Cognitive control of complex motor behavior in marmoset monkeys

Pomberger, Thomas; Risueno-Segovia, Cristina; Gultekin, Yasemin B.; Dohmen, Deniz; Hage, Steffen R.

doi:10.1038/s41467-019-11714-8

Cited by 20 publications

(23 citation statements)

References 42 publications

(54 reference statements)

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“…The monkeys’ hand movements easily suffice these criteria for volition. In addition, the current and other recent behavioral studies showed that monkeys can also produce vocalizations volitionally, albeit only with considerable cognitive effort ( Hage et al, 2013 ; Hage et al, 2016 ; Pomberger et al, 2019 ). At a neuronal level, the current comparison of cued versus spontaneous vocalizations and hand movements showed impressive and highly significant activity differences; neuronal activity in the frontal lobe remains at baseline level for the monkeys’ spontaneous and non-goal directed vocalizations and hand movements but is strongly modulated for volitional and goal-directed responses.…”

Section: Discussionsupporting

confidence: 51%

Distinct neural networks for the volitional control of vocal and manual actions in the monkey homologue of Broca's area

Gavrilov

Nieder

2021

eLife

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The ventrolateral frontal lobe (Broca's area) of the human brain is crucial in speech production. In macaques, neurons in the ventrolateral prefrontal cortex, the suggested monkey homologue of Broca's area, signal the volitional initiation of vocalizations. We explored whether this brain area became specialized for vocal initiation during primate evolution and trained macaques to alternate between a vocal and manual action in response to arbitrary cues. During task performance, single neurons recorded from the ventrolateral prefrontal cortex and the rostroventral premotor cortex of the inferior frontal cortex predominantly signaled the impending vocal or, to a lesser extent, manual action, but not both. Neuronal activity was specific for volitional action plans and differed during spontaneous movement preparations. This implies that the primate inferior frontal cortex controls the initiation of volitional utterances via a dedicated network of vocal selective neurons that might have been exploited during the evolution of Broca’s area.

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Section: Discussionsupporting

confidence: 51%

Distinct neural networks for the volitional control of vocal and manual actions in the monkey homologue of Broca's area

Gavrilov

Nieder

2021

eLife

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“…This suggests that marmosets are not simply calling more but are specifically producing more calls within the context of active conversations. Third, interactive effects revealed by the model suggests that optimizing communication in these challenging acoustic and social landscapes necessitates a dynamic strategy, one in which marmosets must exert control over both the call structure and the behavior Miller et al, 2009a;Pomberger et al, 2019;Zhao et al, 2019). Consistent with previous experiments (Roy et al, 2011) and results in Experiment 1, the predictability of the scene played a significant role in how marmosets solve the CPP for effective communication.…”

Section: Discussionmentioning

confidence: 99%

“…Results from a Linear Model indicated that these primates did not solely rely on audition to effectively communicate in cocktail parties, but adaptively change their behavior in response to the dynamics of the acoustic scene 44, 45, 46, 47, 48 . To control for acoustic interference, it was necessary to decrease the inter-call interval (ICI) between phees in the Distractor VM conversations which resulted in a systematic change in the periodicity of the Distractor VM conversation (i.e.…”

Section: Discussionmentioning

confidence: 99%

Mechanisms for Communicating in a Marmoset ‘Cocktail Party’

Jovanović¹,

Miller²

2020

Preprint

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A key challenge for audition is parsing the voice of a single speaker amid a cacophony of other voices known as the Cocktail Party Problem (CPP). Despite its prevalence, relatively little remains known about how our simian cousins resolve the CPP for active, natural communication. Here we employed an innovative, multi-speaker paradigm comprising five computer-generated Virtual Monkeys (VM) whose respective vocal behavior could be systematically varied to construct marmoset cocktail parties and tested the impact of specific acoustic scene manipulations on subjects’ natural conversations. Results indicate that marmosets not only employ auditory mechanisms – including attention – for speaker stream segregation, but also selectively change their own vocal behavior in response to the dynamics of the acoustic scene. These findings suggest notable parallels with human audition to solve the CPP and highlight the active role that individuals play to optimize communicative efficacy in complex real-world acoustic scenes.

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“…Previous studies have mapped the afferent connections of the primary motor, dorsal and ventral premotor areas in this species (Burman et al 2014a, b, 2015), but there have been no studies of the putative premotor areas located near the dorsal midline. Given the rapidly developing use of marmosets in studies of motor control (Bakola et al 2015; Roy et al 2016; Tia et al 2017; Walker et al 2017; Ebina et al 2018, 2019; Pomberger et al 2019), improved knowledge of the pattern of interconnections between cortical areas is likely to lead to better models to understand the mechanistic basis of neuronal interactions leading to the planning and execution of movement, as well as the circuit basis of differences in motor behavior.…”

Section: Introductionmentioning

confidence: 99%

Afferent connections of cytoarchitectural area 6M and surrounding cortex in the marmoset: putative homologues of the supplementary and pre-supplementary motor areas

Bakola

Burman

Bednarek³

et al. 2021

Preprint

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Cortical projections to the caudomedial frontal cortex were studied using retrograde tracers in marmosets. We tested the hypothesis that cytoarchitectural area 6M includes homologues of the supplementary and pre-supplementary motor areas (SMA and preSMA) of other primates. We found that, irrespective of the injection sites' location within 6M, over half of the labeled neurons were located in motor and premotor areas. Other connections originated in prefrontal area 8b, ventral anterior and posterior cingulate areas, somatosensory areas (3a and 1-2), and areas on the rostral aspect of the dorsal posterior parietal cortex. Although the origin of afferents was similar, injections in rostral 6M received higher percentages of prefrontal afferents, and fewer somatosensory afferents, compared to caudal injections, compatible with differentiation into SMA and preSMA. Injections rostral to 6M (area 8b) revealed a very different set of connections, with increased emphasis in prefrontal and posterior cingulate afferents, and fewer parietal afferents. The connections of 6M were also quantitatively different from those of M1, dorsal premotor areas, and cingulate motor area 24d. These results show that the cortical motor control circuit is conserved in simian primates, indicating that marmosets can be valuable models for studying movement planning and control.

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Cognitive control of complex motor behavior in marmoset monkeys

Cited by 20 publications

References 42 publications

Distinct neural networks for the volitional control of vocal and manual actions in the monkey homologue of Broca's area

Distinct neural networks for the volitional control of vocal and manual actions in the monkey homologue of Broca's area

Mechanisms for Communicating in a Marmoset ‘Cocktail Party’

Afferent connections of cytoarchitectural area 6M and surrounding cortex in the marmoset: putative homologues of the supplementary and pre-supplementary motor areas

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