Motor cortical dynamics are shaped by multiple distinct subspaces during naturalistic behavior

Conti, Sara; Badi, Marion; Bogaard, Andrew; Barra, Beatrice; Wurth, Sophie; Bloch, Jocelyne; Courtine, Grégoire; Micera, Silvestro; Capogrosso, Marco; Milekovic, Tomislav

doi:10.1101/2020.07.30.228767

Cited by 26 publications

(53 citation statements)

References 59 publications

(178 reference statements)

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“…For example, this is true in primary somatosensory cortex during cycling 4 and (unsurprisingly) in primary visual cortex 4,33 . Tangling will also be high when unpredictable external inputs dominate the motor cortex response 34 . For example, autonomous dynamics provide a poorer fit to the data during grasping 35 .…”

Section: Discussionmentioning

confidence: 99%

Motor cortex activity across movement speeds is predicted by network-level strategies for generating muscle activity

Saxena

Russo

Cunningham

et al. 2021

Preprint

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Learned movements can be skillfully performed at different paces. What neural strategies produce this flexibility? Can they be predicted and understood by network modeling? We trained monkeys to perform a cycling task at different speeds, and trained artificial recurrent networks to generate the empirical muscle-activity patterns. Network solutions reflected the principle that smooth well-behaved dynamics require low trajectory tangling, and yielded quantitative and qualitative predictions. To evaluate predictions, we recorded motor cortex population activity during the same task. Responses supported the hypothesis that the dominant neural signals reflect not muscle activity, but network-level strategies for generating muscle activity. Single-neuron responses were better accounted for by network activity than by muscle activity. Similarly, neural population trajectories shared their organization not with muscle trajectories, but with network solutions. Thus, cortical activity could be understood based on the need to generate muscle activity via dynamics that allow smooth, robust control over movement speed.

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Section: Discussionmentioning

confidence: 99%

Motor cortex activity across movement speeds is predicted by network-level strategies for generating muscle activity

Saxena

Russo

Cunningham

et al. 2021

Preprint

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“…Recent methods that exploit simultaneous recordings from multiple brain areas provide a promising tool to identify input signals to a given circuit (Kohn et al, 2020; Perich et al, 2018; Semedo et al, 2019). Using these techniques, Perich et al, (2020) provides evidence of a communication subspace between the somatosensory and motor cortices that contributes to a substantial amount of the variance in MC, consistent with inputs playing a key role in motor cortical dynamics. Studies that perturb neural circuits through stimulation, cooling probes or optogenetics will also provide valuable insight into how inputs are transformed by MC (Guo et al, 2020; Hore et al, 1977; Li et al, 2016; Nashef et al, 2018, 2019; Perich et al, 2020; Svoboda and Li, 2018; Takei et al, 2020).…”

Section: Discussionmentioning

confidence: 77%

“…Using these techniques, Perich et al, (2020) provides evidence of a communication subspace between the somatosensory and motor cortices that contributes to a substantial amount of the variance in MC, consistent with inputs playing a key role in motor cortical dynamics. Studies that perturb neural circuits through stimulation, cooling probes or optogenetics will also provide valuable insight into how inputs are transformed by MC (Guo et al, 2020; Hore et al, 1977; Li et al, 2016; Nashef et al, 2018, 2019; Perich et al, 2020; Svoboda and Li, 2018; Takei et al, 2020). For example, deactivating cerebellar output can substantially impact preparatory activity in the MC and feedback responses to mechanical loads (Chabrol et al, 2019; Conrad et al, 1974; Gao et al, 2018; Meyer-Lohmann et al, 1975).…”

Section: Discussionmentioning

confidence: 77%

Rotational dynamics in motor cortex are consistent with a feedback controller

Kalidindi

Cross

Lillicrap

et al. 2020

Preprint

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SummaryRecent studies hypothesize that motor cortical (MC) dynamics are generated largely through its recurrent connections based on observations that MC activity exhibits rotational structure. However, behavioural and neurophysiological studies suggest that MC behaves like a feedback controller where continuous sensory feedback and interactions with other brain areas contribute substantially to MC processing. We investigated these apparently conflicting theories by building recurrent neural networks that controlled a model arm and received sensory feedback about the limb. Networks were trained to counteract perturbations to the limb and to reach towards spatial targets. Network activities and sensory feedback signals to the network exhibited rotational structure even when the recurrent connections were removed. Furthermore, neural recordings in monkeys performing similar tasks also exhibited rotational structure not only in MC but also in somatosensory cortex. Our results argue that rotational structure may reflect dynamics throughout voluntary motor circuits involved in online control of motor actions.HighlightsNeural networks with sensory feedback generate rotational dynamics during simulated posture and reaching tasksRotational dynamics are observed even without recurrent connections in the networkSimilar dynamics are observed not only in motor cortex, but also in somatosensory cortex of non-huma n primates as well as sensory feedback signalsResults highlight rotational dynamics may reflect internal dynamics, external inputs or any combination of the two.

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“…Estimating population-wide inputs at this scale produces an unprecedented view into multi-region interactions. Furthermore, CURBD scales readily beyond two interconnected regions to brain-wide interactions 19 , circumventing a limitation of many existing approaches [23][24][25][26] . In a single-layer network, each source unit connects to a target unit with a directed interaction weight given by the vector J.…”

Section: Current-based Decomposition Of Multi-region Datasets Using Rmentioning

confidence: 99%

Inferring brain-wide interactions using data-constrained recurrent neural network models

Arlt

Soares

Young

et al. 2020

Preprint

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Behavior arises from the coordinated activity of numerous anatomically and functionally distinct brain regions. Modern experimental tools allow unprecedented access to large neural populations spanning many interacting regions brain-wide. Yet, understanding such large-scale datasets necessitates both scalable computational models to extract meaningful features of interregion communication and principled theories to interpret those features. Here, we introduce Current-Based Decomposition (CURBD), an approach for inferring brain-wide interactions using data-constrained recurrent neural network models that directly reproduce experimentally-obtained neural data. CURBD leverages the functional interactions inferred by such models to reveal directional currents between multiple brain regions. We first show that CURBD accurately isolates inter-region currents in simulated networks with known dynamics. We then apply CURBD to multi-region neural recordings obtained from mice during running, macaques during Pavlovian conditioning, and humans during memory retrieval to demonstrate the widespread applicability of CURBD to untangle brain-wide interactions underlying behavior from a variety of neural datasets.

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Motor cortical dynamics are shaped by multiple distinct subspaces during naturalistic behavior

Cited by 26 publications

References 59 publications

Motor cortex activity across movement speeds is predicted by network-level strategies for generating muscle activity

Motor cortex activity across movement speeds is predicted by network-level strategies for generating muscle activity

Rotational dynamics in motor cortex are consistent with a feedback controller

Inferring brain-wide interactions using data-constrained recurrent neural network models

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