Neural Population Dynamics during Reaching Are Better Explained by a Dynamical System than Representational Tuning

Michaels, Jonathan A.; Dann, Benjamin; Scherberger, Hansjörg

doi:10.1371/journal.pcbi.1005175

Cited by 144 publications

(177 citation statements)

References 54 publications

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“…The experimental data were best reproduced by the simplest RNN connectivity that allowed the network to output the measured muscle activity. A similar result was subsequently achieved with an RNN trained to output the x and y components of hand velocity for a delayed center-out reach task (Michaels et al, 2016). …”

Section: Emergence Of Neural Manifolds Through Learningsupporting

confidence: 53%

“…The concept of the neural manifold and its associated latent variables has been used in a series of recent studies that replace the search for movement representation by single neurons to consider instead movement planning and execution based on the activation of a few neural modes (Ahrens et al, 2012; Bruno et al, 2015; Churchland et al, 2012, 2010a, 2010b; Churchland and Shenoy, 2007; Elsayed et al, 2016; Kaufman et al, 2016, 2014; Michaels et al, 2016; Overduin et al, 2015; Sadtler et al, 2014; Santhanam et al, 2009; Sussillo et al, 2015). …”

Section: From Single Neurons To Neural Manifoldsmentioning

confidence: 99%

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Neural Manifolds for the Control of Movement

Gallego

Perich

Miller

et al. 2017

Neuron

464

475

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The analysis of neural dynamics in several brain cortices has consistently uncovered low-dimensional manifolds that capture a significant fraction of neural variability. These neural manifolds are spanned by specific patterns of correlated neural activity, the “neural modes.” We discuss a model for neural control of movement in which the timedependent activation of these neural modes is the generator of motor behavior. This manifold-based view of motor cortex may lead to a better understanding of how the brain controls movement.

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Section: Emergence Of Neural Manifolds Through Learningsupporting

confidence: 53%

Section: From Single Neurons To Neural Manifoldsmentioning

confidence: 99%

Neural Manifolds for the Control of Movement

Gallego

Perich

Miller

et al. 2017

Neuron

464

475

View full text Add to dashboard Cite

show abstract

“…Recent physiological and theoretical investigations suggest that the neural state in motor cortex obeys smooth dynamics 20,24,26,27,29,58,59 . Smooth dynamics imply that neural trajectories should not be ‘tangled’: similar neural states, either during different movements or at different times for the same movement, should not be associated with different derivatives.…”

Section: Resultsmentioning

confidence: 99%

“…Yet responses of motor cortical neurons can differ from what would be expected if they encode muscle force, motivating the hypothesis that motor cortex primarily encodes movement velocity or direction 3,17–19 . Alternatively, it has been proposed that non-muscle-like response features may be explained by network or feedback dynamics 20–30 . Many studies, largely focused on reaching, have produced little consensus 31–42 .…”

Section: Introductionmentioning

confidence: 99%

Motor Cortex Embeds Muscle-like Commands in an Untangled Population Response

Russo

Bittner

Perkins

et al. 2018

Neuron

244

355

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Summary Primate motor cortex projects to spinal interneurons and motor neurons, suggesting that motor cortex activity may be dominated by muscle-like commands. Extensive observations during reaching lend support to this view, but evidence remains ambiguous and much-debated. To provide a different perspective, we employed a novel behavioral paradigm that affords extensive comparison between time-evolving neural and muscle activity. We found that single motor cortex neurons displayed many muscle-like properties, but the structure of population activity was not muscle-like. Unlike muscle activity, neural activity was structured to avoid ‘tangling’: moments where similar activity patterns led to dissimilar future patterns. Avoidance of tangling was present across tasks and species. Network models revealed a potential reason for this consistent feature: low tangling confers noise robustness. Finally, we were able to predict motor cortex activity from muscle activity alone, by leveraging the hypothesis that muscle-like commands are embedded in additional structure that yields low tangling.

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“…These observations are incompatible with static and trial-averaged tuning frameworks for representation of motor responses, as averaging can mask the inherent trial-to-trial variability of neuronal activity and motor response, and thus their relationship on a trial-by-trial basis (Afshar et al, 2011;Briggman et al, 2005;Churchland and Kiani, 2016;Wei et al, 2019). Frameworks based on dynamical systems-in which the movement-related neuronal dynamics are described by differential equations whose initial conditions are set by the preparatory activity-have been shown to provide a better model than trial-averaged representation frameworks for how motor behavior emerges from pre-motor neuronal population dynamics (Churchland et al, 2010;Mante et al, 2013;Michaels et al, 2016;Pandarinath et al, 2018;Shenoy et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

Cerebellar neurodynamics during motor planning predict decision timing and outcome on single-trial level

Lin

Helmreich

Schlumm

et al. 2019

Preprint

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The neuronal basis of goal-directed behavior requires interaction of multiple separated brain regions. How subcortical regions and their interactions with brain-wide activity are involved in action selection is less understood. We have investigated this question by developing an assay based on whole-brain volumetric calcium imaging using light-field microscopy combined with an operant-conditioning task in larval zebrafish. We find global and recurring dynamics of brain states to exhibit pre-motor bifurcations towards mutually exclusive decision outcomes which arises from a spatially distributed network. Within this network the cerebellum shows a particularly strong pre-motor activity, predictive of both the timing and outcome of behavior up to ~10 seconds before movement initiation. Furthermore, on the single-trial level, decision directions can be inferred from the difference neuroactivity between the ipsilateral and contralateral hemispheres, while the decision time can be quantitatively predicted by the rate of bihemispheric population ramping activity. Our results point towards a cognitive role of the cerebellum and its importance in motor planning. KEYWORDSCerebellum, decision making, action selection, motor planning, whole-brain calcium imaging, population ramping activity, zebrafish Recurring brain state dynamics capture representation of heat and show bifurcation for different behavioral outcomesVolumetric reconstruction of the LFM data (see also Movie S1), followed by neuronal signal extraction using our established data processing pipeline (Prevedel et al., 2014), allowed us to obtain neuronal activity traces from ~5000 of the most active neurons across the entire brain. Figure 2 shows the data for an example

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Neural Population Dynamics during Reaching Are Better Explained by a Dynamical System than Representational Tuning

Cited by 144 publications

References 54 publications

Neural Manifolds for the Control of Movement

Neural Manifolds for the Control of Movement

Motor Cortex Embeds Muscle-like Commands in an Untangled Population Response

Cerebellar neurodynamics during motor planning predict decision timing and outcome on single-trial level

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