Your search keyword '"Population coding"' showing total 847 results

1. Exploring Neural Joint Activity in Spiking Neural Networks for Fraud Detection

Author

Perdigão, Dylan, Antunes, Francisco, Silva, Catarina, Ribeiro, Bernardete, Goos, Gerhard, Series Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Hernández-García, Ruber, editor, Barrientos, Ricardo J., editor, and Velastin, Sergio A., editor

Published

2025

2. Contrast gain control is a reparameterization of a population response curve.

Author

Tring, Elaine, Moosavi, S. Amin, Dipoppa, Mario, and Ringach, Dario L.

Abstract

Neurons in primary visual cortex (area V1) adapt in varying degrees to the average contrast of the environment, suggesting that the representation of visual stimuli may interact with the state of cortical gain control in complex ways. To investigate this possibility, we measured and analyzed the responses of neural populations in mouse V1 to visual stimuli as a function of contrast in different environments, each characterized by a unique distribution of contrast values. Our findings reveal that, for a fixed stimulus, the population response can be described by a vector function r(gec), where the gain ge is a decreasing function of the mean contrast of the environment. Thus, gain control can be viewed as a reparameterization of a population response curve, which is invariant across environments. Different stimuli are mapped to distinct curves, all originating from a common origin, corresponding to a zero-contrast response. Altogether, our findings provide a straightforward, geometric interpretation of contrast gain control at the population level and show that changes in gain are well matched among members of a population. NEW & NOTEWORTHY: The authors study the responses of neural populations in mouse primary visual cortex as a function of stimulus contrast. Measurements are performed in different "environments," each characterized by a different distribution of contrast values. They find that responses across environments can be viewed as a reparameterization of a single contrast-response curve, offering a simple, geometric account of contrast gain control in neural populations. [ABSTRACT FROM AUTHOR]

Published

2024

3. A working memory model based on recurrent neural networks using reinforcement learning.

Author

Wang, Mengyuan, Wang, Yihong, Xu, Xuying, and Pan, Xiaochuan

Abstract

Numerous electrophysiological experiments have reported that the prefrontal cortex (PFC) is involved in the process of working memory. PFC neurons continue firing to maintain stimulus information in the delay period without external stimuli in working memory tasks. Further findings indicate that while the activity of single neurons exhibits strong temporal and spatial dynamics (heterogeneity), the activity of population neurons can encode spatiotemporal information of stimuli stably and reliably. From the perspective of neural networks, the computational mechanism underlying this phenomenon is not well demonstrated. The main purpose of this paper is to adopt a new strategy to explore the neural computation mechanism of working memory. We used reinforcement learning to train a recurrent neural network model to learn a spatial working memory task. The model is composed of a decision network and a baseline network. The decision network is responsible for updating strategies to make action choices, while the baseline network evaluates action choices to predict rewards. Simulated results demonstrate that the model can perform the spatial working memory task. The activity of the recurrent units has characteristics such as temporal dynamics and preferred direction selectivity, but their population activity encodes the stimulus information stably during the delay period in a low-dimensional subspace. These activity characteristics displayed by the model units are similar to those of PFC neurons observed in the same experiments. Meanwhile, as the network model continued learning the task, the temporal stability and spatial separability of the stimulus information encoded by the activity of model units in the low-dimensional subspace gradually strengthened, and the accuracy of the network's action choices also increased. In summary, this network model provides a new simulation method for spatial working memory tasks and a new perspective for understanding the characteristics of neuron activity in the PFC. [ABSTRACT FROM AUTHOR]

Published

2024

4. NEUROBIOLOGICAL PROPERTIES OF THE STRUCTURE OF THE PARALLEL-HIERARCHICAL NETWORK AND ITS USAGE FOR PATTERN RECOGNITION.

Author

Timchenko, Leonid, Kokriatskaia, Natalia, Tverdomed, Volodymyr, Horban, Anatolii, Sobovyi, Oleksandr, Pogrebniak, Liudmyla, Burlaka, Nelia, Didenko, Yurii, Kozyr, Maksym, and Kozbakova, Ainur

Subjects

LASER beams, CENTER of mass, DATA analysis, LASERS

Abstract

Copyright of Informatics Control Measurement in Economy & Environment Protection / Informatyka, Automatyka, Pomiary w Gospodarce i Ochronie Środowiska is the property of Lublin University of Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

5. Common population codes produce extremely nonlinear neural manifolds.

Author

De, Anandita and Chaudhuri, Rishidev

Subjects

computational neuroscience, neural manifolds, population coding, Neurons, Principal Component Analysis, Research Design

Abstract

Populations of neurons represent sensory, motor, and cognitive variables via patterns of activity distributed across the population. The size of the population used to encode a variable is typically much greater than the dimension of the variable itself, and thus, the corresponding neural population activity occupies lower-dimensional subsets of the full set of possible activity states. Given population activity data with such lower-dimensional structure, a fundamental question asks how close the low-dimensional data lie to a linear subspace. The linearity or nonlinearity of the low-dimensional structure reflects important computational features of the encoding, such as robustness and generalizability. Moreover, identifying such linear structure underlies common data analysis methods such as Principal Component Analysis (PCA). Here, we show that for data drawn from many common population codes the resulting point clouds and manifolds are exceedingly nonlinear, with the dimension of the best-fitting linear subspace growing at least exponentially with the true dimension of the data. Consequently, linear methods like PCA fail dramatically at identifying the true underlying structure, even in the limit of arbitrarily many data points and no noise.

Published

2023

6. NEUROBIOLOGICAL PROPERTIES OF THE STRUCTURE OF THE PARALLEL-HIERARCHICAL NETWORK AND ITS USAGE FOR PATTERN RECOGNITION

Author

Leonid Timchenko, Natalia Kokriatskaia, Volodymyr Tverdomed, Anatolii Horban, Oleksandr Sobovyi, Liudmyla Pogrebniak, Nelia Burlaka, Yurii Didenko, Maksym Kozyr, and Ainur Kozbakova

Subjects

parallel-hierarchical network, population coding, pattern recognition task, laser, center of images, proceeding of images, Environmental engineering, TA170-171, Environmental sciences, GE1-350

Abstract

The paper presents the analysis of neurobiological data on the existence of the structure of a parallel-hierarchical network. Discussed method of parallel-hierarchical transformation based on population coding and its application for the pattern recognition task. Based on the analysis, we can conclude that using the methods proposed, it is possible to measure the geometric parameters and properties of images, which can significantly increase the efficiency of processing, in particular estimating the center of mass based on moment characteristics. Experimental results demonstrate that due to various destabilizing factors, accurately measuring the energy center coordinates of laser beam spot images is challenging. However, training the PI network and classifying the fragments into "good" and "bad" can considerably enhance the accuracy of these measurements.

Published

2024

7. Task-specific invariant representation in auditory cortex

Author

Charles R Heller, Gregory R Hamersky, and Stephen V David

Subjects

auditory cortex, population coding, behavior, Medicine, Science, Biology (General), QH301-705.5

Abstract

Categorical sensory representations are critical for many behaviors, including speech perception. In the auditory system, categorical information is thought to arise hierarchically, becoming increasingly prominent in higher-order cortical regions. The neural mechanisms that support this robust and flexible computation remain poorly understood. Here, we studied sound representations in the ferret primary and non-primary auditory cortex while animals engaged in a challenging sound discrimination task. Population-level decoding of simultaneously recorded single neurons revealed that task engagement caused categorical sound representations to emerge in non-primary auditory cortex. In primary auditory cortex, task engagement caused a general enhancement of sound decoding that was not specific to task-relevant categories. These findings are consistent with mixed selectivity models of neural disentanglement, in which early sensory regions build an overcomplete representation of the world and allow neurons in downstream brain regions to flexibly and selectively read out behaviorally relevant, categorical information.

Published

2024

8. On the contrast response function of adapted neural populations.

Author

Tring, Elaine, Dipoppa, Mario, and Ringach, Dario L.

Subjects

*VISUAL cortex, *STIMULUS intensity

Abstract

The magnitude of neural responses in sensory cortex depends on the intensity of a stimulus and its probability of being observed within the environment. How these two variables combine to influence the overall response of cortical populations remains unknown. Here we show that, in primary visual cortex, the vector magnitude of the population response is described by a separable power law that factors the intensity of a stimulus and its probability. Moreover, the discriminability between two contrast levels in a cortical population is proportional to the logarithm of the contrast ratio. [ABSTRACT FROM AUTHOR]

Published

2024

9. Bio-Inspired Small Target Motion Detection With Spatio-Temporal Feedback in Natural Scenes.

Author

Wang, Hongxin, Zhong, Zhiyan, Lei, Fang, Peng, Jigen, and Yue, Shigang

Subjects

*BIOLOGICALLY inspired computing, *MOTION detectors, *IMAGE processing, *FEATURE extraction

Abstract

Small moving objects at far distance always occupy only one or a few pixels in image and exhibit extremely limited visual features, which bring great challenges to motion detection. Highly evolved visual systems endow flying insects with remarkable ability to pursue tiny mates and prey, providing a good template to develop image processing method for small target motion detection. The insects’ excellent sensitivity to small moving objects is believed to come from a class of specific neurons called small target motion detectors (STMDs). However, existing STMD-based methods often experience performance degradation when coping with complex natural scenes. In this paper, we propose a bio-inspired visual system with spatio-temporal feedback mechanism (called Spatio-Temporal Feedback STMD) to suppress false positive background movement while enhancing system responses to small targets. Specifically, the proposed visual system is composed of two complementary subnetworks and a feedback loop. The first subnetwork is designed to extract spatial and temporal movement patterns of cluttered background by neuronal ensemble coding. The second subnetwork is developed to capture small target motion information where its output and signal from the first subnetwork are integrated together via the feedback loop to filter out background false positives in a recurrent manner. Experimental results demonstrate that the proposed spatio-temporal feedback visual system is more competitive than existing methods in discriminating small moving targets from complex natural environments. [ABSTRACT FROM AUTHOR]

Published

2024

10. A dynamic neural resource model bridges sensory and working memory

Author

Ivan Tomić and Paul M Bays

Subjects

short-term memory, population coding, temporal dynamics, delay, encoding, decoding, Medicine, Science, Biology (General), QH301-705.5

Abstract

Probing memory of a complex visual image within a few hundred milliseconds after its disappearance reveals significantly greater fidelity of recall than if the probe is delayed by as little as a second. Classically interpreted, the former taps into a detailed but rapidly decaying visual sensory or ‘iconic’ memory (IM), while the latter relies on capacity-limited but comparatively stable visual working memory (VWM). While iconic decay and VWM capacity have been extensively studied independently, currently no single framework quantitatively accounts for the dynamics of memory fidelity over these time scales. Here, we extend a stationary neural population model of VWM with a temporal dimension, incorporating rapid sensory-driven accumulation of activity encoding each visual feature in memory, and a slower accumulation of internal error that causes memorized features to randomly drift over time. Instead of facilitating read-out from an independent sensory store, an early cue benefits recall by lifting the effective limit on VWM signal strength imposed when multiple items compete for representation, allowing memory for the cued item to be supplemented with information from the decaying sensory trace. Empirical measurements of human recall dynamics validate these predictions while excluding alternative model architectures. A key conclusion is that differences in capacity classically thought to distinguish IM and VWM are in fact contingent upon a single resource-limited WM store.

Published

2024

11. Memorable first impressions

Author

Emilio Salinas and Bashirul I Sheikh

Subjects

short-term memory, population coding, temporal dynamics, delay encoding, iconic memory, Medicine, Science, Biology (General), QH301-705.5

Abstract

Our ability to recall details from a remembered image depends on a single mechanism that is engaged from the very moment the image disappears from view.

Published

2024

12. Accurate Detection of Spiking Motifs in Multi-unit Raster Plots

Author

Perrinet, Laurent U., Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Iliadis, Lazaros, editor, Papaleonidas, Antonios, editor, Angelov, Plamen, editor, and Jayne, Chrisina, editor

Published

2023

13. Population Coding Can Greatly Improve Performance of Neural Networks: A Comparison

Author

Jahrens, Marius, Hansen, Hans-Oliver, Köhler, Rebecca, Martinetz, Thomas, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Iliadis, Lazaros, editor, Papaleonidas, Antonios, editor, Angelov, Plamen, editor, and Jayne, Chrisina, editor

Published

2023

14. Modeling Müller-Lyer Illusion Using Information Geometry

Author

Mazumdar, Debasis, Mitra, Soma, Mandal, Mainak, Ghosh, Kuntal, Bhaumik, Kamales, Bansal, Jagdish Chand, Series Editor, Deep, Kusum, Series Editor, Nagar, Atulya K., Series Editor, Jacob, I. Jeena, editor, Kolandapalayam Shanmugam, Selvanayaki, editor, and Izonin, Ivan, editor

Published

2023

15. An Emergent Population Code in Primary Auditory Cortex Supports Selective Attention to Spectral and Temporal Sound Features.

Author

Downer, Joshua D, Verhein, Jessica R, Rapone, Brittany C, O'Connor, Kevin N, and Sutter, Mitchell L

Subjects

Auditory Cortex, Neurons, Animals, Macaca mulatta, Acoustic Stimulation, Auditory Perception, Attention, Action Potentials, Female, Male, attention, auditory cortex, nonhuman primate, population coding, Neurosciences, Behavioral and Social Science, Basic Behavioral and Social Science, Eye Disease and Disorders of Vision, 1.2 Psychological and socioeconomic processes, 1.1 Normal biological development and functioning, Underpinning research, Neurological, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

Textbook descriptions of primary sensory cortex (PSC) revolve around single neurons' representation of low-dimensional sensory features, such as visual object orientation in primary visual cortex (V1), location of somatic touch in primary somatosensory cortex (S1), and sound frequency in primary auditory cortex (A1). Typically, studies of PSC measure neurons' responses along few (one or two) stimulus and/or behavioral dimensions. However, real-world stimuli usually vary along many feature dimensions and behavioral demands change constantly. In order to illuminate how A1 supports flexible perception in rich acoustic environments, we recorded from A1 neurons while rhesus macaques (one male, one female) performed a feature-selective attention task. We presented sounds that varied along spectral and temporal feature dimensions (carrier bandwidth and temporal envelope, respectively). Within a block, subjects attended to one feature of the sound in a selective change detection task. We found that single neurons tend to be high-dimensional, in that they exhibit substantial mixed selectivity for both sound features, as well as task context. We found no overall enhancement of single-neuron coding of the attended feature, as attention could either diminish or enhance this coding. However, a population-level analysis reveals that ensembles of neurons exhibit enhanced encoding of attended sound features, and this population code tracks subjects' performance. Importantly, surrogate neural populations with intact single-neuron tuning but shuffled higher-order correlations among neurons fail to yield attention- related effects observed in the intact data. These results suggest that an emergent population code not measurable at the single-neuron level might constitute the functional unit of sensory representation in PSC.SIGNIFICANCE STATEMENT The ability to adapt to a dynamic sensory environment promotes a range of important natural behaviors. We recorded from single neurons in monkey primary auditory cortex (A1), while subjects attended to either the spectral or temporal features of complex sounds. Surprisingly, we found no average increase in responsiveness to, or encoding of, the attended feature across single neurons. However, when we pooled the activity of the sampled neurons via targeted dimensionality reduction (TDR), we found enhanced population-level representation of the attended feature and suppression of the distractor feature. This dissociation of the effects of attention at the level of single neurons versus the population highlights the synergistic nature of cortical sound encoding and enriches our understanding of sensory cortical function.

Published

2021

16. Perceptual Learning of Fine Contrast Discrimination Under Non-roving, Roving-Without-Flanker, and Roving-with-Flanker Conditions and its Relation to Neuronal Activity in Macaque V1

Author

Thiele, Alexander, Chen, Xing, Sanayei, Mehdi, Chicharro, Daniel, Distler, Claudia, and Panzeri, Stefano

Published

2024

17. Rozsiany system nocycepcji fizjologicznym podłożem odczuwania bólu u ludzi.

Author

Adamczyk, Wacław M., Skalski, Jacek, Nowak, Daria, Jakubińska, Marta, Kruszyna, Natalia, Budzisz, Aleksandra, Szikszay, Tibor M., and Nastaj, Jakub

Subjects

NEUROPHYSIOLOGY, MATHEMATICAL models, THEORY, NOCICEPTIVE pain, PAIN management

Abstract

Copyright of Pain Research / Ból is the property of Index Copernicus International and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

18. A Distributed Neural Code in the Dentate Gyrus and in CA1

Author

Stefanini, Fabio, Kushnir, Lyudmila, Jimenez, Jessica C, Jennings, Joshua H, Woods, Nicholas I, Stuber, Garret D, Kheirbek, Mazen A, Hen, René, and Fusi, Stefano

Subjects

Neurosciences, Behavioral and Social Science, Basic Behavioral and Social Science, 1.1 Normal biological development and functioning, Underpinning research, Neurological, Action Potentials, Animals, CA1 Region, Hippocampal, Calcium, Dentate Gyrus, Mice, Neurons, Spatial Behavior, calcium imaging, correlated activity, decoding, dentate gyrus, distributed representations, hippocampus, mixed selectivity, place cells, population coding, Psychology, Cognitive Sciences, Neurology & Neurosurgery

Abstract

Neurons are often considered specialized functional units that encode a single variable. However, many neurons are observed to respond to a mix of disparate sensory, cognitive, and behavioral variables. For such representations, information is distributed across multiple neurons. Here we find this distributed code in the dentate gyrus and CA1 subregions of the hippocampus. Using calcium imaging in freely moving mice, we decoded an animal's position, direction of motion, and speed from the activity of hundreds of cells. The response properties of individual neurons were only partially predictive of their importance for encoding position. Non-place cells encoded position and contributed to position encoding when combined with other cells. Indeed, disrupting the correlations between neural activities decreased decoding performance, mostly in CA1. Our analysis indicates that population methods rather than classical analyses based on single-cell response properties may more accurately characterize the neural code in the hippocampus.

Published

2020

19. Gated transformations from egocentric to allocentric reference frames involving retrosplenial cortex, entorhinal cortex, and hippocampus.

Author

Alexander, Andrew S., Robinson, Jennifer C., Stern, Chantal E., and Hasselmo, Michael E.

Subjects

*CINGULATE cortex, *ENTORHINAL cortex, *HIPPOCAMPUS (Brain), *COORDINATE transformations, *ANIMAL behavior

Abstract

This paper reviews the recent experimental finding that neurons in behaving rodents show egocentric coding of the environment in a number of structures associated with the hippocampus. Many animals generating behavior on the basis of sensory input must deal with the transformation of coordinates from the egocentric position of sensory input relative to the animal, into an allocentric framework concerning the position of multiple goals and objects relative to each other in the environment. Neurons in retrosplenial cortex show egocentric coding of the position of boundaries in relation to an animal. These neuronal responses are discussed in relation to existing models of the transformation from egocentric to allocentric coordinates using gain fields and a new model proposing transformations of phase coding that differ from current models. The same type of transformations could allow hierarchical representations of complex scenes. The responses in rodents are also discussed in comparison to work on coordinate transformations in humans and non‐human primates. [ABSTRACT FROM AUTHOR]

Published

2023

20. Serotonin increases population coding of behaviorally relevant stimuli by enhancing responses of ON but not OFF-type sensory neurons

Author

Mariana M. Marquez and Maurice J. Chacron

Subjects

Weakly electric fish, Population coding, Neuroethology, Serotonin, Neuromodulation, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

How neural populations encode sensory input to generate behavioral responses remains a central problem in systems neuroscience. Here we investigated how neuromodulation influences population coding of behaviorally relevant stimuli to give rise to behavior in the electrosensory system of the weakly electric fish Apteronotus leptorhynchus. We performed multi-unit recordings from ON and OFF sensory pyramidal cells in response to stimuli whose amplitude (i.e., envelope) varied in time, before and after electrical stimulation of the raphe nuclei. Overall, raphe stimulation increased population coding by ON- but not by OFF-type cells, despite both cell types showing similar sensitivities to the stimulus at the single neuron level. Surprisingly, only changes in population coding by ON-type cells were correlated with changes in behavioral responses. Taken together, our results show that neuromodulation differentially affects ON vs. OFF-type cells in order to enhance perception of behaviorally relevant sensory input.

Published

2023

21. Rate-distortion theory of neural coding and its implications for working memory

Author

Anthony MV Jakob and Samuel J Gershman

Subjects

working memory, population coding, information theory, Medicine, Science, Biology (General), QH301-705.5

Abstract

Rate-distortion theory provides a powerful framework for understanding the nature of human memory by formalizing the relationship between information rate (the average number of bits per stimulus transmitted across the memory channel) and distortion (the cost of memory errors). Here, we show how this abstract computational-level framework can be realized by a model of neural population coding. The model reproduces key regularities of visual working memory, including some that were not previously explained by population coding models. We verify a novel prediction of the model by reanalyzing recordings of monkey prefrontal neurons during an oculomotor delayed response task.

Published

2023

22. Correlation between neural responses and human perception in figure-ground segregation.

Author

Motofumi Shishikura, Hiroshi Tamura, and Ko Sakai

Subjects

STIMULUS & response (Psychology), MACAQUES, NEURONS, MONKEYS

Abstract

Segmentation of a natural scene into objects (figures) and background (ground) is one of crucial functions for object recognition and scene understanding. Recent studies have investigated neural mechanisms underlying figure-ground (FG) segregation and reported neural modulation to FG in the intermediate-level visual area, V4, of macaque monkeys (FG neurons). However, whether FG neurons contribute to the perception of FG segregation has not been clarified. To examine the contribution of FG neurons, we examined the correlations between perceptual consistency (PC), which quantified perceptual ambiguity in FG determination, and the reliability of neural signals in response to FG. First, we evaluated PCs for the images that were used in the previous neural recording in V4; specifically, we measured how consistently FG can be determined across trials and participants for each stimulus. The PCs were widely distributed, so that we identified the ambiguity in FG segregation for each stimulus. Next, we analyzed the correlation between the PCs and the reliability of neural modulation to FG. We found that the stimuli with higher PCs evoked more consistent and greater modulation in the responses of single neurons than those with lower PCs. Since perception is expected to show a greater correlation with responses of neural population compared to those of single neurons, we examined the correlation between the PCs and the consistency of the population responses in FG determination. Stimuli with higher PCs evoked higher population consistency than those with lower PCs. Finally, we analyzed the correlation between the PCs and neural latencies in FG modulation. We found that the stimuli with higher PCs showed shorter reaction times in FG perception and evoked shorter modulation latencies in FG neurons. These results indicate that the responses of FG neurons recorded from macaque monkeys show significant correlations with human FG perception, suggesting that V4 neurons with FG-dependent responses contribute to the perception of FG segregation. [ABSTRACT FROM AUTHOR]

Published

2023

23. Stable coding of aversive associations in medial prefrontal populations.

Author

Herry, Cyril and Jercog, Daniel

Subjects

*THREAT (Psychology), *PREFRONTAL cortex, *AMYGDALOID body, *ASSOCIATIVE learning, *NEUROSCIENCES, *NEURONS

Abstract

The medial prefrontal cortex (mPFC) is at the core of numerous psychiatric conditions, including fear and anxiety-related disorders. Whereas an abundance of evidence suggests a crucial role of the mPFC in regulating fear behaviour, the precise role of the mPFC in this process is not yet entirely clear. While studies at the single-cell level have demonstrated the involvement of this area in various aspects of fear processing, such as the encoding of threat-related cues and fear expression, an increasingly prevalent idea in the systems neuroscience field is that populations of neurons are, in fact, the essential unit of computation in many integrative brain regions such as prefrontal areas. What mPFC neuronal populations represent when we face threats? To address this question, we performed electrophysiological single-unit population recordings in the dorsal mPFC while mice faced threat-predicting cues eliciting defensive behaviours, and performed pharmacological and optogenetic inactivations of this area and the amygdala. Our data indicated that the presence of threat-predicting cues induces a stable coding dynamics of internally driven representations in the dorsal mPFC, necessary to drive learned defensive behaviours. Moreover, these neural population representations primary reflect learned associations rather than specific defensive behaviours, and the construct of such representations relies on the functional integrity of the amygdala. [ABSTRACT FROM AUTHOR]

Published

2023

24. Neural representational geometry underlies few-shot concept learning.

Author

Sorscher, Ben, Ganguli, Surya, and Sompolinsky, Haim

Subjects

*CONCEPT learning, *GEOMETRY education, *VISUAL learning, *COGNITIVE learning, *VISUAL pathways, *LEARNING ability

Abstract

Understanding the neural basis of the remarkable human cognitive capacity to learn novel concepts from just one or a few sensory experiences constitutes a fundamental problem. We propose a simple, biologically plausible, mathematically tractable, and computationally powerful neural mechanism for few-shot learning of naturalistic concepts. We posit that the concepts that can be learned from few examples are defined by tightly circumscribed manifolds in the neural firing-rate space of higherorder sensory areas. We further posit that a single plastic downstream readout neuron learns to discriminate new concepts based on few examples using a simple plasticity rule. We demonstrate the computational power of our proposal by showing that it can achieve high few-shot learning accuracy on natural visual concepts using both macaque inferotemporal cortex representations and deep neural network (DNN) models of these representations and can even learn novel visual concepts specified only through linguistic descriptors. Moreover, we develop a mathematical theory of few-shot learning that links neurophysiology to predictions about behavioral outcomes by delineating several fundamental and measurable geometric properties of neural representations that can accurately predict the few-shot learning performance of naturalistic concepts across all our numerical simulations. This theory reveals, for instance, that high-dimensional manifolds enhance the ability to learn new concepts from few examples. Intriguingly, we observe striking mismatches between the geometry of manifolds in the primate visual pathway and in trained DNNs. We discuss testable predictions of our theory for psychophysics and neurophysiological experiments. [ABSTRACT FROM AUTHOR]

Published

2022

25. Principles of sensorimotor integration and olfactory processing

Author

Wong, Philip H

Subjects

Neurosciences, Biophysical Simulations, Depolarization Block, Dynamical Systems, Multisensory Integration, Olfaction, Population Coding

Abstract

When confronted with an ever-changing and often perilous environment, how an organism behaves in response to uncertain and incomplete sensory information can be a matter of life and death. Besides the need to assess individual sensory signals accurately, sensory systems must also be able to integrate signals from multiple sensory modalities (e.g. visual, auditory, haptic), some of which may produce conflicting information. Through studying the insect brain of the Drosophila larva, we sought to unwrap the mathematical principles behind how animals process sensory signals to guide their behavior, with a focus on olfaction.In my dissertation, we employ computational models to investigate how the Drosophila larva transduces odors through its olfactory sensory neurons and combines these cues with other sensory modalities. We obtain three important clues towards understanding the neural implementation of sensory systems: 1. Drosophila larvae are capable of computing and combining the variance of sensory inputs to organize orientation behavior, suggesting that even relatively simple nervous systems can achieve probabilistic inference. 2. Upon prolonged increasing excitation, olfactory sensory neurons can counterintuitively transition from a spiking state to a silent state called depolarization block, which preserves sparsity in the neural code. 3. The bifurcation of spiking and silent states in olfactory sensory neurons driven by depolarization block allows Drosophila larvae to encode and discriminate different odors.

Published

2023

26. A Study of Different Aspects of Neural Networks: Neural Representations, Connectivity and Computation

Author

De, Anandita

Subjects

Neurosciences, Applied mathematics, Physics, Auditory modeling, Expander graph, Manifold, Population coding, Working memory

Abstract

This dissertation is split into 3 parts. In the first part (Chapter 2) we look at shapesor manifolds on which neural activity over time lies. In a neural state space, whereeach axis represents a neuron, neural activity over time forms a point cloud. This pointcloud often occupies a small region in the space of all possible activity patterns thusrevealing structure in data. We consider point clouds from neural activities from commonpopulation codes known as “tuning curve models”. In these models, the firing rate ofeach neuron is a function of a latent variable which might be a stimulus variable or avariable related to an internal state and a tuning curve parameter which labels eachneuron. We address the question: How close are point clouds formed by such models toa linear subspace? To answer this, we define the linear dimension of the data to be thenumber of dimensions which captures a very high fraction of variance, for example 95%variance in this data. We show that the linear dimension grows exponentially with thenumber of latent variables encoded by the population. Thus the manifolds formed by theneural activities from these models are extremely non-linear. Linear dimension is not agood measure for the intrinsic dimension of the manifold on which this point cloud lies.In the second part (Chapter 3), we model connections between distant brain regionsby sparse random connections. We start by observing that such a network has a specialproperty known as the expander property. Using this property it can be shown thatinformation can be transmitted efficiently from a source region to a target region evenif the target region has fewer neurons than the source region. We also consider if thecompressed patterns in the target region can be re-coded or expanded to perform somecomputation. We show that the compressed patterns can be re-expanded by algorithmsknown as Locally Competitive Algorithms (LCA) and the re-expanded patterns can beseparated by a downstream neuron into arbitrarily defined classes. We next considerwhether long range reciprocal connections between two regions can be used to maintainpersistent activity in both the regions. Such activity is thought to be a substrate forworking memory, the ability to hold things in mind. We show that the network can indeedmaintain sparse patterns of activity through simple network dynamics. We conclude thatsparse random connections can be used to transmit information effectively and improvethe performance of certain computations compared to dense random connections.In the last part (Chapter 4), we built a computational rate model for the pre-cortexbiological neural circuit responsible for the localisation of sound in the vertical plane.Interaction of incoming sound waves with the outer ear filters out energy from specificfrequency bands in the spectrum of the incoming sound. The frequency bands with zeroor reduced power in them are known as notches. The position of the notches is a functionof the angle of elevation of the sound source. There is a dedicated set of neurons in theauditory pathway which are sensitive to the position of these notches and hence thoughtto be responsible for the localization of sound in the vertical plane. These neurons showdifferent levels of excitation or inhibition above or below their spontaneous rates for different combinations of frequencies and intensities of sound. We built a computational model to probe how this complex set of responses arise from the interaction between the various populations of neurons in the auditory pathway.

Published

2023

27. Efficient coding in biophysically realistic excitatory-inhibitory spiking networks.

Author

Koren V, Malerba SB, Schwalger T, and Panzeri S

Abstract

The principle of efficient coding posits that sensory cortical networks are designed to encode maximal sensory information with minimal metabolic cost. Despite the major influence of efficient coding in neuroscience, it has remained unclear whether fundamental empirical properties of neural network activity can be explained solely based on this normative principle. Here, we derive the structural, coding, and biophysical properties of excitatory-inhibitory recurrent networks of spiking neurons that emerge directly from imposing that the network minimizes an instantaneous loss function and a time-averaged performance measure enacting efficient coding. We assumed that the network encodes a number of independent stimulus features varying with a time scale equal to the membrane time constant of excitatory and inhibitory neurons. The optimal network has biologically-plausible biophysical features, including realistic integrate-and-fire spiking dynamics, spike-triggered adaptation, and a non-specific excitatory external input. The excitatory-inhibitory recurrent connectivity between neurons with similar stimulus tuning implements feature-specific competition, similar to that recently found in visual cortex. Networks with unstructured connectivity cannot reach comparable levels of coding efficiency. The optimal ratio of excitatory vs inhibitory neurons and the ratio of mean inhibitory-to-inhibitory vs excitatory-to-inhibitory connectivity are comparable to those of cortical sensory networks. The efficient network solution exhibits an instantaneous balance between excitation and inhibition. The network can perform efficient coding even when external stimuli vary over multiple time scales. Together, these results suggest that key properties of biological neural networks may be accounted for by efficient coding.

Published

2024

28. Local contour features contribute to figure-ground segregation in monkey V4 neural populations and human perception.

Author

Shishikura M, Machida I, Tamura H, and Sakai K

Abstract

Figure-ground (FG) segregation is a crucial step towards the recognition of objects in natural scenes. Gestalt psychologists have emphasized the importance of contour features in perception of FG. Recent electrophysiological studies have identified a neural population in V4 that shows FG-dependent modulation (FG neurons). However, whether the contour features contribute to the modulation of the response patterns of the neural population remains unclear. In the present study, we quantified the contour features associated with Gestalt factors in local natural stimuli and examined whether salient contour-features evoked reliable perceptual and neural responses by analyzing response consistency (stability) across trials. The results showed the tendency that the more salient contour-features evoked the greater consistencies in the perceptual FG judgments and population-based neural responses in FG determination; a greater partial correlation for curvature and weaker correlations for closure and parallelism. Multiple linear regression analyses demonstrated that the perceptual consistency depended similarly on curvature and closure, and the neural consistency depended significantly on curvature but weakly on closure. We further observed a strong correlation between the consistencies in the perceptual and neural responses, i.e., stimuli that evoked more stable percepts tended to evoke more stable neural responses. These results indicate that local contour-features modulate the responses of the neural population in V4 and contribute to the perception of FG organization., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024. Published by Elsevier Ltd.)

Published

2024

29. Neural Representations in Context

Author

Plebe, Alessio, De La Cruz, Vivian M., Capone, Alessandro, Editor-in-Chief, Allan, Keith, Advisory Editor, Cummings, Louise, Advisory Editor, Davis, Wayne A., Advisory Editor, Douven, Igor, Advisory Editor, Huang, Yan, Advisory Editor, Kecskes, Istvan, Advisory Editor, Lo Piparo, Franco, Advisory Editor, Pennisi, Antonino, Advisory Editor, Santuli, Francesca, Advisory Editor, Burton-Roberts, Noel, Editorial Board Member, Butler, Brian, Editorial Board Member, Carapezza, Marco, Editorial Board Member, Cimatti, Felice, Editorial Board Member, Corazza, Eros, Editorial Board Member, Dascal, Marcelo, Editorial Board Member, Devitt, Michael, Editorial Board Member, van Eemeren, Frans, Editorial Board Member, Falzone, Alessandra, Editorial Board Member, Feit, Neil, Editorial Board Member, Giorgi, Alessandra, Editorial Board Member, Horn, Larry, Editorial Board Member, von Heusinger, Klaus, Editorial Board Member, Jaszczolt, Katarzyna, Editorial Board Member, Kiefer, Ferenc, Editorial Board Member, Korta, Kepa, Editorial Board Member, Lepore, Ernest, Editorial Board Member, Levinson, Stephen C., Editorial Board Member, Macagno, Fabrizio, Editorial Board Member, Mey, Jacob L., Editorial Board Member, Perconti, Pietro, Editorial Board Member, Piazza, Francesca, Editorial Board Member, Posner, Roland, Editorial Board Member, Richard, Mark, Editorial Board Member, Salmon, Nathan, Editorial Board Member, Schiffer, Stephen R., Editorial Board Member, Seymour, Michel, Editorial Board Member, Simons, Mandy, Editorial Board Member, Williamson, Timothy, Editorial Board Member, Wierbizcka, Anna, Editorial Board Member, and Zielinska, Dorota, Editorial Board Member

Published

2020

30. Dual Population Coding for Path Planning in Graphs with Overlapping Place Representations

Author

Mallot, Hanspeter A., Ecke, Gerrit A., Baumann, Tristan, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Šķilters, Jurǵis, editor, Newcombe, Nora S., editor, and Uttal, David, editor

Published

2020

31. Coordinated multiplexing of information about separate objects in visual cortex

Author

Na Young Jun, Douglas A Ruff, Lily E Kramer, Brittany Bowes, Surya T Tokdar, Marlene R Cohen, and Jennifer M Groh

Subjects

noise correlations, variability, multiplexing, population coding, object vision, Medicine, Science, Biology (General), QH301-705.5

Abstract

Sensory receptive fields are large enough that they can contain more than one perceptible stimulus. How, then, can the brain encode information about each of the stimuli that may be present at a given moment? We recently showed that when more than one stimulus is present, single neurons can fluctuate between coding one vs. the other(s) across some time period, suggesting a form of neural multiplexing of different stimuli (Caruso et al., 2018). Here, we investigate (a) whether such coding fluctuations occur in early visual cortical areas; (b) how coding fluctuations are coordinated across the neural population; and (c) how coordinated coding fluctuations depend on the parsing of stimuli into separate vs. fused objects. We found coding fluctuations do occur in macaque V1 but only when the two stimuli form separate objects. Such separate objects evoked a novel pattern of V1 spike count (‘noise’) correlations involving distinct distributions of positive and negative values. This bimodal correlation pattern was most pronounced among pairs of neurons showing the strongest evidence for coding fluctuations or multiplexing. Whether a given pair of neurons exhibited positive or negative correlations depended on whether the two neurons both responded better to the same object or had different object preferences. Distinct distributions of spike count correlations based on stimulus preferences were also seen in V4 for separate objects but not when two stimuli fused to form one object. These findings suggest multiple objects evoke different response dynamics than those evoked by single stimuli, lending support to the multiplexing hypothesis and suggesting a means by which information about multiple objects can be preserved despite the apparent coarseness of sensory coding.

Published

2022

32. Translational neuronal ensembles: Neuronal microcircuits in psychology, physiology, pharmacology and pathology.

Author

Lara-González, Esther, Padilla-Orozco, Montserrat, Fuentes-Serrano, Alejandra, Bargas, José, and Duhne, Mariana

Subjects

PHYSIOLOGY, ANIMAL disease models, LARGE-scale brain networks, PHARMACOLOGY, PATHOLOGY, MEMORY trace (Psychology), LONG-term synaptic depression

Abstract

Multi-recording techniques show evidence that neurons coordinate their firing forming ensembles and that brain networks are made by connections between ensembles. While "canonical" microcircuits are composed of interconnected principal neurons and interneurons, it is not clear how they participate in recorded neuronal ensembles: "groups of neurons that show spatiotemporal co-activation". Understanding synapses and their plasticity has become complex, making hard to consider all details to fill the gap between cellular-synaptic and circuit levels. Therefore, two assumptions became necessary: First, whatever the nature of the synapses these may be simplified by "functional connections". Second, whatever the mechanisms to achieve synaptic potentiation or depression, the resultant synaptic weights are relatively stable. Both assumptions have experimental basis cited in this review, and tools to analyze neuronal populations are being developed based on them. Microcircuitry processing followed with multi-recording techniques show temporal sequences of neuronal ensembles resembling computational routines. These sequences can be aligned with the steps of behavioral tasks and behavior can be modified upon their manipulation, supporting the hypothesis that they are memory traces. In vitro, recordings show that these temporal sequences can be contained in isolated tissue of histological scale. Sequences found in control conditions differ from those recorded in pathological tissue obtained from animal disease models and those recorded after the actions of clinically useful drugs to treat disease states, setting the basis for new bioassays to test drugs with potential clinical use. These findings make the neuronal ensembles theoretical framework a dynamic neuroscience paradigm. [ABSTRACT FROM AUTHOR]

Published

2022

33. Integrated neural dynamics for behavioural decisions and attentional competition in the prefrontal cortex.

Author

Erez, Yaara, Kadohisa, Mikiko, Petrov, Philippe, Sigala, Natasha, Buckley, Mark J., Kusunoki, Makoto, and Duncan, John

Subjects

*PREFRONTAL cortex, *FRONTAL lobe diseases, *PRINCIPAL components analysis

Abstract

In the behaving monkey, complex neural dynamics in the prefrontal cortex contribute to context‐dependent decisions and attentional competition. We used demixed principal component analysis to track prefrontal activity dynamics in a cued target detection task. In this task, the animal combined identity of a visual object with a prior instruction cue to determine a target/nontarget decision. From population activity, we extracted principal components for each task feature and examined their time course and sensitivity to stimulus and task variations. For displays containing a single choice object in left or right hemifield, object identity, cue identity and decision were all encoded in population activity, with different dynamics and lateralisation. Object information peaked at 100–200 ms from display onset and was largely confined to the contralateral hemisphere. Cue information was weaker and present even prior to display onset. Integrating information from cue and object, decision information arose more slowly and was bilateral. Individual neurons contributed independently to coding of the three task features. The analysis was then extended to displays with a target in one hemifield and a competing distractor in the other. In this case, the data suggest that each hemisphere initially encoded the identity of the contralateral object. The distractor representation was then rapidly suppressed, with the final target decision again encoded bilaterally. The results show how information is coded along task‐related dimensions while competition is resolved and suggest how information flows within and across frontal lobes to implement a learned behavioural decision. [ABSTRACT FROM AUTHOR]

Published

2022

34. Translational neuronal ensembles: Neuronal microcircuits in psychology, physiology, pharmacology and pathology

Author

Esther Lara-González, Montserrat Padilla-Orozco, Alejandra Fuentes-Serrano, José Bargas, and Mariana Duhne

Subjects

neuronal ensembles, neuronal networks, functional connections, synaptic weights, population coding, Parkinson’s disease, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Multi-recording techniques show evidence that neurons coordinate their firing forming ensembles and that brain networks are made by connections between ensembles. While “canonical” microcircuits are composed of interconnected principal neurons and interneurons, it is not clear how they participate in recorded neuronal ensembles: “groups of neurons that show spatiotemporal co-activation”. Understanding synapses and their plasticity has become complex, making hard to consider all details to fill the gap between cellular-synaptic and circuit levels. Therefore, two assumptions became necessary: First, whatever the nature of the synapses these may be simplified by “functional connections”. Second, whatever the mechanisms to achieve synaptic potentiation or depression, the resultant synaptic weights are relatively stable. Both assumptions have experimental basis cited in this review, and tools to analyze neuronal populations are being developed based on them. Microcircuitry processing followed with multi-recording techniques show temporal sequences of neuronal ensembles resembling computational routines. These sequences can be aligned with the steps of behavioral tasks and behavior can be modified upon their manipulation, supporting the hypothesis that they are memory traces. In vitro, recordings show that these temporal sequences can be contained in isolated tissue of histological scale. Sequences found in control conditions differ from those recorded in pathological tissue obtained from animal disease models and those recorded after the actions of clinically useful drugs to treat disease states, setting the basis for new bioassays to test drugs with potential clinical use. These findings make the neuronal ensembles theoretical framework a dynamic neuroscience paradigm.

Published

2022

35. Unraveling Functional Diversity of Cortical Synaptic Architecture Through the Lens of Population Coding

Author

Jacob L. Yates and Benjamin Scholl

Subjects

synapse, two-photon imaging, population coding, visual cortex, input - output analysis, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The synaptic inputs to single cortical neurons exhibit substantial diversity in their sensory-driven activity. What this diversity reflects is unclear, and appears counter-productive in generating selective somatic responses to specific stimuli. One possibility is that this diversity reflects the propagation of information from one neural population to another. To test this possibility, we bridge population coding theory with measurements of synaptic inputs recorded in vivo with two-photon calcium imaging. We construct a probabilistic decoder to estimate the stimulus orientation from the responses of a realistic, hypothetical input population of neurons to compare with synaptic inputs onto individual neurons of ferret primary visual cortex (V1) recorded with two-photon calcium imaging in vivo. We find that optimal decoding requires diverse input weights and provides a straightforward mapping from the decoder weights to excitatory synapses. Analytically derived weights for biologically realistic input populations closely matched the functional heterogeneity of dendritic spines imaged in vivo with two-photon calcium imaging. Our results indicate that synaptic diversity is a necessary component of information transmission and reframes studies of connectivity through the lens of probabilistic population codes. These results suggest that the mapping from synaptic inputs to somatic selectivity may not be directly interpretable without considering input covariance and highlights the importance of population codes in pursuit of the cortical connectome.

Published

2022

36. Mixing novel and familiar cues modifies representations of familiar visual images and affects behavior.

Author

Nitzan, Noam, Bennett, Corbett, Movshon, J. Anthony, Olsen, Shawn R., and Buzsáki, György

Abstract

While visual responses to familiar and novel stimuli have been extensively studied, it is unknown how neuronal representations of familiar stimuli are affected when they are interleaved with novel images. We examined a large-scale dataset from mice performing a visual go/no-go change detection task. After training with eight images, six novel images were interleaved with two familiar ones. Unexpectedly, we found that the behavioral performance in response to familiar images was impaired when they were mixed with novel images. When familiar images were interleaved with novel ones, the dimensionality of their representation increased, indicating a perturbation of their neuronal responses. Furthermore, responses to familiar images in the primary visual cortex were less predictive of responses in higher-order areas, indicating less efficient communication. Spontaneous correlations between neurons were predictive of responses to novel images, but less so to familiar ones. Our study demonstrates the modification of representations of familiar images by novelty. [Display omitted] • Mice perform poorly on a change detection task when familiar and novel images are mixed • Neuronal responses to familiar images are perturbed when they are mixed with novel stimuli • Communication between visual areas during familiar stimuli is perturbed by novel stimuli • Mixing novel and familiar stimuli alters spontaneous correlations in the visual cortex Based on a large-scale dataset from mice trained on a visual go/no-go change detection task, Nitzan et al. found that mice's behavior is impaired when familiar and novel stimuli are mixed. The decrease in performance was paralleled by a series of physiological correlates, which persisted during spontaneous activity. [ABSTRACT FROM AUTHOR]

Published

2024

37. Mechanisms for Cognitive Impairment in Epilepsy: Moving Beyond Seizures.

Author

Khalife, Mohamed R., Scott, Rod C., and Hernan, Amanda E.

Subjects

COGNITION disorders, EPILEPSY, SEIZURES (Medicine), MEMORY disorders, INFORMATION processing

Abstract

There has been a major emphasis on defining the role of seizures in the causation of cognitive impairments like memory deficits in epilepsy. Here we focus on an alternative hypothesis behind these deficits, emphasizing the mechanisms of information processing underlying healthy cognition characterized as rate, temporal and population coding. We discuss the role of the underlying etiology of epilepsy in altering neural networks thereby leading to both the propensity for seizures and the associated cognitive impairments. In addition, we address potential treatments that can recover the network function in the context of a diseased brain, thereby improving both seizure and cognitive outcomes simultaneously. This review shows the importance of moving beyond seizures and approaching the deficits from a system-level perspective with the guidance of network neuroscience. [ABSTRACT FROM AUTHOR]

Published

2022

38. Optimal Population Coding for Dynamic Input by Nonequilibrium Networks.

Author

Chen, Kevin S.

Subjects

*RECURRENT neural networks, *ISING model, *NEURAL circuitry, *LINEAR network coding, *NEURAL codes

Abstract

The efficient coding hypothesis states that neural response should maximize its information about the external input. Theoretical studies focus on optimal response in single neuron and population code in networks with weak pairwise interactions. However, more biological settings with asymmetric connectivity and the encoding for dynamical stimuli have not been well-characterized. Here, we study the collective response in a kinetic Ising model that encodes the dynamic input. We apply gradient-based method and mean-field approximation to reconstruct networks given the neural code that encodes dynamic input patterns. We measure network asymmetry, decoding performance, and entropy production from networks that generate optimal population code. We analyze how stimulus correlation, time scale, and reliability of the network affect optimal encoding networks. Specifically, we find network dynamics altered by statistics of the dynamic input, identify stimulus encoding strategies, and show optimal effective temperature in the asymmetric networks. We further discuss how this approach connects to the Bayesian framework and continuous recurrent neural networks. Together, these results bridge concepts of nonequilibrium physics with the analyses of dynamics and coding in networks. [ABSTRACT FROM AUTHOR]

Published

2022

39. Methylphenidate as a causal test of translational and basic neural coding hypotheses.

Author

Ni, Amy M., Bowes, Brittany S., Ruff, Douglas A., and Cohen, Marlene R.

Subjects

*NEURAL codes, *ATTENTION-deficit hyperactivity disorder, *METHYLPHENIDATE, *NEUROBEHAVIORAL disorders, *NEUROSCIENCES

Abstract

Most systems neuroscience studies fall into one of two categories: basic science work aimed at understanding the relationship between neurons and behavior, or translational work aimed at developing treatments for neuropsychiatric disorders. Here we use these two approaches to inform and enhance each other. Our study both tests hypotheses about basic science neural coding principles and elucidates the neuronal mechanisms underlying clinically relevant behavioral effects of systemically administered methylphenidate (Ritalin). We discovered that orally administered methylphenidate, used clinically to treat attention deficit hyperactivity disorder (ADHD) and generally to enhance cognition, increases spatially selective visual attention, enhancing visual performance at only the attended location. Further, we found that this causal manipulation enhances vision in rhesus macaques specifically when it decreases the mean correlated variability of neurons in visual area V4. Our findings demonstrate that the visual system is a platform for understanding the neural underpinnings of both complex cognitive processes (basic science) and neuropsychiatric disorders (translation). Addressing basic science hypotheses, our results are consistent with a scenario in which methylphenidate has cognitively specific effects by working through naturally selective cognitive mechanisms. Clinically, our findings suggest that the often staggeringly specific symptoms of neuropsychiatric disorders may be caused and treated by leveraging general mechanisms. [ABSTRACT FROM AUTHOR]

Published

2022

40. Mechanisms for Cognitive Impairment in Epilepsy: Moving Beyond Seizures

Author

Mohamed R. Khalife, Rod C. Scott, and Amanda E. Hernan

Subjects

epilepsy, cognition, neural coding, information processing, place cells, population coding, Neurology. Diseases of the nervous system, RC346-429

Abstract

There has been a major emphasis on defining the role of seizures in the causation of cognitive impairments like memory deficits in epilepsy. Here we focus on an alternative hypothesis behind these deficits, emphasizing the mechanisms of information processing underlying healthy cognition characterized as rate, temporal and population coding. We discuss the role of the underlying etiology of epilepsy in altering neural networks thereby leading to both the propensity for seizures and the associated cognitive impairments. In addition, we address potential treatments that can recover the network function in the context of a diseased brain, thereby improving both seizure and cognitive outcomes simultaneously. This review shows the importance of moving beyond seizures and approaching the deficits from a system-level perspective with the guidance of network neuroscience.

Published

2022

41. Distinct representations of body and head motion are dynamically encoded by Purkinje cell populations in the macaque cerebellum

Author

Omid A Zobeiri and Kathleen E Cullen

Subjects

cerebellum, Purkinje cells, vestibular, proprioception, neurophysiology, population coding, Medicine, Science, Biology (General), QH301-705.5

Abstract

The ability to accurately control our posture and perceive our spatial orientation during self-motion requires knowledge of the motion of both the head and body. However, while the vestibular sensors and nuclei directly encode head motion, no sensors directly encode body motion. Instead, the integration of vestibular and neck proprioceptive inputs is necessary to transform vestibular information into the body-centric reference frame required for postural control. The anterior vermis of the cerebellum is thought to play a key role in this transformation, yet how its Purkinje cells transform multiple streams of sensory information into an estimate of body motion remains unknown. Here, we recorded the activity of individual anterior vermis Purkinje cells in alert monkeys during passively applied whole-body, body-under-head, and head-on-body rotations. Most Purkinje cells dynamically encoded an intermediate representation of self-motion between head and body motion. Notably, Purkinje cells responded to both vestibular and neck proprioceptive stimulation with considerable heterogeneity in their response dynamics. Furthermore, their vestibular responses were tuned to head-on-body position. In contrast, targeted neurons in the deep cerebellar nuclei are known to unambiguously encode either head or body motion across conditions. Using a simple population model, we established that combining responses of~40-50 Purkinje cells could explain the responses of these deep cerebellar nuclei neurons across all self-motion conditions. We propose that the observed heterogeneity in Purkinje cell response dynamics underlies the cerebellum’s capacity to compute the dynamic representation of body motion required to ensure accurate postural control and perceptual stability in our daily lives.

Published

2022

42. Decoding neurobiological spike trains using recurrent neural networks: a case study with electrophysiological auditory cortex recordings.

Author

Szabó, Péter and Barthó, Péter

Subjects

*ARTIFICIAL neural networks, *AUDITORY neurons, *NEURAL codes, *AUDITORY cortex, *FEATURE extraction, *ELECTROPHYSIOLOGY, *RECURRENT neural networks

Abstract

Recent advancements in multielectrode methods and spike-sorting algorithms enable the in vivo recording of the activities of many neurons at a high temporal resolution. These datasets offer new opportunities in the investigation of the biological neural code, including the direct testing of specific coding hypotheses, but they also reveal the limitations of present decoder algorithms. Classical methods rely on a manual feature extraction step, resulting in a feature vector, like the firing rates of an ensemble of neurons. In this paper, we present a recurrent neural-network-based decoder and evaluate its performance on experimental and artificial datasets. The experimental datasets were obtained by recording the auditory cortical responses of rats exposed to sound stimuli, while the artificial datasets represent preset encoding schemes. The task of the decoder was to classify the action potential timeseries according to the corresponding sound stimuli. It is illustrated that, depending on the coding scheme, the performance of the recurrent-network-based decoder can exceed the performance of the classical methods. We also show how randomized copies of the training datasets can be used to reveal the role of candidate spike-train features. We conclude that artificial neural network decoders can be a useful alternative to classical population vector-based techniques in studies of the biological neural code. [ABSTRACT FROM AUTHOR]

Published

2022

43. Learning-induced biases in the ongoing dynamics of sensory representations predict stimulus generalization

Author

Dominik F. Aschauer, Jens-Bastian Eppler, Luke Ewig, Anna R. Chambers, Christoph Pokorny, Matthias Kaschube, and Simon Rumpel

Subjects

mouse, auditory cortex, population coding, perception, chronic calcium imaging, response transitions, Biology (General), QH301-705.5

Abstract

Summary: Sensory stimuli have long been thought to be represented in the brain as activity patterns of specific neuronal assemblies. However, we still know relatively little about the long-term dynamics of sensory representations. Using chronic in vivo calcium imaging in the mouse auditory cortex, we find that sensory representations undergo continuous recombination, even under behaviorally stable conditions. Auditory cued fear conditioning introduces a bias into these ongoing dynamics, resulting in a long-lasting increase in the number of stimuli activating the same subset of neurons. This plasticity is specific for stimuli sharing representational similarity to the conditioned sound prior to conditioning and predicts behaviorally observed stimulus generalization. Our findings demonstrate that learning-induced plasticity leading to a representational linkage between the conditioned stimulus and non-conditioned stimuli weaves into ongoing dynamics of the brain rather than acting on an otherwise static substrate.

Published

2022

44. Constraints on the design of neuromorphic circuits set by the properties of neural population codes

Author

Stefano Panzeri, Ella Janotte, Alejandro Pequeño-Zurro, Jacopo Bonato, and Chiara Bartolozzi

Subjects

neural coding, neuromorphic circuit design, population coding, Electronic computers. Computer science, QA75.5-76.95

Abstract

In the brain, information is encoded, transmitted and used to inform behaviour at the level of timing of action potentials distributed over population of neurons. To implement neural-like systems in silico, to emulate neural function, and to interface successfully with the brain, neuromorphic circuits need to encode information in a way compatible to that used by populations of neuron in the brain. To facilitate the cross-talk between neuromorphic engineering and neuroscience, in this review we first critically examine and summarize emerging recent findings about how population of neurons encode and transmit information. We examine the effects on encoding and readout of information for different features of neural population activity, namely the sparseness of neural representations, the heterogeneity of neural properties, the correlations among neurons, and the timescales (from short to long) at which neurons encode information and maintain it consistently over time. Finally, we critically elaborate on how these facts constrain the design of information coding in neuromorphic circuits. We focus primarily on the implications for designing neuromorphic circuits that communicate with the brain, as in this case it is essential that artificial and biological neurons use compatible neural codes. However, we also discuss implications for the design of neuromorphic systems for implementation or emulation of neural computation.

Published

2023

45. Nonuniform magnetic domain-wall synapses enabled by population coding

Author

Ya Qiao, Yajun Zhang, and Zhe Yuan

Subjects

neuromorphic computing, magnetic domain walls, spin-transfer torque, population coding, Science, Physics, QC1-999

Abstract

Traditional artificial intelligence implemented in software is usually executed on accurate digital computers. Nevertheless, the nanoscale devices for the implementation of neuromorphic computing may not be ideally identical, and the performance is reduced by nonuniform devices. In biological brains, information is usually encoded by a cluster of neurons such that the variability of nerve cells does not influence the accuracy of human cognition and movement. Here, we introduce the population encoding strategy in neuromorphic computing and demonstrate that this strategy can overcome the problems caused by nonuniform devices. Using magnetic memristor device based on current-induced domain-wall motion as an example, we show that imperfect storage devices can be applied in a hardware network to perform principal component analysis (PCA), and the accuracy of unsupervised classification is comparable to that of conventional PCA using ideally accurate synaptic weights. Our results pave the way for hardware implementation of neuromorphic computing and lower the criteria for the uniformity of nanoscale devices.

Published

2023

46. Analysing the information contributions and anatomical arrangement of neurons in population codes

Author

Yarrow, Stuart James, Series, Peggy, and Bednar, Jim

Subjects

612.8, population coding, information theory, Fisher information, topographic maps

Abstract

Population coding—the transmission of information by the combined activity of many neurons—is a feature of many neural systems. Identifying the role played by individual neurons within a population code is vital for the understanding of neural codes. In this thesis I examine which stimuli are best encoded by a given neuron within a population and how this depends on the informational measure used, on commonly-measured neuronal properties, and on the population size and the spacing between stimuli. I also show how correlative measures of topography can be used to test for significant topography in the anatomical arrangement of arbitrary neuronal properties. The neurons involved in a population code are generally clustered together in one region of the brain, and moreover their response selectivity is often reflected in their anatomical arrangement within that region. Although such topographic maps are an often-encountered feature in the brains of many species, there are no standard, objective procedures for quantifying topography. Topography in neural maps is typically identified and described subjectively, but in cases where the scale of the map is close to the resolution limit of the measurement technique, identifying the presence of a topographic map can be a challenging subjective task. In such cases, an objective statistical test for detecting topography would be advantageous. To address these issues, I assess seven measures by quantifying topography in simulated neural maps, and show that all but one of these are effective at detecting statistically significant topography even in weakly topographic maps. The precision of the neural code is commonly investigated using two different families of statistical measures: (i) Shannon mutual information and derived quantities when investigating very small populations of neurons and (ii) Fisher information when studying large populations. The Fisher information always predicts that neurons convey most information about stimuli coinciding with the steepest regions of the tuning curve, but it is known that information theoretic measures can give very different predictions. Using a Monte Carlo approach to compute a stimulus-specific decomposition of the mutual information (the stimulus-specific information, or SSI) for populations up to hundreds of neurons in size, I address the following questions: (i) Under what conditions can Fisher information accurately predict the information transmitted by a neuron within a population code? (ii) What are the effects of level of trial-to-trial variability (noise), correlations in the noise, and population size on the best-encoded stimulus? (iii) How does the type of task in a behavioural experiment (i.e. fine and coarse discrimination, classification) affect the best-encoded stimulus? I show that, for both unimodal and monotonic tuning curves, the shape of the SSI is dependent upon trial-to-trial variability, population size and stimulus spacing, in addition to the shape of the tuning curve. It is therefore important to take these factors into account when assessing which stimuli a neuron is informative about; just knowing the tuning curve may not be sufficient.

Published

2015

47. Feature-specific divisive normalization improves natural image encoding for depth perception.

Author

Ni L and Burge J

Abstract

Vision science and visual neuroscience seek to understand how stimulus and sensor properties limit the precision with which behaviorally-relevant latent variables are encoded and decoded. In the primate visual system, binocular disparity-the canonical cue for stereo-depth perception-is initially encoded by a set of binocular receptive fields with a range of spatial frequency preferences. Here, with a stereo-image database having ground-truth disparity information at each pixel, we examine how response normalization and receptive field properties determine the fidelity with which binocular disparity is encoded in natural scenes. We quantify encoding fidelity by computing the Fisher information carried by the normalized receptive field responses. Several findings emerge from an analysis of the response statistics. First, broadband (or feature-unspecific) normalization yields Laplace-distributed receptive field responses, and narrowband (or feature-specific) normalization yields Gaussian-distributed receptive field responses. Second, the Fisher information in narrowband-normalized responses is larger than in broadband-normalized responses by a scale factor that grows with population size. Third, the most useful spatial frequency decreases with stimulus size and the range of spatial frequencies that is useful for encoding a given disparity decreases with disparity magnitude, consistent with neurophysiological findings. Fourth, the predicted patterns of psychophysical performance, and absolute detection threshold, match human performance with natural and artificial stimuli. The current computational efforts establish a new functional role for response normalization, and bring us closer to understanding the principles that should govern the design of neural systems that support perception in natural scenes.

Published

2024

48. Task-specific invariant representation in auditory cortex.

Author

Heller CR, Hamersky GR, and David SV

Subjects

Animals, Neurons physiology, Acoustic Stimulation, Auditory Cortex physiology, Ferrets, Auditory Perception physiology

Abstract

Categorical sensory representations are critical for many behaviors, including speech perception. In the auditory system, categorical information is thought to arise hierarchically, becoming increasingly prominent in higher-order cortical regions. The neural mechanisms that support this robust and flexible computation remain poorly understood. Here, we studied sound representations in the ferret primary and non-primary auditory cortex while animals engaged in a challenging sound discrimination task. Population-level decoding of simultaneously recorded single neurons revealed that task engagement caused categorical sound representations to emerge in non-primary auditory cortex. In primary auditory cortex, task engagement caused a general enhancement of sound decoding that was not specific to task-relevant categories. These findings are consistent with mixed selectivity models of neural disentanglement, in which early sensory regions build an overcomplete representation of the world and allow neurons in downstream brain regions to flexibly and selectively read out behaviorally relevant, categorical information., Competing Interests: CH, GH, SD No competing interests declared, (© 2023, Heller et al.)

Published

2024

49. Multiplexed Representation of Itch and Mechanical and Thermal Sensation in the Primary Somatosensory Cortex.

Author

Xiao-Jun Chen, Yan-He Liu, Ning-Long Xu, and Yan-Gang Sun

Subjects

*SOMATOSENSORY cortex, *PYRAMIDAL neurons, *ITCHING, *SENSES, *DENDRITIC spines, *NEURONS

Abstract

The primary somatosensory cortex (S1) plays a critical role in processing multiple somatosensations, but the mechanism underlying the representation of different submodalities of somatosensation in S1 remains unclear. Using in vivo two-photon calcium imaging that simultaneously monitors hundreds of layer 2/3 pyramidal S1 neurons of awake male mice, we examined neuronal responses triggered by mechanical, thermal, or pruritic stimuli. We found that mechanical, thermal, and pruritic stimuli activated largely overlapping neuronal populations in the same somatotopic S1 subregion. Population decoding analysis revealed that the local neuronal population in S1 encoded sufficient information to distinguish different somatosensory submodalities. Although multimodal S1 neurons responding to multiple types of stimuli exhibited no spatial clustering, S1 neurons preferring mechanical and thermal stimuli tended to show local clustering. These findings demonstrated the coding scheme of different submodalities of somatosensation in S1, paving the way for a deeper understanding of the processing and integration of multimodal somatosensory information in the cortex. [ABSTRACT FROM AUTHOR]

Published

2021

50. How REM sleep shapes hypothalamic computations for feeding behavior.

Author

Oesch, Lukas T. and Adamantidis, Antoine R.

Subjects

*RAPID eye movement sleep, *NON-REM sleep, *GABA transporters, *HOMEOSTASIS, *EYE movements, *ACTION theory (Psychology)

Abstract

The electrical activity of diverse brain cells is modulated across states of vigilance, namely wakefulness, non-rapid eye movement (NREM) sleep, and rapid eye movement (REM) sleep. Enhanced activity of neuronal circuits during NREM sleep impacts on subsequent awake behaviors, yet the significance of their activation, or lack thereof, during REM sleep remains unclear. This review focuses on feeding-promoting cells in the lateral hypothalamus (LH) that express the vesicular GABA and glycine transporter (vgat) as a model to further understand the impact of REM sleep on neural encoding of goal-directed behavior. It emphasizes both spatial and temporal aspects of hypothalamic cell dynamics across awake behaviors and REM sleep, and discusses a role for REM sleep in brain plasticity underlying energy homeostasis and behavioral optimization. Hypothalamic neurons have an input–output connectivity map that encompasses much of the brain in vertebrates. These neurons are central in the modulation of homeostatic behaviors including feeding and sleep, suggesting that specific hypothalamic circuits share diverse physiological functions. Patterns of activity of lateral hypothalamus (LH) inhibitory neurons during awake feeding behavior show a high diversity of discharge profiles. These patterns of low and high cellular activities are conserved during rapid eye movement (REM) sleep. Emerging evidence reveals a role for sleep in the stabilization of the behavior encoded by these circuits. Sleep-dependent tuning of hypothalamic feeding circuits may be essential for the stability of the internal representation of behavior, optimization of strategies for behavioral adaptation to the environment, and species perpetuation. Understanding the spatiotemporal encoding of hypothalamic-controlled behaviors (e.g., reproduction, social interactions, aversion, and fight/flight responses) may lead to a more comprehensive view of the role of sleep in hypothalamic physiology and pathologies. [ABSTRACT FROM AUTHOR]

Published

2021