A Probabilistic Strategy for Understanding Action Selection

Kim, Byoung-Hoon; Basso, Michele A.

doi:10.1523/jneurosci.1730-09.2010

Cited by 58 publications

(49 citation statements)

References 89 publications

(169 reference statements)

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“…Activity in such a map does not encode the specific object features (e.g., color, shape) of potential movement goals; rather, it represents the physical salience and behavioral relevance of the goals. Target selection has been hypothesized to involve a competition among the goals in the priority map, leading to the selection of a single movement goal (1)(2)(3)(4)(5). Current evidence suggests that priority maps for target selection are distributed across a number of brain regions (6-10), and oculomotor areas, such as the SC, have been shown to possess the characteristics of a priority map for eyemovement tasks (7,(11)(12)(13)(14)(15)(16)(17).…”

Section: Discussionmentioning

confidence: 99%

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Deficits in reach target selection during inactivation of the midbrain superior colliculus

Song

Rafal

McPeek

2011

Proc. Natl. Acad. Sci. U.S.A.

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Purposive action requires the selection of a single movement goal from multiple possibilities. Neural structures involved in movement planning and execution often exhibit activity related to target selection. A key question is whether this activity is specific to the type of movement produced by the structure, perhaps consisting of a competition among effector-specific movement plans, or whether it constitutes a more abstract, effector-independent selection signal. Here, we show that temporary focal inactivation of the primate superior colliculus (SC), an area involved in eye-movement target selection and execution, causes striking target selection deficits for reaching movements, which cannot be readily explained as a simple impairment in visual perception or motor execution. This indicates that target selection activity in the SC does not simply represent a competition among eye-movement goals and, instead, suggests that the SC contributes to a more general purpose priority map that influences target selection for other actions, such as reaches. G oal-directed behavior requires the serial selection of individual targets embedded in visual scenes that are often crowded with many different objects. Target selection is usually conceived of as a competition among potential movement goals (1-5), occurring in a priority map that encodes both the physical salience and behavioral relevance of each goal (6-10).Much of the research on the neural mechanisms of target selection has focused on selection-related signals in brain areas involved in planning and executing the resultant motor response. For example, activity related to eye-movement target selection has been identified in the superior colliculus (SC) (7,(11)(12)(13)(14)(15)(16)(17), frontal eye field (18-20), lateral intraparietal area (10, 21-23), and supplementary eye fields (24), all areas in which signals related to eye movement execution are seen and in which electrical microstimulation and/or temporary inactivation affects the execution of eye movements (25-31). For reaching movements, target selection activity has been observed in the dorsal premotor area (32-34), a region from which reaches can be electrically elicited (35), as well as in the parietal reach region (36, 37), which exhibits reach-related planning and execution signals (38, 39).Clear evidence for a more abstract, effector-independent priority map used for target selection has generally been limited to higher level cortical association areas, such as the dorsolateral prefrontal cortex, which shows activity related to both saccade and reach target selection (40-42) but from which neither saccades nor reaches can be evoked. This suggests a hierarchical model for target selection, in which effector-independent selection signals in higher level areas are selectively transmitted to appropriate lower level, effector-specific structures, which, in turn, finalize the selection process, plan, and execute the desired movement. Under this view, activity in these effector-specific structures, such as the...

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Section: Discussionmentioning

confidence: 99%

“…Target selection is usually conceived of as a competition among potential movement goals (1)(2)(3)(4)(5), occurring in a priority map that encodes both the physical salience and behavioral relevance of each goal (6)(7)(8)(9)(10).…”

mentioning

confidence: 99%

Deficits in reach target selection during inactivation of the midbrain superior colliculus

Song

Rafal

McPeek

2011

Proc. Natl. Acad. Sci. U.S.A.

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“…Three monkeys (Macaca mulatta) were implanted with eye loops for monitoring eye movements and cranial cylinders for electrophysiological recording of single neurons, as described previously (Kim and Basso 2010;Li and Basso 2011). These animals participated in electrophysiological experiments ongoing in the laboratory.…”

Section: Methodsmentioning

confidence: 99%

Blinks slow memory-guided saccades

Powers

Basso

Evinger

2013

Journal of Neurophysiology

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Powers AS, Basso MA, Evinger C. Blinks slow memory-guided saccades. J Neurophysiol 109: 734 -741, 2013. First published November 14, 2012 doi:10.1152/jn.00746.2012.-Memory-guided saccades are slower than visually guided saccades. The usual explanation for this slowing is that the absence of a visual drive reduces the discharge of neurons in the superior colliculus. We tested a related hypothesis: that the slowing of memory-guided saccades was due also to the more frequent occurrence of gaze-evoked blinks with memoryguided saccades compared with visually guided saccades. We recorded gaze-evoked blinks in three monkeys while they performed visually guided and memory-guided saccades and compared the kinematics of the different saccade types with and without blinks. Gaze-evoked blinks were more common during memory-guided saccades than during visually guided saccades, and the well-established relationship between peak and average velocity for saccades was disrupted by blinking. The occurrence of gaze-evoked blinks was associated with a greater slowing of memory-guided saccades compared with visually guided saccades. Likewise, when blinks were absent, the peak velocity of visually guided saccades was only slightly higher than that of memory-guided saccades. Our results reveal interactions between circuits generating saccades and blink-evoked eye movements. The interaction leads to increased curvature of saccade trajectories and a corresponding decrease in saccade velocity. Consistent with this interpretation, the amount of saccade curvature and slowing increased with gaze-evoked blink amplitude. Thus, although the absence of vision decreases the velocity of memory-guided saccades relative to visually guided saccades somewhat, the cooccurrence of gaze-evoked blinks produces the majority of slowing for memory-guided saccades.

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“…It is also reminiscent of the neural mechanisms underlying saccade and reach target selection in visual search tasks (Kim and Basso 2010;Purcell et al 2012;Song and McPeek 2010). Ultimately, neural recordings will be needed to provide more definitive evidence for the neural mechanisms leading to reach target selection in the CG task.…”

Section: Alternate Hypotheses For Choice Behavior In the Cg Taskmentioning

confidence: 99%

“…This has been extensively studied in the oculomotor system in tasks in which subjects chose the target for saccadic eye movements from among multiple distractors in visual-search paradigms or on the basis of the direction of variable-strength coherent visual motion in random-dot kinematogram (RDK) stimuli (Carpenter and Williams 1998;Churchland et al 2008;Ditterich 2006aDitterich , 2006bDitterich , 2010Hanes and Schall 1996;Horwitz et al 2004;Kim and Basso 2010;Kim and Shadlen 1999;Mazurek et al 2003;Palmer et al 2005;Purcell et al 2012;Ratcliff et al 2003Ratcliff et al , 2007Roitman and Shadlen 2002;Sato and Schall 2003;Shadlen et al 1996). These studies suggest that saccade target selection is accomplished by parallel neural circuits that continuously acquire sensory evidence for and against each target choice across time until the accumulated evidence in one circuit exceeds a decision criterion threshold.…”

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confidence: 99%