Dorsal premotor cortex: neural correlates of reach target decisions based on a color-location matching rule and conflicting sensory evidence

Coallier, Émilie; Michelet, Thomas; Kalaska, John

doi:10.1152/jn.00166.2014

Cited by 93 publications

(96 citation statements)

References 128 publications

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“…Domains in M1 receive inputs from cingulate motor cortex, SMA, PMC, and PPCr, cerebellar inputs relayed via the motor thalamus and sensory inputs, especially proprioceptive inputs from area 3a, adding further levels of competition to the selection process. The PMC and M1 domains are involved in second and third levels of selection (Coallier et al, 2015), based on the different sources of information, as well as being involved in initiating and guiding the sequences of movements for each type of behavior. Ultimately, M1 domains have the most relevant information, and are the most critical in the selection process.…”

Section: The Organization Of Ppc and Parietal-frontal Sensorimotor Nementioning

confidence: 99%

Evolution of posterior parietal cortex and parietal‐frontal networks for specific actions in primates

Kaas

Stepniewska

2015

J of Comparative Neurology

101

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Posterior parietal cortex (PPC) is an extensive region of the human brain that develops relatively late in development and is proportionally large compared to that of monkeys and prosimian primates. Our ongoing comparative studies have lead to several conclusions about the evolution of this posterior parietal region. In early placental mammals, PPC likely was a small multisensory region much like PPC of extant rodents and tree shrews. In early primates, PPC likely resembled that of prosimian galagos where caudal PPC (PPCc) is visual and rostral PPC (PPCr) has eight or more multisensory domains where electrical stimulation evokes different complex motor behaviors, including reaching, hand-to-mouth, looking, protecting the face or body and grasping. These evoked behaviors depend on connections with functionally matched domains in premotor cortex (PMC) and motor cortex (M1). Domains in each region compete with each other, and a serial arrangement of domains allows different factors to successively influence motor outcomes. Similar arrangements of domains have been retained in New and Old World monkeys, and humans appear to have at least some of these domains. The great expansion and prolonged development of PPC in humans suggest the addition of functionally distinct territories. Across primates we propose that PMC and M1 domains are second and third levels in a number of parallel, interacting networks for mediating and selecting one type of action over others.

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Section: The Organization Of Ppc and Parietal-frontal Sensorimotor Nementioning

confidence: 99%

Evolution of posterior parietal cortex and parietal‐frontal networks for specific actions in primates

Kaas

Stepniewska

2015

J of Comparative Neurology

101

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“…Indeed, although previous decision-making experiments that used visual stimuli revealed an encoding of the stimulus sensory properties (i.e. face vs. house) in the occipital and parietal cortices, around 150ms post-stimulus (Delis et al, 2016; Tu et al, 2017), most of them failed to find sensory-related activity in the premotor cortex (Boussaoud & Wise, 1993; Coallier, Michelet, & Kalaska, 2015; di Pellegrino & Wise, 1991; Nakayama, Yamagata, Tanji, & Hoshi, 2008; Wang et al, 2019). Rather, they showed that the premotor plays a key role in the conversion of sensory information into a choice-related signal (Cisek & Kalaska, 2002; Donner et al, 2009; Wang et al, 2019).…”

Section: Discussionmentioning

confidence: 98%

Prioritized neural processing of social threats during perceptual decision-making

Meaux¹,

Zein

Mennella³

et al. 2019

Preprint

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Socially-relevant signals benefit from prioritized processing, from initial orientation to behavioral choice elaboration. Yet it remains unclear whether such prioritized processing engages specific or similar neural computations as the processing of non-social cues during decision-making. Here, we developed a novel behavioral paradigm in which participants performed two different detection tasks on the same, two-dimensional visual stimuli. We presented morphed facial displays of emotion (from neutral to angry) on top of a morphed colored background (from grey to violet). Participants reported the presence or absence of either emotion (anger) or color (violet) in the stimulus, while ignoring the other task-irrelevant dimension. Importantly, we equalized detection sensitivity across dimensions using an adaptive titration procedure. Computational modeling of electroencephalographic (EEG) activity first revealed that premotor EEG activity scales with the amount of perceptual evidence earlier, around 150ms, when the decision concerns emotion rather than color. Second, participant choice was decoded earlier during emotion (260ms) than color decisions in band-limited EEG power in the same premotor regions. Third, these two effects varied across participants as a function of their social anxiety. Together, these findings indicate that emotion cues benefit from a prioritized neural coding in action-selective brain regions, further supporting their motivational value.

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“…In the last years different groups have addressed the role of PMd in somatomotor decision by employing tasks in which the sensorial instruction required some form of discrimination (establishing which amount of two colours was more present 33,35 ) or could continuously change 13 .…”

Section: Discussionmentioning

confidence: 99%

“…Neural activity of this area represents various properties of the impending movement, including its direction, distance, trajectory, timing and speed 19,20,21,22,23,24,25,26,27,28,29,30,31 , it signals the direction of potential and final reach choices 14 as well the selection of specific rules 32 . Furthermore it reflects conflicts related to the dynamic competition between contemporary alternative movement choices 33,34 , and express a decision process related to the selection of actions based on sensory cues 35 or dynamic sensory signals 34 as well change of mind 36 . Of relevance, PMd contains neural activity that modulates according to movement inhibition 37,38 .…”

Section: Introductionmentioning

confidence: 99%

Visual salience of the stop-signal affects neural dynamics of controlled inhibition

Pani

Giarrocco

Giamundo

et al. 2018

Preprint

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The countermanding or stop-signal task is broadly used to evaluate response inhibition: it sporadically requires to inhibit a movement upon an incoming salient stop-signal.To study the neural basis of arm movements inhibition we combined the approach typically employed for the study of perceptual-decision making with the countermanding task, that is broadly used to evaluate response inhibition To this aim we modified the salience of the stop-signal and we found that this modulation affected the ability to inhibit in macaque monkeys: coherently to what already observed in humans, we found that less salient stimuli deteriorate inhibitory performance. These behavioural results were subtended by neural modulations representing an inhibitory process that started later in time and showed a less steeper dynamic for stimuli difficult to be processed.This study shows that the neural patterns observed when deciding to stop are broadly similar to the neural patterns observed when deciding to act in the literature; thus it is a first step in investigating the perceptual decision making process involved in movement inhibition.

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Dorsal premotor cortex: neural correlates of reach target decisions based on a color-location matching rule and conflicting sensory evidence

Cited by 93 publications

References 128 publications

Evolution of posterior parietal cortex and parietal‐frontal networks for specific actions in primates

Evolution of posterior parietal cortex and parietal‐frontal networks for specific actions in primates

Prioritized neural processing of social threats during perceptual decision-making

Visual salience of the stop-signal affects neural dynamics of controlled inhibition

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