers. 24In the ensuing delay period, the laminar organization of low-spiking rate activity matched t… Show more

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Cited by 2 publications
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“…The methodologies, results, and model described in this review can lead to many more questions, such as: (a) How is the T‐to‐G transformation accomplished through the interaction of neurons within and between different layers of SC and FEF microcircuits? (Basso & May, 2017; Bastos et al., 2012; Chandrasekaran, Peixoto, Newsome, & Shenoy, 2017; Heinzleet al, 2007; Massot, Jagadisan, & Gandhi, 2019; Sajad, Godlove, & Schall, 2019; Shin & Sommer, 2012); (b) How do the spatial codes at the individual neuron and population levels change in other visuomotor behaviors, such as express saccades (latency < 100 ms), in which the temporal visual and motor responses entirely overlap (Dorris, Pare, & Munoz, 1997; Isa, 2002)? ; (c) how does this methodology extend to other areas of the brain involved in gaze control (Bremmer et al., 2016; Schneider, Dominguez‐Vargas, Gibson, Kagan, & Wilke, 2020)?…”
Section: Theoretical Implications: a New Conceptual Model For Gaze Comentioning
confidence: 99%
“…The methodologies, results, and model described in this review can lead to many more questions, such as: (a) How is the T‐to‐G transformation accomplished through the interaction of neurons within and between different layers of SC and FEF microcircuits? (Basso & May, 2017; Bastos et al., 2012; Chandrasekaran, Peixoto, Newsome, & Shenoy, 2017; Heinzleet al, 2007; Massot, Jagadisan, & Gandhi, 2019; Sajad, Godlove, & Schall, 2019; Shin & Sommer, 2012); (b) How do the spatial codes at the individual neuron and population levels change in other visuomotor behaviors, such as express saccades (latency < 100 ms), in which the temporal visual and motor responses entirely overlap (Dorris, Pare, & Munoz, 1997; Isa, 2002)? ; (c) how does this methodology extend to other areas of the brain involved in gaze control (Bremmer et al., 2016; Schneider, Dominguez‐Vargas, Gibson, Kagan, & Wilke, 2020)?…”
Section: Theoretical Implications: a New Conceptual Model For Gaze Comentioning
confidence: 99%