Your search keyword '"Ashok Litwin-Kumar"' showing total 63 results

51. Balanced neural architecture and the idling brain.

Author

Brent Doiron and Ashok Litwin-Kumar

Published

2014

52. The mechanics of state-dependent neural correlations

Author

Brent Doiron, Ashok Litwin-Kumar, Krešimir Josić, Robert Rosenbaum, and Gabriel Koch Ocker

Subjects

0301 basic medicine, Computer science, Spike train, Models, Neurological, Population, Article, Arousal, 03 medical and health sciences, 0302 clinical medicine, Neural Pathways, Feature (machine learning), medicine, Biological neural network, Animals, education, Feedback, Physiological, Neurons, education.field_of_study, Computational neuroscience, General Neuroscience, Feed forward, 030104 developmental biology, medicine.anatomical_structure, Neuron, Neuroscience, 030217 neurology & neurosurgery

Abstract

Simultaneous recordings from large neural populations are becoming increasingly common. An important feature of the population activity are the trial-to-trial correlated fluctuations of the spike train outputs of recorded neuron pairs. Like the firing rate of single neurons, correlated activity can be modulated by a number of factors, from changes in arousal and attentional state to learning and task engagement. However, the network mechanisms that underlie these changes are not fully understood. We review recent theoretical results that identify three separate biophysical mechanisms that modulate spike train correlations: changes in input correlations, internal fluctuations, and the transfer function of single neurons. We first examine these mechanisms in feedforward pathways, and then show how the same approach can explain the modulation of correlations in recurrent networks. Such mechanistic constraints on the modulation of population activity will be important in statistical analyses of high dimensional neural data.

Published

2016

53. Evolving the Olfactory System

Author

Peter Y. Wang, Yi Sun, Guangyu Robert Yang, Richard Axel, Larry F. Abbott, and Ashok Litwin-Kumar

Subjects

Olfactory system, Biology, Neuroscience

Published

2019

54. The complete connectome of a learning and memory center in an insect brain

Author

Ingrid Andrade, Marta Zlatic, Richard D. Fetter, Andreas S. Thum, Feng Li, Katharina Eichler, Ashok Litwin-Kumar, James W Truman, Carey E. Priebe, Claire Eschbach, Albert Cardona, Casey M Schneider-Mizell, Timo Saumweber, Youngser Park, Bertram Gerber, Annina Huser, Larry F. Abbott, Eichler, Katharina [0000-0002-7833-8621], Zlatic, Marta [0000-0002-3149-2250], Cardona Torrens, Albert [0000-0003-4941-6536], and Apollo - University of Cambridge Repository

Subjects

Kenyon cell, Computer science, Stimulus (physiology), 03 medical and health sciences, 0302 clinical medicine, Memory, Neural Pathways, medicine, Connectome, Animals, Reinforcement, Mushroom Bodies, 030304 developmental biology, Feedback, Physiological, 0303 health sciences, Brain, Content-addressable memory, medicine.anatomical_structure, Drosophila melanogaster, nervous system, Larva, Mushroom bodies, Synapses, Female, Neuron, Neuroscience, 030217 neurology & neurosurgery

Abstract

Associating stimuli with positive or negative reinforcement is essential for survival, but a complete wiring diagram of a higherorder circuit supporting associative memory has not been previously available. We reconstructed one such circuit at synaptic resolution, theDrosophilalarval mushroom body, and found that most Kenyon cells integrate random combinations of inputs but a subset receives stereotyped inputs from single projection neurons. This organization maximizes performance of a model output neuron on a stimulus discrimination task. We also report a novel canonical circuit in each mushroom body compartment with previously unidentified connections: reciprocal Kenyon cell to modulatory neuron connections, modulatory neuron to output neuron connections, and a surprisingly high number of recurrent connections between Kenyon cells. Stereotyped connections between output neurons could enhance the selection of learned responses. The complete circuit map of the mushroom body should guide future functional studies of this learning and memory center.

Published

2017

55. Slow dynamics and high variability in balanced cortical networks with clustered connections

Author

Brent Doiron and Ashok Litwin-Kumar

Subjects

Cerebral Cortex, Neurons, Quantitative Biology::Neurons and Cognition, Chemistry, General Neuroscience, Models, Neurological, Dynamics (mechanics), High variability, Cortical architecture, Action Potentials, Article, Cortex (botany), Nonlinear Dynamics, Excitatory postsynaptic potential, Animals, Cluster Analysis, Humans, Computer Simulation, Nerve Net, Cluster analysis, Neuroscience

Abstract

Anatomical studies demonstrate that excitatory connections in cortex are not uniformly distributed across a network but instead exhibit clustering into groups of highly connected neurons. The implications of clustering for cortical activity are unclear. We studied the effect of clustered excitatory connections on the dynamics of neuronal networks that exhibited high spike time variability owing to a balance between excitation and inhibition. Even modest clustering substantially changed the behavior of these networks, introducing slow dynamics during which clusters of neurons transiently increased or decreased their firing rate. Consequently, neurons exhibited both fast spiking variability and slow firing rate fluctuations. A simplified model shows how stimuli bias networks toward particular activity states, thereby reducing firing rate variability as observed experimentally in many cortical areas. Our model thus relates cortical architecture to the reported variability in spontaneous and evoked spiking activity.

Published

2012

56. Correlated neural variability in persistent state networks

Author

Ashok Litwin-Kumar, Amber Polk, and Brent Doiron

Subjects

Neural variability, Elementary cognitive task, Nerve net, Models, Neurological, Population, Action Potentials, Stimulus (physiology), Correlation, Attractor, medicine, Animals, Humans, education, Mathematics, Neurons, education.field_of_study, Multidisciplinary, Quantitative Biology::Neurons and Cognition, business.industry, Biological Sciences, Memory, Short-Term, medicine.anatomical_structure, Stochastic drift, Artificial intelligence, Nerve Net, business, Neuroscience, Algorithms

Abstract

Neural activity that persists long after stimulus presentation is a biological correlate of short-term memory. Variability in spiking activity causes persistent states to drift over time, ultimately degrading memory. Models of short-term memory often assume that the input fluctuations to neural populations are independent across cells, a feature that attenuates population-level variability and stabilizes persistent activity. However, this assumption is at odds with experimental recordings from pairs of cortical neurons showing that both the input currents and output spike trains are correlated. It remains unclear how correlated variability affects the stability of persistent activity and the performance of cognitive tasks that it supports. We consider the stochastic long-timescale attractor dynamics of pairs of mutually inhibitory populations of spiking neurons. In these networks, persistent activity was less variable when correlated variability was globally distributed across both populations compared with the case when correlations were locally distributed only within each population. Using a reduced firing rate model with a continuum of persistent states, we show that, when input fluctuations are correlated across both populations, they drive firing rate fluctuations orthogonal to the persistent state attractor, thereby causing minimal stochastic drift. Using these insights, we establish that distributing correlated fluctuations globally as opposed to locally improves network's performance on a two-interval, delayed response discrimination task. Our work shows that the correlation structure of input fluctuations to a network is an important factor when determining long-timescale, persistent population spiking activity.

Published

2012

57. Self-Organization of Microcircuits in Networks of Spiking Neurons with Plastic Synapses

Author

Ashok Litwin-Kumar, Brent Doiron, and Gabriel Koch Ocker

Subjects

Models, Neurological, Nonsynaptic plasticity, Action Potentials, Biology, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Homeostatic plasticity, Metaplasticity, Genetics, Molecular Biology, lcsh:QH301-705.5, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Spiking neural network, Neurons, 0303 health sciences, Synaptic scaling, Neuronal Plasticity, Ecology, Quantitative Biology::Neurons and Cognition, business.industry, Computational Biology, Network dynamics, Hebbian theory, Computational Theory and Mathematics, lcsh:Biology (General), Modeling and Simulation, Synaptic plasticity, Synapses, Artificial intelligence, Nerve Net, business, Neuroscience, 030217 neurology & neurosurgery, Research Article

Abstract

The synaptic connectivity of cortical networks features an overrepresentation of certain wiring motifs compared to simple random-network models. This structure is shaped, in part, by synaptic plasticity that promotes or suppresses connections between neurons depending on their joint spiking activity. Frequently, theoretical studies focus on how feedforward inputs drive plasticity to create this network structure. We study the complementary scenario of self-organized structure in a recurrent network, with spike timing-dependent plasticity driven by spontaneous dynamics. We develop a self-consistent theory for the evolution of network structure by combining fast spiking covariance with a slow evolution of synaptic weights. Through a finite-size expansion of network dynamics we obtain a low-dimensional set of nonlinear differential equations for the evolution of two-synapse connectivity motifs. With this theory in hand, we explore how the form of the plasticity rule drives the evolution of microcircuits in cortical networks. When potentiation and depression are in approximate balance, synaptic dynamics depend on weighted divergent, convergent, and chain motifs. For additive, Hebbian STDP these motif interactions create instabilities in synaptic dynamics that either promote or suppress the initial network structure. Our work provides a consistent theoretical framework for studying how spiking activity in recurrent networks interacts with synaptic plasticity to determine network structure., Author Summary The connectivity of mammalian brains exhibits structure at a wide variety of spatial scales, from the broad (which brain areas connect to which) to the extremely fine (where synapses form on the morphology of individual neurons). Recent experimental work in the neocortex has highlighted structure at the level of microcircuits: different patterns of connectivity between small groups of neurons are either more or less abundant than would be expected by chance. A central question in systems neuroscience is how this structure emerges. Attempts to answer this question are confounded by the mutual interaction of network structure and spiking activity. Synaptic connections influence spiking statistics, while individual synapses are highly plastic and become stronger or weaker depending on the activity of the pre- and postsynaptic neurons. We present a self-consistent theory for how activity-dependent synaptic plasticity leads to the emergence of neuronal microcircuits. We use this theory to show how the form of the plasticity rule can govern the promotion or suppression of different connectivity patterns. Our work provides a foundation for understanding how cortical circuits, and not just individual synapses, are malleable in response to inputs both external and internal to a network.

Published

2015

58. Inhibitory stabilization and visual coding in cortical circuits with multiple interneuron subtypes

Author

Brent Doiron, X Ashok Litwin-Kumar, and Robert Rosenbaum

Subjects

0301 basic medicine, Interneuron, Physiology, Surround suppression, Population, Models, Neurological, Action Potentials, Optogenetics, Stimulus (physiology), Neural Circuits, Inhibitory postsynaptic potential, 03 medical and health sciences, Mice, 0302 clinical medicine, Interneurons, medicine, Animals, education, Visual Cortex, education.field_of_study, biology, General Neuroscience, Neural Inhibition, Synaptic Potentials, 030104 developmental biology, medicine.anatomical_structure, Visual cortex, Parvalbumins, biology.protein, Visual Perception, Nerve Net, Somatostatin, Neuroscience, 030217 neurology & neurosurgery, Parvalbumin, Vasoactive Intestinal Peptide

Abstract

Recent anatomical and functional characterization of cortical inhibitory interneurons has highlighted the diverse computations supported by different subtypes of interneurons. However, most theoretical models of cortex do not feature multiple classes of interneurons and rather assume a single homogeneous population. We study the dynamics of recurrent excitatory-inhibitory model cortical networks with parvalbumin (PV)-, somatostatin (SOM)-, and vasointestinal peptide-expressing (VIP) interneurons, with connectivity properties motivated by experimental recordings from mouse primary visual cortex. Our theory describes conditions under which the activity of such networks is stable and how perturbations of distinct neuronal subtypes recruit changes in activity through recurrent synaptic projections. We apply these conclusions to study the roles of each interneuron subtype in disinhibition, surround suppression, and subtractive or divisive modulation of orientation tuning curves. Our calculations and simulations determine the architectural and stimulus tuning conditions under which cortical activity consistent with experiment is possible. They also lead to novel predictions concerning connectivity and network dynamics that can be tested via optogenetic manipulations. Our work demonstrates that recurrent inhibitory dynamics must be taken into account to fully understand many properties of cortical dynamics observed in experiments.

Published

2015

59. Population activity structure of excitatory and inhibitory neurons

Author

Matthew A. Smith, Byron M. Yu, Sean R. Bittner, Adam C. Snyder, Ashok Litwin-Kumar, Steven M. Chase, Brent Doiron, and Ryan C. Williamson

Subjects

0301 basic medicine, Physiology, lcsh:Medicine, Action Potentials, Monkeys, Macaque, Mathematical and Statistical Techniques, 0302 clinical medicine, Animal Cells, Medicine and Health Sciences, Cluster Analysis, Neural networks (Neurobiology), lcsh:Science, Visual Cortex, Mammals, Neurons, education.field_of_study, Multidisciplinary, Covariance, biology, Single Neuron Function, Electrophysiology, medicine.anatomical_structure, Vertebrates, Physical Sciences, Excitatory postsynaptic potential, Cellular Types, Factor Analysis, Algorithms, Network Analysis, Statistics (Mathematics), Research Article, Primates, Computer and Information Sciences, Neural Networks, Models, Neurological, Population, Neurophysiology, Research and Analysis Methods, Inhibitory postsynaptic potential, Membrane Potential, 03 medical and health sciences, Cellular neuroscience, biology.animal, Old World monkeys, medicine, Animals, Statistical Methods, education, Computational Neuroscience, FOS: Clinical medicine, lcsh:R, Organisms, Neurosciences, Excitatory Postsynaptic Potentials, Biology and Life Sciences, Computational Biology, Random Variables, Cell Biology, Probability Theory, 030104 developmental biology, Visual cortex, Inhibitory Postsynaptic Potentials, nervous system, Cellular Neuroscience, Amniotes, Macaca, lcsh:Q, Neuron, Neuroscience, Non-spiking neuron, Mathematics, 030217 neurology & neurosurgery

Abstract

Many studies use population analysis approaches, such as dimensionality reduction, to characterize the activity of large groups of neurons. To date, these methods have treated each neuron equally, without taking into account whether neurons are excitatory or inhibitory. We studied population activity structure as a function of neuron type by applying factor analysis to spontaneous activity from spiking networks with balanced excitation and inhibition. Throughout the study, we characterized population activity structure by measuring its dimensionality and the percentage of overall activity variance that is shared among neurons. First, by sampling only excitatory or only inhibitory neurons, we found that the activity structures of these two populations in balanced networks are measurably different. We also found that the population activity structure is dependent on the ratio of excitatory to inhibitory neurons sampled. Finally we classified neurons from extracellular recordings in the primary visual cortex of anesthetized macaques as putative excitatory or inhibitory using waveform classification, and found similarities with the neuron type-specific population activity structure of a balanced network with excitatory clustering. These results imply that knowledge of neuron type is important, and allows for stronger statistical tests, when interpreting population activity structure.

Published

2017

60. Optimal Degrees of Synaptic Connectivity

Author

Haim Sompolinsky, Richard Axel, Ashok Litwin-Kumar, L. F. Abbott, and Kameron Decker Harris

Subjects

0301 basic medicine, Models, Neurological, Population, Plasticity, Biology, Article, Purkinje Cells, 03 medical and health sciences, 0302 clinical medicine, Cerebellum, medicine, Animals, education, Mushroom Bodies, Cerebral Cortex, education.field_of_study, Neuronal Plasticity, General Neuroscience, Drosophila melanogaster, 030104 developmental biology, medicine.anatomical_structure, nervous system, Cerebral cortex, Synapses, Mushroom bodies, Neuron, Neuroscience, 030217 neurology & neurosurgery

Abstract

Synaptic connectivity varies widely across neuronal types. Cerebellar granule cells receive five orders of magnitude fewer inputs than the Purkinje cells they innervate, and cerebellum-like circuits, including the insect mushroom body, also exhibit large divergences in connectivity. In contrast, the number of inputs per neuron in cerebral cortex is more uniform and large. We investigate how the dimension of a representation formed by a population of neurons depends on how many inputs each neuron receives and what this implies for learning associations. Our theory predicts that the dimensions of the cerebellar granule-cell and Drosophila Kenyon-cell representations are maximized at degrees of synaptic connectivity that match those observed anatomically, showing that sparse connectivity is sometimes superior to dense connectivity. When input synapses are subject to supervised plasticity, however, dense wiring becomes advantageous, suggesting that the type of plasticity exhibited by a set of synapses is a major determinant of connection density.

Published

2017

61. Formation and maintenance of neuronal assemblies through synaptic plasticity

Author

Ashok Litwin-Kumar and Brent Doiron

Subjects

Neurons, Multidisciplinary, Synaptic scaling, Neuronal Plasticity, Spike train, Models, Neurological, General Physics and Astronomy, Nonsynaptic plasticity, Action Potentials, Sensory system, General Chemistry, Anatomy, Biology, General Biochemistry, Genetics and Molecular Biology, medicine.anatomical_structure, Cortex (anatomy), Homeostatic plasticity, Metaplasticity, Synaptic plasticity, medicine, Animals, Homeostasis, Nerve Net, Neuroscience

Abstract

The architecture of cortex is flexible, permitting neuronal networks to store recent sensory experiences as specific synaptic connectivity patterns. However, it is unclear how these patterns are maintained in the face of the high spike time variability associated with cortex. Here we demonstrate, using a large-scale cortical network model, that realistic synaptic plasticity rules coupled with homeostatic mechanisms lead to the formation of neuronal assemblies that reflect previously experienced stimuli. Further, reverberation of past evoked states in spontaneous spiking activity stabilizes, rather than erases, this learned architecture. Spontaneous and evoked spiking activity contains a signature of learned assembly structures, leading to testable predictions about the effect of recent sensory experience on spike train statistics. Our work outlines requirements for synaptic plasticity rules capable of modifying spontaneous dynamics and shows that this modification is beneficial for stability of learned network architectures.

Published

2014

62. The spatial structure of stimuli shapes the timescale of correlations in population spiking activity

Author

Brent Doiron, Maurice J. Chacron, and Ashok Litwin-Kumar

Subjects

Nerve net, Spike train, Statistics as Topic, Action Potentials, computer.software_genre, 0302 clinical medicine, Biology (General), Electric fish, 0303 health sciences, education.field_of_study, Electric Organ, Neuronal Plasticity, Ecology, Applied Mathematics, Physics, Complex Systems, Neuroethology, Sensory Systems, medicine.anatomical_structure, Computational Theory and Mathematics, Modeling and Simulation, Neural coding, Research Article, Neural Networks, QH301-705.5, Population, Models, Neurological, Neurophysiology, Stimulus (physiology), Biology, Machine learning, Statistical Mechanics, 03 medical and health sciences, Cellular and Molecular Neuroscience, Neuroplasticity, Genetics, medicine, Biological neural network, Animals, Computer Simulation, Neurons, Afferent, education, Molecular Biology, Theoretical Biology, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Computational Neuroscience, Models, Statistical, Quantitative Biology::Neurons and Cognition, business.industry, Electric Stimulation, Nonlinear Dynamics, Artificial intelligence, Nerve Net, business, computer, Neuroscience, 030217 neurology & neurosurgery, Mathematics, Electric Fish

Abstract

Throughout the central nervous system, the timescale over which pairs of neural spike trains are correlated is shaped by stimulus structure and behavioral context. Such shaping is thought to underlie important changes in the neural code, but the neural circuitry responsible is largely unknown. In this study, we investigate a stimulus-induced shaping of pairwise spike train correlations in the electrosensory system of weakly electric fish. Simultaneous single unit recordings of principal electrosensory cells show that an increase in the spatial extent of stimuli increases correlations at short () timescales while simultaneously reducing correlations at long () timescales. A spiking network model of the first two stages of electrosensory processing replicates this correlation shaping, under the assumptions that spatially broad stimuli both saturate feedforward afferent input and recruit an open-loop inhibitory feedback pathway. Our model predictions are experimentally verified using both the natural heterogeneity of the electrosensory system and pharmacological blockade of descending feedback projections. For weak stimuli, linear response analysis of the spiking network shows that the reduction of long timescale correlation for spatially broad stimuli is similar to correlation cancellation mechanisms previously suggested to be operative in mammalian cortex. The mechanism for correlation shaping supports population-level filtering of irrelevant distractor stimuli, thereby enhancing the population response to relevant prey and conspecific communication inputs., Author Summary The size of a stimulus that is sensed by the nervous system can control the activity of neurons in sensory areas. How neural wiring supports this dependence remains an open question. We explore this general phenomenon using weakly electric fish, which possess a sensory system that detects electric field modulations produced by the surrounding environment. In particular, these animals' nervous systems are tuned to detect the difference between spatially compact prey inputs and spatially broad communication calls from other fish. In experiment, we discover that these two classes of stimuli differentially control the synchrony between pairs of electrosensory neurons. Using a computational model, we predict that this modulation is related to feedforward and feedback neural pathways in the electrosensory system, and we verify this prediction with experiments. This architecture prevents low frequency distractor stimuli, such as the animal's own tail motion, from driving neural population responses. With our model, we demonstrate how a common neural architecture enables a population-level code for behaviorally relevant stimuli.

Published

2012

63. Balanced synaptic input shapes the correlation between neural spike trains

Author

Nathaniel N. Urban, Ashok Litwin-Kumar, Brent Doiron, and Anne-Marie M. Oswald

Subjects

Computer science, Spike train, Action Potentials, computer.software_genre, Synaptic Transmission, Correlation, Mice, 0302 clinical medicine, lcsh:QH301-705.5, Neurons, 0303 health sciences, education.field_of_study, Coding Mechanisms, Ecology, Physics, Brain, Sensory Systems, Single Neuron Function, medicine.anatomical_structure, Computational Theory and Mathematics, Modeling and Simulation, Excitatory postsynaptic potential, 69999 Biological Sciences not elsewhere classified, Research Article, Population, Models, Neurological, Mice, Inbred Strains, Stimulus (physiology), Neurotransmission, Inhibitory postsynaptic potential, Machine learning, Statistical Mechanics, 03 medical and health sciences, Cellular and Molecular Neuroscience, Genetics, medicine, Animals, education, Molecular Biology, Biology, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Computational Neuroscience, Quantitative Biology::Neurons and Cognition, business.industry, lcsh:Biology (General), FOS: Biological sciences, Artificial intelligence, Neuron, business, Neuroscience, computer, 030217 neurology & neurosurgery

Abstract

Stimulus properties, attention, and behavioral context influence correlations between the spike times produced by a pair of neurons. However, the biophysical mechanisms that modulate these correlations are poorly understood. With a combined theoretical and experimental approach, we show that the rate of balanced excitatory and inhibitory synaptic input modulates the magnitude and timescale of pairwise spike train correlation. High rate synaptic inputs promote spike time synchrony rather than long timescale spike rate correlations, while low rate synaptic inputs produce opposite results. This correlation shaping is due to a combination of enhanced high frequency input transfer and reduced firing rate gain in the high input rate state compared to the low state. Our study extends neural modulation from single neuron responses to population activity, a necessary step in understanding how the dynamics and processing of neural activity change across distinct brain states., Author Summary Neurons in sensory, motor, and cognitive regions of the nervous system integrate synaptic input and output trains of action potentials (spikes). A critical feature of neural computation is the ability for neurons to modulate their spike train response to a given input, allowing task context or past history to affect the flow of information in the brain. The mechanisms that modulate the input-output transfer of single neurons have received significant attention. However, neural computation involves the coordinated activity of populations of neurons, and the mechanisms that modulate the correlation between spike trains from pairs of neurons are relatively unexplored. We show that the level of excitatory and inhibitory input that a neuron receives modulates not only the sensitivity of a single neuron's response to input, but also the magnitude and timescale of correlated spiking activity of pairs of neurons receiving a common synaptic drive. Thus, while modulatory synaptic activity has been traditionally studied from a single neuron perspective, it can also shape the coordinated activity of a population of neurons.

Published

2011