Computing by Robust Transience: How the Fronto-Parietal Network Performs Sequential, Category-Based Decisions

Decision making involves dynamic interplay between internal judgements and external perception, which has been investigated in delayed match-to-category (DMC) experiments. Our analysis of neural recordings shows that, during DMC tasks, LIP and PFC neurons demonstrate mixed, time-varying, and heterog...

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Published inNeuron (Cambridge, Mass.) Vol. 93; no. 6; pp. 1504 - 1517.e4
Main Authors Chaisangmongkon, Warasinee, Swaminathan, Sruthi K., Freedman, David J., Wang, Xiao-Jing
Format Journal Article
LanguageEnglish
Published United States Elsevier Inc 22.03.2017
Elsevier Limited
Subjects
Animals
category learning
Decision making
Decision Making - physiology
delayed match-to-category task
hessian-free algorithm
lateral intraparietal cortex
LIP
Macaca mulatta
Male
Memory
Models, Neurological
Neural networks
Neural Networks (Computer)
Neurons
Neurons - physiology
Parietal Lobe - physiology
PFC
Population levels
prefrontal cortex
Prefrontal Cortex - physiology
recurrent neural network
Studies
Tunnels
working memory
category learning
LIP
recurrent neural network
working memory
prefrontal cortex
decision making
PFC
hessian-free algorithm
delayed match-to-category task
lateral intraparietal cortex
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Abstract Decision making involves dynamic interplay between internal judgements and external perception, which has been investigated in delayed match-to-category (DMC) experiments. Our analysis of neural recordings shows that, during DMC tasks, LIP and PFC neurons demonstrate mixed, time-varying, and heterogeneous selectivity, but previous theoretical work has not established the link between these neural characteristics and population-level computations. We trained a recurrent network model to perform DMC tasks and found that the model can remarkably reproduce key features of neuronal selectivity at the single-neuron and population levels. Analysis of the trained networks elucidates that robust transient trajectories of the neural population are the key driver of sequential categorical decisions. The directions of trajectories are governed by network self-organized connectivity, defining a “neural landscape” consisting of a task-tailored arrangement of slow states and dynamical tunnels. With this model, we can identify functionally relevant circuit motifs and generalize the framework to solve other categorization tasks. •Recurrent networks trained to perform DMC tasks exhibit robust transience dynamics•Dynamics consist of stable and slow states connected by robust trajectory tunnels•Models’ neural activities are remarkably similar to recordings from LIP and PFC•Trained RNNs replicate categorization studies with multiple categories Chaisangmongkon et al. present a recurrent neural network model of primate fronto-parietal network that can capture various phenomena from neurophysiological experiments in delayed match-to-category tasks.
AbstractList Decision making involves dynamic interplay between internal judgements and external perception, which has been investigated in delayed match-to-category (DMC) experiments. Our analysis of neural recordings shows that, during DMC tasks, LIP and PFC neurons demonstrate mixed, time-varying, and heterogeneous selectivity, but previous theoretical work has not established the link between these neural characteristics and population-level computations. We trained a recurrent network model to perform DMC tasks and found that the model can remarkably reproduce key features of neuronal selectivity at the single-neuron and population levels. Analysis of the trained networks elucidates that robust transient trajectories of the neural population are the key driver of sequential categorical decisions. The directions of trajectories are governed by network self-organized connectivity, defining a "neural landscape" consisting of a task-tailored arrangement of slow states and dynamical tunnels. With this model, we can identify functionally relevant circuit motifs and generalize the framework to solve other categorization tasks.Decision making involves dynamic interplay between internal judgements and external perception, which has been investigated in delayed match-to-category (DMC) experiments. Our analysis of neural recordings shows that, during DMC tasks, LIP and PFC neurons demonstrate mixed, time-varying, and heterogeneous selectivity, but previous theoretical work has not established the link between these neural characteristics and population-level computations. We trained a recurrent network model to perform DMC tasks and found that the model can remarkably reproduce key features of neuronal selectivity at the single-neuron and population levels. Analysis of the trained networks elucidates that robust transient trajectories of the neural population are the key driver of sequential categorical decisions. The directions of trajectories are governed by network self-organized connectivity, defining a "neural landscape" consisting of a task-tailored arrangement of slow states and dynamical tunnels. With this model, we can identify functionally relevant circuit motifs and generalize the framework to solve other categorization tasks.
Decision making involves dynamic interplay between internal judgements and external perception, which has been investigated in delayed match-to-category (DMC) experiments. Our analysis of neural recordings shows that, during DMC tasks, LIP and PFC neurons demonstrate mixed, time-varying, and heterogeneous selectivity, but previous theoretical work has not established the link between these neural characteristics and population-level computations. We trained a recurrent network model to perform DMC tasks and found that the model can remarkably reproduce key features of neuronal selectivity at the single-neuron and population levels. Analysis of the trained networks elucidates that robust transient trajectories of the neural population are the key driver of sequential categorical decisions. The directions of trajectories are governed by network self-organized connectivity, defining a "neural landscape" consisting of a task-tailored arrangement of slow states and dynamical tunnels. With this model, we can identify functionally relevant circuit motifs and generalize the framework to solve other categorization tasks.
SummaryDecision making involves dynamic interplay between internal judgements and external perception, which has been investigated in delayed match-to-category (DMC) experiments. Our analysis of neural recordings shows that, during DMC tasks, LIP and PFC neurons demonstrate mixed, time-varying, and heterogeneous selectivity, but previous theoretical work has not established the link between these neural characteristics and population-level computations. We trained a recurrent network model to perform DMC tasks and found that the model can remarkably reproduce key features of neuronal selectivity at the single-neuron and population levels. Analysis of the trained networks elucidates that robust transient trajectories of the neural population are the key driver of sequential categorical decisions. The directions of trajectories are governed by network self-organized connectivity, defining a “neural landscape” consisting of a task-tailored arrangement of slow states and dynamical tunnels. With this model, we can identify functionally relevant circuit motifs and generalize the framework to solve other categorization tasks.
Decision making involves dynamic interplay between internal judgements and external perception, which has been investigated in delayed match-to-category (DMC) experiments. Our analysis of neural recordings shows that, during DMC tasks, LIP and PFC neurons demonstrate mixed, time-varying, and heterogeneous selectivity, but previous theoretical work has not established the link between these neural characteristics and population-level computations. We trained a recurrent network model to perform DMC tasks and found that the model can remarkably reproduce key features of neuronal selectivity at the single-neuron and population levels. Analysis of the trained networks elucidates that robust transient trajectories of the neural population are the key driver of sequential categorical decisions. The directions of trajectories are governed by network self-organized connectivity, defining a “neural landscape” consisting of a task-tailored arrangement of slow states and dynamical tunnels. With this model, we can identify functionally relevant circuit motifs and generalize the framework to solve other categorization tasks. •Recurrent networks trained to perform DMC tasks exhibit robust transience dynamics•Dynamics consist of stable and slow states connected by robust trajectory tunnels•Models’ neural activities are remarkably similar to recordings from LIP and PFC•Trained RNNs replicate categorization studies with multiple categories Chaisangmongkon et al. present a recurrent neural network model of primate fronto-parietal network that can capture various phenomena from neurophysiological experiments in delayed match-to-category tasks.
Author Chaisangmongkon, Warasinee
Freedman, David J.
Wang, Xiao-Jing
Swaminathan, Sruthi K.
AuthorAffiliation 3 The University of Chicago, Department of Neurobiology, Chicago, IL
4 Grossman Institute for Neuroscience, Quantitative Biology, and Human Behavior, Chicago, IL
2 Institute of Field Robotics, King Mongkut’s University of Technology Thonburi, Bangkok, Thailand
6 NYU-ECNU Joint Institute of Brain and Cognitive Science, NYU-Shanghai, Shanghai, China
5 New York University, Center for Neural Science, New York, New York
1 Yale University School of Medicine, Department of Neurobiology and Kavli Institute for Neuroscience, New Haven, CT
AuthorAffiliation_xml – name: 2 Institute of Field Robotics, King Mongkut’s University of Technology Thonburi, Bangkok, Thailand
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  surname: Wang
  fullname: Wang, Xiao-Jing
  email: xjwang@nyu.edu
  organization: Department of Neurobiology and Kavli Institute for Neuroscience, Yale University School of Medicine, New Haven, CT 06511, USA
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Keywords category learning
LIP
recurrent neural network
working memory
prefrontal cortex
decision making
PFC
hessian-free algorithm
delayed match-to-category task
lateral intraparietal cortex
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Snippet Decision making involves dynamic interplay between internal judgements and external perception, which has been investigated in delayed match-to-category (DMC)...
SummaryDecision making involves dynamic interplay between internal judgements and external perception, which has been investigated in delayed match-to-category...
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StartPage 1504
SubjectTerms Animals
category learning
Decision making
Decision Making - physiology
delayed match-to-category task
hessian-free algorithm
lateral intraparietal cortex
LIP
Macaca mulatta
Male
Memory
Models, Neurological
Neural networks
Neural Networks (Computer)
Neurons
Neurons - physiology
Parietal Lobe - physiology
PFC
Population levels
prefrontal cortex
Prefrontal Cortex - physiology
recurrent neural network
Studies
Tunnels
working memory
Title Computing by Robust Transience: How the Fronto-Parietal Network Performs Sequential, Category-Based Decisions
URI https://dx.doi.org/10.1016/j.neuron.2017.03.002
https://www.ncbi.nlm.nih.gov/pubmed/28334612
https://www.proquest.com/docview/1884247376
https://www.proquest.com/docview/1881264126
https://pubmed.ncbi.nlm.nih.gov/PMC5586485
Volume 93
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