Learning multiple variable-speed sequences in striatum via cortical tutoring

Murray, James; Escola, Sean

doi:10.7554/elife.26084

Cited by 97 publications

(87 citation statements)

References 103 publications

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“…The read-out neurons learn spike sequences in a supervised manner, and the supervisor sequence is encoded into the read-out weight matrix. Bringing together elements from different studies [18,22,32,37], our model exploits a clock-like dynamics encoded in the RNN to learn a mapping to read-out neurons so as to perform the computational task of learning and replaying spatiotemporal sequences. We illustrated the application of our scheme on a simple non-Markovian state transition sequence, a combination of two such simple sequences, and a time series with more complex dynamics from bird singing.…”

Section: Discussionmentioning

confidence: 99%

“…Another example is sequential dynamics, where longer time scales are obtained by clusters of neurons that activate each other in a sequence. This sequential dynamics can emerge by a specific connectivity in the excitatory neurons [16,17] or in the inhibitory neurons [18,19]. However, it is unclear how the brain learns these dynamics, as most of the current approaches use non biologically plausible ways to set or "train" the synaptic weights.…”

Section: Introductionmentioning

confidence: 99%

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Learning spatiotemporal signals using a recurrent spiking network that discretizes time

2020

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Learning to produce spatiotemporal sequences is a common task that the brain has to solve. The same neurons may be used to produce different sequential behaviours. The way the brain learns and encodes such tasks remains unknown as current computational models do not typically use realistic biologically-plausible learning. Here, we propose a model where a spiking recurrent network of excitatory and inhibitory spiking neurons drives a read-out layer: the dynamics of the driver recurrent network is trained to encode time which is then mapped through the read-out neurons to encode another dimension, such as space or a phase. Different spatiotemporal patterns can be learned and encoded through the synaptic weights to the read-out neurons that follow common Hebbian learning rules. We demonstrate that the model is able to learn spatiotemporal dynamics on time scales that are behaviourally relevant and we show that the learned sequences are robustly replayed during a regime of spontaneous activity.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Learning spatiotemporal signals using a recurrent spiking network that discretizes time

2020

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“…Third, although we assumed that recurrent interactions were fixed during our experiment, it is almost certain that synaptic plasticity plays a key role as the network learns to incorporate context-dependent inputs (Kleim et al 1998;Pascual-Leone et al 1995;Yang et al 2014;Xu et al 2009) . Finally, the persistent separation of neural trajectories observed in DMFC allowed for a dynamical account which did not require invocation of "hidden" network states to explain timing behavior (Buonomano & Merzenich 1995;Karmarkar & Buonomano 2007;Murray & Escola 2017) or contextual control (Stokes et al 2013) . However, it is possible that factors not measured by extracellular recording (e.g., short-term synaptic plasticity) contribute to both contextual control and timing behavior in RSG and similar tasks.…”

Section: Discussionmentioning

confidence: 99%

Flexible sensorimotor computations through rapid reconfiguration of cortical dynamics

Remington

Narain

Hosseini

et al. 2018

Preprint

126

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SummarySensorimotor computations can be flexibly adjusted according to internal states and contextual inputs. The mechanisms supporting this flexibility are not understood. Here, we tested the utility of a dynamical system perspective to approach this problem. In a dynamical system whose state is determined by interactions among neurons, computations can be rapidly and flexibly reconfigured by controlling the system‘s inputs and initial conditions. To investigate whether the brain employs such control strategies, we recorded from the dorsomedial frontal cortex (DMFC) of monkeys trained to measure time intervals and subsequently produce timed motor responses according to multiple context-specific stimulus-response rules. Analysis of the geometry of neural states revealed a control mechanism that relied on the system‘s inputs and initial conditions. A tonic input specified by the behavioral context adjusted firing rates throughout each trial, while the dynamics in the measurement epoch allowed the system to establish initial conditions for the ensuing production epoch. This initial condition in turn set the speed of neural dynamics in the production epoch allowing the animal to aim for the target interval. These results provide evidence that the language of dynamical systems can be used to parsimoniously link brain activity to sensorimotor computations.

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“…Network models with clustered architecture provide a parsimonious explanation for the state sequences that have been observed ubiquitously in alert mammalian cortex, during both task engagement 17,18,46,47 and inter-trial periods. 11,39,40 In addition, this type of models accounts for various physiological observations such as stimulus-induced reduction of trial-to-trial variability 11,14,15,48 , neural dimensionality 16 , and firing rate multistability 11 (see also 49,50 ). In particular, models with metastable attractors have been used to explain the state sequences observed in rodent gustatory cortex during taste processing and decision making 11,45,51 .…”

Section: Clustered Connectivity and Metastable Statesmentioning

confidence: 99%

Expectation-induced modulation of metastable activity underlies faster coding of sensory stimuli

Mazzucato

Camera

Fontanini

et al. 2017

Preprint

148

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1Sensory stimuli can be recognized more rapidly when they are expected. This 2 phenomenon depends on expectation affecting the cortical processing of sensory 3 information. However, virtually nothing is known on the mechanisms responsible for 4 the effects of expectation on sensory networks. Here, we report a novel computational 5 mechanism underlying the expectation-dependent acceleration of coding observed in 6 the gustatory cortex (GC) of alert rats. We use a recurrent spiking network model with a 7 clustered architecture capturing essential features of cortical activity, including the 8 metastable activity observed in GC before and after gustatory stimulation. Relying both 9 on network theory and computer simulations, we propose that expectation exerts its 10 function by modulating the intrinsically generated dynamics preceding taste delivery. 11Our model, whose predictions are confirmed in the experimental data, demonstrates 12 how the modulation of intrinsic metastable activity can shape sensory coding and 13 mediate cognitive processes such as the expectation of relevant events. Altogether, these 14 results provide a biologically plausible theory of expectation and ascribe a new 15 functional role to intrinsically generated, metastable activity. 16 17

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Learning multiple variable-speed sequences in striatum via cortical tutoring

Cited by 97 publications

References 103 publications

Learning spatiotemporal signals using a recurrent spiking network that discretizes time

Learning spatiotemporal signals using a recurrent spiking network that discretizes time

Flexible sensorimotor computations through rapid reconfiguration of cortical dynamics

Expectation-induced modulation of metastable activity underlies faster coding of sensory stimuli

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