Your search keyword '"neural coding"' showing total 8,880 results

251. Pansharpening of Satellite Images with Convolutional Sparse Coding and Adaptive PCNN-Based Approach

Author

Rajesh Gogineni, Shailesh Panchal, Rajesh A. Thakker, and Dhara J. Sangani

Subjects

biology, Computer science, business.industry, Geography, Planning and Development, Earth and Planetary Sciences (miscellaneous), Satellite (biology), Pattern recognition, Artificial intelligence, business, Neural coding, biology.organism_classification

Published

2021

252. Neuronal architecture and functional mapping of the taste center of larval Helicoverpa armigera (Lepidoptera: Noctuidae)

Author

Gui-Ying Xie, Ya-Nan Wang, Yang Liu, Guirong Wang, Bente Gunnveig Berg, Qing-Bo Tang, Wenbo Chen, Longlong Sun, Xin-Cheng Zhao, and XiaoLan Liu

Subjects

Taste, Sensory Receptor Cells, Interneuron, media_common.quotation_subject, Sensory system, Insect, Moths, Biology, Helicoverpa armigera, General Biochemistry, Genetics and Molecular Biology, medicine, Animals, Herbivory, Ecology, Evolution, Behavior and Systematics, media_common, fungi, Motor neuron, biology.organism_classification, Sensory neuron, Lepidoptera, medicine.anatomical_structure, nervous system, Larva, Insect Science, Neural coding, Agronomy and Crop Science, Neuroscience

Abstract

The sense of taste plays a crucial role in herbivorous insects by discriminating nutrients from complex plant metabolic compounds. The peripheral coding of taste has been thoroughly studied in many insect species, but the central gustatory pathways are poorly described. In the present study, we characterized single neurons in the gnathal ganglion of Helicoverpa armigera larvae using the intracellular recording/staining technique. We identified different types of neurons, including sensory neurons, interneurons, and motor neurons. The morphologies of these neurons were largely diverse and their arborizations seemingly covered the whole gnathal ganglion. The representation of the single neurons responding to the relevant stimuli of sweet and bitter cues showed no distinct patterns in the gnathal ganglion. We postulate that taste signals may be processed in a manner consistent with the principle of population coding in the gnathal ganglion of H. armigera larvae. This article is protected by copyright. All rights reserved.

Published

2021

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

Author

Peter Bartho and Péter Szabó

Subjects

Artificial neural network, Computer science, business.industry, Feature vector, Feature extraction, Pattern recognition, Auditory cortex, Recurrent neural network, Artificial Intelligence, Artificial intelligence, Neural coding, business, Encoder, Software, Decoding methods, Coding (social sciences)

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.

Published

2021

254. Demonstration of Stochastic Resonance, Population Coding, and Population Voting Using Artificial MoS2 Based Synapses

Author

Akhil Dodda and Saptarshi Das

Subjects

education.field_of_study, Noise (signal processing), Stochastic resonance, Computer science, business.industry, Population, General Engineering, General Physics and Astronomy, Pattern recognition, Synaptic noise, symbols.namesake, Additive white Gaussian noise, symbols, Redundancy (engineering), General Materials Science, Detection theory, Artificial intelligence, education, Neural coding, business

Abstract

Fast detection of weak signals at low energy expenditure is a challenging but inescapable task for the evolutionary success of animals that survive in resource constrained environments. This task is accomplished by the sensory nervous system by exploiting the synergy between three astounding neural phenomena, namely, stochastic resonance (SR), population coding (PC), and population voting (PV). In SR, the constructive role of synaptic noise is exploited for the detection of otherwise invisible signals. In PC, the redundancy in neural population is exploited to reduce the detection latency. Finally, PV ensures unambiguous signal detection even in the presence of excessive noise. Here we adopt a similar strategies and experimentally demonstrate how a population of stochastic artificial neurons based on monolayer MoS2 field effect transistors (FETs) can use an optimum amount of white Gaussian noise and population voting to detect invisible signals at a frugal energy expenditure (∼10s of nano-Joules). Our findings can aid remote sensing in the emerging era of the Internet of things (IoT) that thrive on energy efficiency.

Published

2021

255. Cross-domain EEG signal classification via geometric preserving transfer discriminative dictionary learning

Author

Jia Qu, Tongguang Ni, Xiaoqing Gu, and Zongxuan Shen

Subjects

Computer Networks and Communications, business.industry, Computer science, Pattern recognition, Sparse approximation, Signal, Domain (software engineering), ComputingMethodologies_PATTERNRECOGNITION, Discriminative model, Hardware and Architecture, Classifier (linguistics), Media Technology, Artificial intelligence, Laplacian matrix, business, Neural coding, Software, Subspace topology

Abstract

EEG signal classification is a key technology for EEG signal processing and identification systems. Dictionary learning has shown excellent performance due to its sparse representation and learning capability. Usually dictionary learning requires sufficient labeled EEG signals to build classification models, and assumes that the data distribution of training and test signals are the same. However, in new EEG signal domain, often only a small amount of signals are labeled, and more are not labeled. At the same time, data dynamicity, confounding factors and strong interclass similarity also seriously disrupt the performance of EEG signal classifier. To this end, a geometric preserving transfer discriminative dictionary learning method called GPTDDL is developed for cross-domain EEG signal classification. Through projected signals of different domains to the common subspace, a shared discriminative dictionary is obtained, which explores the geometric structure information by graph Laplacian regularization and discriminative information by principal component analysis regularization. Benefiting from the discriminative information transferred from source domain, the discriminability of the learned sparse coding of target domain is strengthened. GPTDDL integrates this idea into the framework of LC-KSVD, and learns the subspace and dictionary learning parameters in an iterative strategy. The experimental results on Bonn EEG signal dataset demonstrate the validity of the GPTDDL method.

Published

2021

256. Interpretable convolutional sparse coding method of Lamb waves for damage identification and localization

Author

Jing Lin, Tong Tong, Jiadong Hua, and Han Zhang

Subjects

Identification (information), Lamb waves, business.industry, Computer science, Mechanical Engineering, Nondestructive testing, Biophysics, Pattern recognition, Artificial intelligence, Structural health monitoring, business, Neural coding, Interpretability

Abstract

Lamb wave-based damage identification and localization methods hold the potential for nondestructive evaluation and structural health monitoring. Dispersive and multimodal characteristics lead to complicated Lamb wave signals that are challenging to be analyzed. Deep learning architectures could identify damage-related features effectively. Convolutional neural network (CNN) is a promising architecture that has been widely applied in recent years. However, this data-driven approach still lacks a certain degree of physical interpretability and requires a large number of parameters. In this article, an interpretable Lamb wave convolutional sparse coding (LW-CSC) method is proposed for structural damage identification and localization. First, toneburst signals at different center frequencies are considered in the first convolutional layer. The network convolves the waveforms with a set of parametrized functions that implement band-pass filters, which performs more physical interpretability compared to conventional CNN model. Subsequently, the damage features are extracted according to the multi-layer iterative soft thresholding algorithm for multi-layer CSC model, which could realize a deeper network without adding parameters unlike CNN. Finally, Lamb wave-based damage localization is visualized using an imaging algorithm. The experimental results demonstrate that the proposed method not only enables improvement of the classification accuracy but also achieves structural damage localization accurately.

Published

2021

257. Similarity Based Block Sparse Subset Selection for Video Summarization

Author

David Dagan Feng, Shaohui Mei, Mingyang Ma, Shuai Wan, Zhiyong Wang, and Mohammed Bennamoun

Subjects

Selection (relational algebra), business.industry, Computer science, Feature vector, Frame (networking), Pattern recognition, Automatic summarization, Kernel (linear algebra), Similarity (network science), Media Technology, Artificial intelligence, Electrical and Electronic Engineering, business, Neural coding, Sparse matrix

Abstract

Video summarization (VS) is generally formulated as a subset selection problem where a set of representative keyframes or key segments is selected from an entire video frame set. Though many sparse subset selection based VS algorithms have been proposed in the past decade, most of them adopt linear sparse formulation in the explicit feature vector space of video frames, and don’t consider the local or global relationships among frames. In this paper, we first extend the conventional sparse subset selection for VS into kernel block sparse subset selection (KBS3) to utilize the advantage of kernel sparse coding and introduce a local inter-frame relationship through packing of frame blocks. Going a step further, we propose a similarity based block sparse subset selection (SB2S3) model by applying a specially designed transformation matrix on the KBS3 model in order to introduce a kind of global inter-frame relationship through the similarity. Finally, a greedy pursuit based algorithm is devised for the proposed NP-hard model optimization. The proposed SB2S3 has the following advantages: 1) through the similarity between each frame and any other frame, the global relationship among all frames can be considered; 2) through block sparse coding, the local relationship of adjacent frames is further considered; and 3) it has a wider application, since features can derive similarity, but not vice versa. It is believed that the effect of modeling such global and local relationships among frames in this paper, is similar to that of modeling the long-range and short-range dependencies among frames in deep learning based methods. Experimental results on three benchmark datasets have demonstrated that the proposed approach is superior to not only other sparse subset selection based VS methods but also most unsupervised deep-learning based VS methods.

Published

2021

258. Reversible Fronto-occipitotemporal Signaling Complements Task Encoding and Switching under Ambiguous Cues

Author

Junichi Chikazoe, Kaho Tsumura, Koji Jimura, Yoshiki Hattori, Kiyoshi Nakahara, Ryuta Aoki, Keita Kosugi, and Masaki Takeda

Subjects

Cued speech, Brain Mapping, Computer science, Cognitive Neuroscience, Brain, Prefrontal Cortex, Flexibility (personality), Magnetic Resonance Imaging, Task (project management), Cellular and Molecular Neuroscience, Encoding (memory), Alternation (linguistics), Cues, Neural coding, Prefrontal cortex, Neuroscience, Coding (social sciences)

Abstract

Adaptation to changing environments involves the appropriate extraction of environmental information to achieve a behavioral goal. It remains unclear how behavioral flexibility is guided under situations where the relevant behavior is ambiguous. Using functional brain mapping of machine learning decoders and directional functional connectivity, we show that brain-wide reversible neural signaling underpins task encoding and behavioral flexibility in ambiguously changing environments. When relevant behavior is cued ambiguously during behavioral shifting, neural coding is attenuated in distributed cortical regions, but top-down signals from the prefrontal cortex complement the coding. When behavioral shifting is cued more explicitly, modality-specialized occipitotemporal regions implement distinct neural coding about relevant behavior, and bottom-up signals from the occipitotemporal region to the prefrontal cortex supplement the behavioral shift. These results suggest that our adaptation to an ever-changing world is orchestrated by the alternation of top-down and bottom-up signaling in the fronto-occipitotemporal circuit depending on the availability of environmental information.

Published

2021

259. Reliable Sensory Processing in Mouse Visual Cortex through Cooperative Interactions between Somatostatin and Parvalbumin Interneurons

Author

Mriganka Sur, Murat Yildirim, Ming Hu, Vincent Breton-Provencher, and Rajeev V. Rikhye

Subjects

Male, genetic structures, Mice, Transgenic, Sensory system, Optogenetics, Mice, Calcium imaging, Interneurons, medicine, Animals, Research Articles, Visual Cortex, biology, General Neuroscience, fungi, food and beverages, Mice, Inbred C57BL, Parvalbumins, medicine.anatomical_structure, Visual cortex, nervous system, biology.protein, Female, Perception, Neuron, Pyramidal cell, Somatostatin, Neural coding, Neuroscience, Parvalbumin

Abstract

Intrinsic neuronal variability significantly limits information encoding in the primary visual cortex (V1). However, under certain conditions, neurons can respond reliably with highly precise responses to the same visual stimuli from trial to trial. This suggests that there exists intrinsic neural circuit mechanisms that dynamically modulate the intertrial variability of visual cortical neurons. Here, we sought to elucidate the role of different inhibitory interneurons (INs) in reliable coding in mouse V1. To study the interactions between somatostatin-expressing interneurons (SST-INs) and parvalbumin-expressing interneurons (PV-INs), we used a dual-color calcium imaging technique that allowed us to simultaneously monitor these two neural ensembles while awake mice, of both sexes, passively viewed natural movies. SST neurons were more active during epochs of reliable pyramidal neuron firing, whereas PV neurons were more active during epochs of unreliable firing. SST neuron activity lagged that of PV neurons, consistent with a feedback inhibitory SST→PV circuit. To dissect the role of this circuit in pyramidal neuron activity, we used temporally limited optogenetic activation and inactivation of SST and PV interneurons during periods of reliable and unreliable pyramidal cell firing. Transient firing of SST neurons increased pyramidal neuron reliability by actively suppressing PV neurons, a proposal that was supported by a rate-based model of V1 neurons. These results identify a cooperative functional role for the SST→PV circuit in modulating the reliability of pyramidal neuron activity.SIGNIFICANCE STATEMENTCortical neurons often respond to identical sensory stimuli with large variability. However, under certain conditions, the same neurons can also respond highly reliably. The circuit mechanisms that contribute to this modulation remain unknown. Here, we used novel dual-wavelength calcium imaging and temporally selective optical perturbation to identify an inhibitory neural circuit in visual cortex that can modulate the reliability of pyramidal neurons to naturalistic visual stimuli. Our results, supported by computational models, suggest that somatostatin interneurons increase pyramidal neuron reliability by suppressing parvalbumin interneurons via the inhibitory SST→PV circuit. These findings reveal a novel role of the SST→PV circuit in modulating the fidelity of neural coding critical for visual perception.

Published

2021

260. Model-based signal processing enables bidirectional inferring between local field potential and spikes evoked by noxious stimulation

Author

Radhouane Dallel, Lénaïc Monconduit, F. Gabrielli, Philippe Luccarini, and M. Megemont

Subjects

Male, Nociception, 0301 basic medicine, Signal Detection, Psychological, genetic structures, Models, Neurological, Population, Probability density function, Local field potential, Nerve Fibers, Myelinated, Membrane Potentials, Convolution, Rats, Sprague-Dawley, 03 medical and health sciences, 0302 clinical medicine, Physical Stimulation, Noxious stimulus, Animals, education, Evoked Potentials, Physics, Nerve Fibers, Unmyelinated, Signal processing, education.field_of_study, musculoskeletal, neural, and ocular physiology, General Neuroscience, Electroencephalography, Electrophysiological Phenomena, Rats, Posterior Horn Cells, 030104 developmental biology, nervous system, Kernel (image processing), Neural coding, Biological system, Algorithms, 030217 neurology & neurosurgery

Abstract

Background Recording spontaneous and evoked activities by means of unitary extracellular recordings and local field potential (LFP) are key understanding the mechanisms of neural coding. The LFP is one of the most popular and easy methods to measure the activity of a population of neurons. LFP is also a composite signal known to be difficult to interpret and model. There is a growing need to highlight the relationship between spiking activity and LFP. Here, we hypothesized that LFP could be inferred from spikes under evoked noxious conditions. Method Recording was performed from the medullary dorsal horn (MDH) in deeply anesthetized rats. We detail a process to highlight the C-fiber (nociceptive) evoked activity, by removing the A-fiber evoked activity using a model-based approach. Then, we applied the convolution kernel theory and optimization algorithms to infer the C-fiber LFP from the single cell spikes. Finally, we used a probability density function and an optimization algorithm to infer the spikes distribution from the LFP. Results We successfully extracted C-fiber LFP in all data recordings. We observed that C-fibers spikes preceded the C-fiber LFP and were rather correlated to the LFP derivative. Finally, we inferred LFP from spikes with excellent correlation coefficient (r = 0.9) and reverse generated the spikes distribution from LFP with good correlation coefficients (r = 0.7) on spikes number. Conclusion We introduced the kernel convolution theory to successfully infer the LFP from spikes, and we demonstrated that we could generate the spikes distribution from the LFP.

Published

2021

261. Building partially understandable convolutional neural networks by differentiating class-related neural nodes

Author

Dawei Dai, Chengfu Tang, Shuyin Xia, and Guoyin Wang

Subjects

0209 industrial biotechnology, Artificial neural network, Computer science, business.industry, Cognitive Neuroscience, 02 engineering and technology, Convolutional neural network, Field (computer science), Computer Science Applications, Task (project management), 020901 industrial engineering & automation, Artificial Intelligence, Encoding (memory), 0202 electrical engineering, electronic engineering, information engineering, Feature (machine learning), 020201 artificial intelligence & image processing, Artificial intelligence, business, Neural coding, Coding (social sciences)

Abstract

In recent years, convolutional neural networks (CNNs) have been successfully applied in the field of image processing, and have been deployed to a variety of artificial intelligence systems. However, such neural models are still considered to be “black box” for most tasks. Two of fundamental issues underlying this problem are as follows: 1. What type of knowledge learned by a neural network in a task was not understandable and predictable? 2. The decision made by a neural model was generally not evaluable. Like neural coding in the brain, some neurons only participated in encoding a particular task. Inspired by this, in this paper, we propose a method to modify traditional CNN models into understandable CNNs, to clarify the information coding in high conv-layers of CNNs and further evaluate the decisions made by a neural model. In our understandable CNN models, each neural node (feature map) in a selected conv-layer was assigned to participate in encoding only one class in a classification task. Our models use the same training data as ordinary models without the need for additional annotations for supervision. We applied our method to the ResNet and DenseNet models. The experiments showed that new models can learn the information coding mode that we expected in an image-recognition task, and, using the pre-assigned coding mode, we can interpret why a neural model makes a right or wrong decision, which decisions are credible, and which are not.

Published

2021

262. Descending neurons of the hoverfly respond to pursuits of artificial targets.

Author

Ogawa Y, Nicholas S, Thyselius M, Leibbrandt R, Nowotny T, Knight JC, and Nordström K

Subjects

Animals, Male, Neurons physiology, Visual Fields, Vision, Ocular, Photic Stimulation, Motion Perception physiology, Diptera physiology

Abstract

Many animals use motion vision information to control dynamic behaviors. Predatory animals, for example, show an exquisite ability to detect rapidly moving prey, followed by pursuit and capture. Such target detection is not only used by predators but is also important in conspecific interactions, such as for male hoverflies defending their territories against conspecific intruders. Visual target detection is believed to be subserved by specialized target-tuned neurons found in a range of species, including vertebrates and arthropods. However, how these target-tuned neurons respond to actual pursuit trajectories is currently not well understood. To redress this, we recorded extracellularly from target-selective descending neurons (TSDNs) in male Eristalis tenax hoverflies. We show that they have dorso-frontal receptive fields with a preferred direction up and away from the visual midline. We reconstructed visual flow fields as experienced during pursuits of artificial targets (black beads). We recorded TSDN responses to six reconstructed pursuits and found that each neuron responded consistently at remarkably specific time points but that these time points differed between neurons. We found that the observed spike probability was correlated with the spike probability predicted from each neuron's receptive field and size tuning. Interestingly, however, the overall response rate was low, with individual neurons responding to only a small part of each reconstructed pursuit. In contrast, the TSDN population responded to substantially larger proportions of the pursuits but with lower probability. This large variation between neurons could be useful if different neurons control different parts of the behavioral output., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

263. Exploiting noise as a resource for computation and learning in spiking neural networks.

Author

Ma G, Yan R, and Tang H

Abstract

Networks of spiking neurons underpin the extraordinary information-processing capabilities of the brain and have become pillar models in neuromorphic artificial intelligence. Despite extensive research on spiking neural networks (SNNs), most studies are established on deterministic models, overlooking the inherent non-deterministic, noisy nature of neural computations. This study introduces the noisy SNN (NSNN) and the noise-driven learning (NDL) rule by incorporating noisy neuronal dynamics to exploit the computational advantages of noisy neural processing. The NSNN provides a theoretical framework that yields scalable, flexible, and reliable computation and learning. We demonstrate that this framework leads to spiking neural models with competitive performance, improved robustness against challenging perturbations compared with deterministic SNNs, and better reproducing probabilistic computation in neural coding. Generally, this study offers a powerful and easy-to-use tool for machine learning, neuromorphic intelligence practitioners, and computational neuroscience researchers., Competing Interests: The authors declare no competing interests., (© 2023 The Authors.)

Published

2023

264. A robust and compact population code for competing sounds in auditory cortex.

Author

Nocon JC, Witter J, Gritton H, Han X, Houghton C, and Sen K

Subjects

Humans, Animals, Mice, Sound, Neurons, Auditory Cortex

Abstract

Cortical circuits encoding sensory information consist of populations of neurons, yet how information aggregates via pooling individual cells remains poorly understood. Such pooling may be particularly important in noisy settings where single-neuron encoding is degraded. One example is the cocktail party problem, with competing sounds from multiple spatial locations. How populations of neurons in auditory cortex code competing sounds have not been previously investigated. Here, we apply a novel information-theoretic approach to estimate information in populations of neurons in mouse auditory cortex about competing sounds from multiple spatial locations, including both summed population (SP) and labeled line (LL) codes. We find that a small subset of neurons is sufficient to nearly maximize mutual information over different spatial configurations, with the labeled line code outperforming the summed population code and approaching information levels attained in the absence of competing stimuli. Finally, information in the labeled line code increases with spatial separation between target and masker, in correspondence with behavioral results on spatial release from masking in humans and animals. Taken together, our results reveal that a compact population of neurons in auditory cortex provides a robust code for competing sounds from different spatial locations. NEW & NOTEWORTHY Little is known about how populations of neurons within cortical circuits encode sensory stimuli in the presence of competing stimuli at other spatial locations. Here, we investigate this problem in auditory cortex using a recently proposed information-theoretic approach. We find a small subset of neurons nearly maximizes information about target sounds in the presence of competing maskers, approaching information levels for isolated stimuli, and provides a noise-robust code for sounds in a complex auditory scene.

Published

2023

265. The Representation of the Pitch of Vowel Sounds in Ferret Auditory Cortex

Author

Schnupp, Jan, King, Andrew, Walker, Kerry, Bizley, Jennifer, Lopez-Poveda, Enrique A., editor, Palmer, Alan R., editor, and Meddis, Ray, editor

Published

2010

266. Short-Term Synaptic Plasticity and Adaptation Contribute to the Coding of Timing and Intensity Information

Author

MacLeod, Katrina, Ashida, Go, Glaze, Chris, Carr, Catherine, Lopez-Poveda, Enrique A., editor, Palmer, Alan R., editor, and Meddis, Ray, editor

Published

2010

267. Logarithmic distributions prove that intrinsic learning is Hebbian [version 2; referees: 2 approved]

Author

Gabriele Scheler

Subjects

Research Article, Articles, Theoretical & Computational Neuroscience, neural coding, synaptic weights, Hebbian learning, intrinsic excitability, rate coding, spike frequency, neural circuits, neural networks, lognormal distributions.

Abstract

In this paper, we present data for the lognormal distributions of spike rates, synaptic weights and intrinsic excitability (gain) for neurons in various brain areas, such as auditory or visual cortex, hippocampus, cerebellum, striatum, midbrain nuclei. We find a remarkable consistency of heavy-tailed, specifically lognormal, distributions for rates, weights and gains in all brain areas examined. The difference between strongly recurrent and feed-forward connectivity (cortex vs. striatum and cerebellum), neurotransmitter (GABA (striatum) or glutamate (cortex)) or the level of activation (low in cortex, high in Purkinje cells and midbrain nuclei) turns out to be irrelevant for this feature. Logarithmic scale distribution of weights and gains appears to be a general, functional property in all cases analyzed. We then created a generic neural model to investigate adaptive learning rules that create and maintain lognormal distributions. We conclusively demonstrate that not only weights, but also intrinsic gains, need to have strong Hebbian learning in order to produce and maintain the experimentally attested distributions. This provides a solution to the long-standing question about the type of plasticity exhibited by intrinsic excitability.

Published

2017

268. Logarithmic distributions prove that intrinsic learning is Hebbian [version 1; referees: 1 approved, 1 approved with reservations]

Author

Gabriele Scheler

Subjects

Research Article, Articles, Theoretical & Computational Neuroscience, neural coding, synaptic weights, Hebbian learning, intrinsic excitability, rate coding, spike frequency, neural circuits, neural networks, lognormal distributions.

Abstract

In this paper, we document lognormal distributions for spike rates, synaptic weights and intrinsic excitability (gain) for neurons in various brain areas, such as auditory or visual cortex, hippocampus, cerebellum, striatum, midbrain nuclei. We find a remarkable consistency of heavy-tailed, specifically lognormal, distributions for rates, weights and gains in all brain areas. The difference between strongly recurrent and feed-forward connectivity (cortex vs. striatum and cerebellum), neurotransmitter (GABA (striatum) or glutamate (cortex)) or the level of activation (low in cortex, high in Purkinje cells and midbrain nuclei) turns out to be irrelevant for this feature. Logarithmic scale distribution of weights and gains appears as a functional property that is present everywhere. Secondly, we created a generic neural model to show that Hebbian learning will create and maintain lognormal distributions. We could prove with the model that not only weights, but also intrinsic gains, need to have strong Hebbian learning in order to produce and maintain the experimentally attested distributions. This settles a long-standing question about the type of plasticity exhibited by intrinsic excitability.

Published

2017

269. Dynamic population coding and its relationship to working memory.

Author

Meyers, Ethan M.

Subjects

*SHORT-term memory, *NEUROPHYSIOLOGY, *PREFRONTAL cortex, *NEUROSCIENCES, *DYNAMICAL systems

Abstract

For over 45 years, neuroscientists have conducted experiments aimed at understanding the neural basis of working memory. Early results examining individual neurons highlighted that information is stored in working memory in persistent sustained activity where neurons maintained elevated firing rates over extended periods of time. However, more recent work has emphasized that information is often stored in working memory in dynamic population codes, where different neurons contain information at different periods in time. In this paper, I review findings that show that both sustained activity as well as dynamic codes are present in the prefrontal cortex and other regions during memory delay periods. I also review work showing that dynamic codes are capable of supporting working memory and that such dynamic codes could easily be "readout" by downstream regions. Finally, I discuss why dynamic codes could be useful for enabling animals to solve tasks that involve working memory. Although additional work is still needed to know definitively whether dynamic coding is critical for working memory, the findings reviewed here give insight into how different codes could contribute to working memory, which should be useful for guiding future research. [ABSTRACT FROM AUTHOR]

Published

2018

270. Changes in Neuronal Representations of Consonants in the Ascending Auditory System and Their Role in Speech Recognition.

Author

Steadman, Mark A. and Sumner, Christian J.

Abstract

A fundamental task of the ascending auditory system is to produce representations that facilitate the recognition of complex sounds. This is particularly challenging in the context of acoustic variability, such as that between different talkers producing the same phoneme. These representations are transformed as information is propagated throughout the ascending auditory system from the inner ear to the auditory cortex (AI). Investigating these transformations and their role in speech recognition is key to understanding hearing impairment and the development of future clinical interventions. Here, we obtained neural responses to an extensive set of natural vowel-consonant-vowel phoneme sequences, each produced by multiple talkers, in three stages of the auditory processing pathway. Auditory nerve (AN) representations were simulated using a model of the peripheral auditory system and extracellular neuronal activity was recorded in the inferior colliculus (IC) and primary auditory cortex (AI) of anaesthetized guinea pigs. A classifier was developed to examine the efficacy of these representations for recognizing the speech sounds. Individual neurons convey progressively less information from AN to AI. Nonetheless, at the population level, representations are sufficiently rich to facilitate recognition of consonants with a high degree of accuracy at all stages indicating a progression from a dense, redundant representation to a sparse, distributed one. We examined the timescale of the neural code for consonant recognition and found that optimal timescales increase throughout the ascending auditory system from a few milliseconds in the periphery to several tens of milliseconds in the cortex. Despite these longer timescales, we found little evidence to suggest that representations up to the level of AI become increasingly invariant to across-talker differences. Instead, our results support the idea that the role of the subcortical auditory system is one of dimensionality expansion, which could provide a basis for flexible classification of arbitrary speech sounds. [ABSTRACT FROM AUTHOR]

Published

2018

271. Taste sensitivity and divergence in host plant acceptance between adult females and larvae of Papilio hospiton.

Author

Sollai, Giorgia, Biolchini, Maurizio, and Crnjar, Roberto

Subjects

*TASTE, *PHAGOSTIMULANTS, *FERULA, *PAPILIO, *PAPILIONIDAE, *LEPIDOPTERA

Abstract

Abstract: On the island of Sardinia the lepidopteran Papilio hospiton uses Ferula communis as exclusive host plant. However, on the small island of Tavolara, adult females lay eggs on Seseli tortuosum, a plant confined to the island. When raised in captivity on Seseli only few larvae grew beyond the first–second instar. Host specificity of lepidopterans is determined by female oviposition preferences, but also by larval food acceptance, and adult and larval taste sensitivity may be related to host selection in both cases. Aim of this work was: (i) to study the taste sensitivity of larvae and ovipositing females to saps of Ferula and Seseli; (ii) to cross‐compare the spike activity of gustatory receptor neurons (GRNs) to both taste stimuli; (iii) to evaluate the discriminating capability between the two saps and determine which neural code/s is/are used. The results show that: (i) the spike responses of the tarsal GRNs of adult females to both plant saps are not different and therefore they cannot discriminate the two plants; (ii) larval L‐lat GRN shows a higher activity in response to Seseli than Ferula, while the opposite occurs for the phagostimulant neurons, and larvae may discriminate between the two saps by means of multiple neural codes; (iii) the number of eggs laid on the two plants is the same, but the larval growth performance is better on Ferula than Seseli. Taste sensitivity differences may explain the absence of a positive relationship between oviposition preferences by adult females and plant acceptance and growth performance by larvae. [ABSTRACT FROM AUTHOR]

Published

2018

272. Optimal Localist and Distributed Coding of Spatiotemporal Spike Patterns Through STDP and Coincidence Detection.

Author

Masquelier, Timothée and Kheradpisheh, Saeed R.

Subjects

SUPERVISED learning, SIGNAL-to-noise ratio, SPATIO-temporal variation, MATERIAL plasticity, POISSON processes

Abstract

Repeating spatiotemporal spike patterns exist and carry information. Here we investigated how a single spiking neuron can optimally respond to one given pattern (localist coding), or to either one of several patterns (distributed coding, i.e., the neuron's response is ambiguous but the identity of the pattern could be inferred from the response of multiple neurons), but not to random inputs. To do so, we extended a theory developed in a previous paper (Masquelier, 2017), which was limited to localist coding. More specifically, we computed analytically the signal-to-noise ratio (SNR) of a multi-pattern-detector neuron, using a threshold-free leaky integrate-and-fire (LIF) neuron model with non-plastic unitary synapses and homogeneous Poisson inputs. Surprisingly, when increasing the number of patterns, the SNR decreases slowly, and remains acceptable for several tens of independent patterns. In addition, we investigated whether spike-timing-dependent plasticity (STDP) could enable a neuron to reach the theoretical optimal SNR. To this aim, we simulated a LIF equipped with STDP, and repeatedly exposed it to multiple input spike patterns, embedded in equally dense Poisson spike trains. The LIF progressively became selective to every repeating pattern with no supervision, and stopped discharging during the Poisson spike trains. Furthermore, tuning certain STDP parameters, the resulting pattern detectors were optimal. Tens of independent patterns could be learned by a single neuron using a low adaptive threshold, in contrast with previous studies, in which higher thresholds led to localist coding only. Taken together these results suggest that coincidence detection and STDP are powerful mechanisms, fully compatible with distributed coding. Yet we acknowledge that our theory is limited to single neurons, and thus also applies to feed-forward networks, but not to recurrent ones. [ABSTRACT FROM AUTHOR]

Published

2018

273. Code Under Construction: Neural Coding Over Development.

Author

Avitan, Lilach and Goodhill, Geoffrey J.

Subjects

*NEURAL codes, *MAMMALS, *RECEPTIVE fields (Neurology), *SENSORY stimulation, *SENSORY neurons

Abstract

Developing animals must begin to interact with the world before their neural development is complete. This means they must build neural codes appropriate for turning sensory inputs into motor outputs adaptively as their neural hardware matures. We review some recent progress in the understanding of the relationship between neural coding and neural circuit development. We focus particularly on neural coding in the context of topographic maps and spontaneous activity, as well as receptive field and circuit development, drawing on examples from both mammalian visual cortex and fish optic tectum. Overall we suggest that neural coding strategies during development may be highly dynamic. [ABSTRACT FROM AUTHOR]

Published

2018

274. A Hierarchy of Time Scales for Discriminating and Classifying the Temporal Shape of Sound in Three Auditory Cortical Fields.

Author

Osman, Ahmad F., Lee, Christopher M., Escabí, Monty A., and Read, Heather L.

Subjects

*AUDITORY cortex physiology, *NEURAL codes, *ELECTROPHYSIOLOGY, *SURGICAL complications, *ANIMAL models in research

Abstract

Auditory cortex is essential for mammals, including rodents, to detect temporal "shape" cues in the sound envelope but it remains unclear how different cortical fields may contribute to this ability (Lomber and Malhotra, 2008; Threlkeld et al., 2008). Previously, we found that precise spiking patterns provide a potential neural code for temporal shape cues in the sound envelope in the primary auditory (A1), and ventral auditory field (VAF) and caudal suprarhinal auditory field (cSRAF) of the rat (Lee et al., 2016). Here, we extend these findings and characterize the time course of the temporally precise output of auditory cortical neurons in male rats. A pairwise sound discrimination index and a Naive Bayesian classifier are used to determine how these spiking patterns could provide brain signals for behavioral discrimination and classification of sounds. We find response durations and optimal time constants for discriminating sound envelope shape increase in rank order with: A1 < VAF < cSRAF. Accordingly, sustained spiking is more prominent and results in more robust sound discrimination in non-primary cortex versus A1. Spike-timing patterns classify 10 different sound envelope shape sequences and there is a twofold increase in maximal performance when pooling output across the neuron population indicating a robust distributed neural code in all three cortical fields. Together, these results support the idea that temporally precise spiking patterns from primary and non-primary auditory cortical fields provide the necessary signals for animals to discriminate and classify a large range of temporal shapes in the sound envelope. [ABSTRACT FROM AUTHOR]

Published

2018

275. Supra-Threshold Hearing and Fluctuation Profiles: Implications for Sensorineural and Hidden Hearing Loss.

Author

Carney, Laurel H.

Subjects

BRAIN stem physiology, COCHLEA physiology, HEARING, HEARING levels, HAIR cells, ACOUSTIC nerve, SENSORINEURAL hearing loss, HIDDEN hearing loss, RESEARCH funding

Abstract

An important topic in contemporary auditory science is supra-threshold hearing. Difficulty hearing at conversational speech levels in background noise has long been recognized as a problem of sensorineural hearing loss, including that associated with aging (presbyacusis). Such difficulty in listeners with normal thresholds has received more attention recently, especially associated with descriptions of synaptopathy, the loss of auditory nerve (AN) fibers as a result of noise exposure or aging. Synaptopathy has been reported to cause a disproportionate loss of low- and medium-spontaneous rate (L/MSR) AN fibers. Several studies of synaptopathy have assumed that the wide dynamic ranges of L/MSR AN fiber rates are critical for coding supra-threshold sounds. First, this review will present data from the literature that argues against a direct role for average discharge rates of L/MSR AN fibers in coding sounds at moderate to high sound levels. Second, the encoding of sounds at supra-threshold levels is examined. A key assumption in many studies is that saturation of AN fiber discharge rates limits neural encoding, even though the majority of AN fibers, high-spontaneous rate (HSR) fibers, have saturated average rates at conversational sound levels. It is argued here that the cross-frequency profile of low-frequency neural fluctuation amplitudes, not average rates, encodes complex sounds. As described below, this fluctuation-profile coding mechanism benefits from both saturation of inner hair cell (IHC) transduction and average rate saturation associated with the IHC-AN synapse. Third, the role of the auditory efferent system, which receives inputs from L/MSR fibers, is revisited in the context of fluctuation-profile coding. The auditory efferent system is hypothesized to maintain and enhance neural fluctuation profiles. Lastly, central mechanisms sensitive to neural fluctuations are reviewed. Low-frequency fluctuations in AN responses are accentuated by cochlear nucleus neurons which, either directly or via other brainstem nuclei, relay fluctuation profiles to the inferior colliculus (IC). IC neurons are sensitive to the frequency and amplitude of low-frequency fluctuations and convert fluctuation profiles from the periphery into a phase-locked rate profile that is robust across a wide range of sound levels and in background noise. The descending projection from the midbrain (IC) to the efferent system completes a functional loop that, combined with inputs from the L/MSR pathway, is hypothesized to maintain "sharp" supra-threshold hearing, reminiscent of visual mechanisms that regulate optical accommodation. Examples from speech coding and detection in noise are reviewed. Implications for the effects of synaptopathy on control mechanisms hypothesized to influence supra-threshold hearing are discussed. This framework for understanding neural coding and control mechanisms for supra-threshold hearing suggests strategies for the design of novel hearing aid signal-processing and electrical stimulation patterns for cochlear implants. [ABSTRACT FROM AUTHOR]

Published

2018

276. Modern Machine Learning as a Benchmark for Fitting Neural Responses.

Author

Benjamin, Ari S., Fernandes, Hugo L., Tomlinson, Tucker, Ramkumar, Pavan, VerSteeg, Chris, Chowdhury, Raeed H., Miller, Lee E., and Kording, Konrad P.

Subjects

MACHINE learning, NEUROSCIENCES, NEURAL transmission, SOMATOSENSORY cortex, NEURONS

Abstract

Neuroscience has long focused on finding encoding models that effectively ask "what predicts neural spiking?" and generalized linear models (GLMs) are a typical approach. It is often unknown how much of explainable neural activity is captured, or missed, when fitting a model. Here we compared the predictive performance of simple models to three leading machine learning methods: feedforward neural networks, gradient boosted trees (using XGBoost), and stacked ensembles that combine the predictions of several methods. We predicted spike counts in macaque motor (M1) and somatosensory (S1) cortices from standard representations of reaching kinematics, and in rat hippocampal cells from open field location and orientation. Of these methods, XGBoost and the ensemble consistently produced more accurate spike rate predictions and were less sensitive to the preprocessing of features. These methods can thus be applied quickly to detect if feature sets relate to neural activity in a manner not captured by simpler methods. Encoding models built with a machine learning approach accurately predict spike rates and can offer meaningful benchmarks for simpler models. [ABSTRACT FROM AUTHOR]

Published

2018

277. Sparse bursts optimize information transmission in a multiplexed neural code.

Author

Naud, Richard and Sprekeler, Henning

Subjects

*BIOLOGICAL neural networks, *NEURAL transmission, *NEURAL physiology, *NEUROSCIENCES, *COMPUTER simulation

Abstract

Many cortical neurons combine the information ascending and descending the cortical hierarchy. In the classical view, this information is combined nonlinearly to give rise to a single firing-rate output, which collapses all input streams into one. We analyze the extent to which neurons can simultaneously represent multiple input streams by using a code that distinguishes spike timing patterns at the level of a neural ensemble. Using computational simulations constrained by experimental data, we show that cortical neurons are well suited to generate such multiplexing. Interestingly, this neural code maximizes information for short and sparse bursts, a regime consistent with in vivo recordings. Neurons can also demultiplex this information, using specific connectivity patterns. The anatomy of the adult mammalian cortex suggests that these connectivity patterns are used by the nervous system to maintain sparse bursting and optimal multiplexing. Contrary to firing-rate coding, our findings indicate that the physiology and anatomy of the cortex may be interpreted as optimizing the transmission of multiple independent signals to different targets. [ABSTRACT FROM AUTHOR]

Published

2018

278. Cortical Coding of Auditory Features.

Author

Wang, Xiaoqin

Subjects

*CEREBRAL cortex, *AUDITORY perception, *NEUROSCIENCES, *AUDITORY cortex, *HUMAN information processing

Abstract

How the cerebral cortex encodes auditory features of biologically important sounds, including speech and music, is one of the most important questions in auditory neuroscience. The pursuit to understand related neural coding mechanisms in the mammalian auditory cortex can be traced back several decades to the early exploration of the cerebral cortex. Significant progress in this field has been made in the past two decades with new technical and conceptual advances. This article reviews the progress and challenges in this area of research. [ABSTRACT FROM AUTHOR]

Published

2018

279. White noise analysis for the correlation-type elementary motion detectors with half-wave rectifiers.

Author

Ikeda, Hideaki and Aonishi, Toru

Subjects

*WHITE noise theory, *MOTION detectors, *KINECT (Motion sensor), *KINETIC energy, *RANDOM noise theory

Abstract

The motion detection mechanism of insects has been attracted attention of many researchers. Several motion-detection models have been proposed on the basis of insect visual system studies. Here, we examine two models, the Hassenstein–Reichardt (HR) model and the two-detector (2D) model. We analytically obtain the mean and variance of the stationary responses of the HR and the 2D models to white noise, and we derive the signal-to-fluctuation-noise ratio (SFNR) to evaluate encoding abilities of the two models. Especially when analyzing the 2D model, we calculate higher-order cumulants of a rectified Gaussian. The results show that the 2D model robustly works almost as well as the HR model in several sets of parameters estimated on the basis of experimental data. [ABSTRACT FROM AUTHOR]

Published

2018

280. Multineuron spike train analysis with R-convolution linear combination kernel.

Author

Tezuka, Taro

Subjects

*NEURONS, *MOTOR neurons, *GAUSSIAN processes, *REGRESSION analysis, *MATHEMATICAL optimization

Abstract

A spike train kernel provides an effective way of decoding information represented by a spike train. Some spike train kernels have been extended to multineuron spike trains, which are simultaneously recorded spike trains obtained from multiple neurons. However, most of these multineuron extensions were carried out in a kernel-specific manner. In this paper, a general framework is proposed for extending any single-neuron spike train kernel to multineuron spike trains, based on the R-convolution kernel. Special subclasses of the proposed R-convolution linear combination kernel are explored. These subclasses have a smaller number of parameters and make optimization tractable when the size of data is limited. The proposed kernel was evaluated using Gaussian process regression for multineuron spike trains recorded from an animal brain. It was compared with the sum kernel and the population Spikernel, which are existing ways of decoding multineuron spike trains using kernels. The results showed that the proposed approach performs better than these kernels and also other commonly used neural decoding methods. • A novel way of extending any single spike train kernel to multineuron spike trains is proposed. • Subclasses of a kernel having fewer parameters are introduced, making optimization more feasible. • Gaussian process regression with the kernel outperformed other existing decoding methods. [ABSTRACT FROM AUTHOR]

Published

2018

281. The effect of an exogenous magnetic field on neural coding in deep spiking neural networks.

Author

Lei Guo, Wei Zhang, and Jialei Zhang

Subjects

NEURAL codes, MAGNETIC fields, NEURAL circuitry, BIOLOGICAL neural networks, NEUROSCIENCES

Abstract

A ten-layer feed forward network is constructed in the presence of an exogenous alternating magnetic field. Specifically, our results indicate that for rate coding, the firing rate is significantly increased in the presence of an exogenous alternating magnetic field and particularly with increasing enhancement of the alternating magnetic field amplitude. For temporal coding, the interspike intervals of the spiking sequence are decreased and the distribution of the interspike intervals of the spiking sequence tends to be uniform in the presence of alternating magnetic field. [ABSTRACT FROM AUTHOR]

Published

2018

282. Contrast coding in the primary visual cortex depends on temporal contexts.

Author

Dai, Ji and Wang, Yi

Subjects

*VISUAL cortex, *STIMULUS & response (Psychology), *OPTICAL information processing, *ADAPTABILITY (Personality), *NEURAL stimulation, *TEMPORAL lobe

Abstract

Abstract: Contrast response function in the primary visual cortex (V1) has long been described as following a sigmoid curve. However, this is mainly based on measuring neural responses to drifting contrast grating in a stable stimulation, a model that does not consider the effects of motion or length of stimulus presentation. During natural viewing, the visual system can obtain sufficient information for identifying the shapes defined by contrast from a single glance; acquiring greater knowledge of the neuronal response properties to contrast in such a short timescale is necessary to understand the underlying mechanisms. We investigated responses of cat V1 neurons to contrast presented by static grating for 40 ms without pause compared to drifting grating presented continuously for 2000 ms. The neuronal response to transiently presented contrast could be well described by a linear function. Further examination of the effects of motion and presentation duration on contrast responses demonstrated that motion increased response sensitivity in the low‐contrast range, while brief presentation increased response sensitivity in the high‐contrast range. Motion and prolonged presentation (adaptation) together resulted in an asymptotic sigmoid curve with a saturation response in the high‐contrast range. These results suggest that motion mainly enhance the neural response sensitivity to low‐contrast objects, while short and rapid presentation mainly enhance the neural sensitivity to high‐contrast stimulus. Our findings indicate that multiple factors influence the properties of contrast response functions, suggesting that V1 neuron contrast coding is flexible and depends on the temporal contexts. [ABSTRACT FROM AUTHOR]

Published

2018

283. Neural coding of sound envelope structure in songbirds.

Author

Boari, Santiago and Amador, Ana

Subjects

*NEURAL codes, *SONGBIRDS, *ZEBRA finch, *TELENCEPHALON, *ELECTROPHYSIOLOGY, *PHYSIOLOGY

Abstract

Songbirds are a well-established animal model to study the neural basis of learning, perception and production of complex vocalizations. In this system, telencephalic neurons in HVC present a state-dependent, highly selective response to auditory presentations of the bird’s own song (BOS). This property provides an opportunity to study the neural code behind a complex motor behavior. In this work, we explore whether changes in the temporal structure of the sound envelope can drive changes in the neural responses of highly selective HVC units. We generated an envelope-modified BOS (MOD) by reversing each syllable’s envelope but leaving the overall temporal structure of syllable spectra unchanged, which resulted in a subtle modification for each song syllable. We conducted in vivo electrophysiological recordings of HVC neurons in anaesthetized zebra finches (Taeniopygia guttata). Units analyzed presented a high BOS selectivity and lower response to MOD, but preserved the profile response shape. These results show that the temporal evolution of the sound envelope is being sensed by the avian song system and suggest that the biomechanical properties of the vocal apparatus could play a role in enhancing subtle sound differences. [ABSTRACT FROM AUTHOR]

Published

2018

284. A neural model of retrospective attention in visual working memory.

Author

Bays, Paul M. and Taylor, Robert

Subjects

*VISUAL memory, *SHORT-term memory, *ARTIFICIAL neural networks, *NUMERICAL analysis, *MATHEMATICAL models

Abstract

An informative cue that directs attention to one of several items in working memory improves subsequent recall of that item. Here we examine the mechanism of this retro-cue effect using a model of short-term memory based on neural population coding. Our model describes recalled feature values as the output of an optimal decoding of spikes generated by a tuned population of neurons. This neural model provides a better account of human recall data than an influential model that assumes errors can be described as a mixture of normally distributed noise and random guesses. The retro-cue benefit is revealed to be consistent with a higher firing rate of the population encoding the cued versus uncued items, with no difference in tuning specificity. Additionally, a retro-cued item is less likely to be swapped with another item in memory, an effect that can also be explained by greater activity of the underlying population. These results provide a parsimonious account of the effects of retrospective attention on recall and demonstrate a principled method for investigating neural representations with behavioral tasks. [ABSTRACT FROM AUTHOR]

Published

2018

285. Mutual Information and Information Gating in Synfire Chains.

Author

Xiao, Zhuocheng, Wang, Binxu, Sornborger, Andrew T., and Tao, Louis

Subjects

*KNOWLEDGE transfer, *INFORMATION processing, *COGNITIVE ability, *CHANNEL capacity (Telecommunications), *MEMBRANE potential

Abstract

Coherent neuronal activity is believed to underlie the transfer and processing of information in the brain. Coherent activity in the form of synchronous firing and oscillations has been measured in many brain regions and has been correlated with enhanced feature processing and other sensory and cognitive functions. In the theoretical context, synfire chains and the transfer of transient activity packets in feedforward networks have been appealed to in order to describe coherent spiking and information transfer. Recently, it has been demonstrated that the classical synfire chain architecture, with the addition of suitably timed gating currents, can support the graded transfer of mean firing rates in feedforward networks (called synfire-gated synfire chains--SGSCs). Here we study information propagation in SGSCs by examining mutual information as a function of layer number in a feedforward network. We explore the effects of gating and noise on information transfer in synfire chains and demonstrate that asymptotically, two main regions exist in parameter space where information may be propagated and its propagation is controlled by pulse-gating: a large region where binary codes may be propagated, and a smaller region near a cusp in parameter space that supports graded propagation across many layers. [ABSTRACT FROM AUTHOR]

Published

2018

286. What the whiskers tell the brain.

Author

Campagner, Dario, Evans, Mathew H., Loft, Michaela S.E., and Petersen, Rasmus S.

Subjects

*SENSORY stimulation, *ELECTROPHYSIOLOGY, *NEURAL circuitry, *SOMATOSENSORY cortex, *AFFERENT pathways

Abstract

A fundamental question in the investigation of any sensory system is what physical signals drive its sensory neurons during natural behavior. Surprisingly, in the whisker system, it is only recently that answers to this question have emerged. Here, we review the key developments, focussing mainly on the first stage of the ascending pathway – the primary whisker afferents (PWAs). We first consider a biomechanical framework, which describes the fundamental mechanical forces acting on the whiskers during active sensation. We then discuss technical progress that has allowed such mechanical variables to be estimated in awake, behaving animals. We discuss past electrophysiological evidence concerning how PWAs function and reinterpret it within the biomechanical framework. Finally, we consider recent studies of PWAs in awake, behaving animals and compare the results to related studies of the cortex. We argue that understanding ‘what the whiskers tell the brain’ sheds valuable light on the computational functions of downstream neural circuits, in particular, the barrel cortex. [ABSTRACT FROM AUTHOR]

Published

2018

287. Organization of orientation-specific whisker deflection responses in layer 2/3 of mouse somatosensory cortex.

Author

Kwon, Sung Eun, Tsytsarev, Vassiliy, Erzurumlu, Reha S., and O'Connor, Daniel H.

Subjects

*SOMATOSENSORY cortex, *STIMULUS & response (Biology), *PERCEPTUAL learning, *SPATIAL orientation, *WHISKERS

Abstract

The rodent whisker-barrel system is characterized by its patterned somatotopic mapping between the sensory periphery and multiple regions of the brain. While somatotopy in the whisker system is established, we know far less about how preferences for stimulus orientation or other features are organized. Mouse somatosensation is an increasingly popular model for circuit-based dissection of perceptual decision making and learning, yet our understanding of how stimulus feature representations are organized in the cortex is incomplete. Here, we used in vivo two-photon calcium imaging to monitor activity of populations of layer (L) 2/3 neurons in the mouse primary somatosensory cortex during deflections of a single whisker in two orthogonal orientations (azimuthal or elevational). We split the population response to whisker deflections into an orientation-specific component and a non-specific component that reflected overall excitability in response to deflection of a single whisker. Orientation-specific responses were organized in a locally heterogeneous and spatially distributed manner. Correlations in the stimulus-independent trial-to-trial variability of pairs of neurons were higher among neurons that preferred the same orientation. These correlations depended on similarity in both orientation-specific and non-specific components of responses to single-whisker deflections. Our results shed light on L2/3 organization in mouse somatosensory cortex, and lay a foundation for dissecting circuit mechanisms of perceptual learning and decision-making during orientation discrimination tasks. [ABSTRACT FROM AUTHOR]

Published

2018

288. Information processing across behavioral states: Modes of operation and population dynamics in rodent sensory cortex.

Author

Sabri, Mohammad Mahdi and Arabzadeh, Ehsan

Subjects

*SOMATOSENSORY cortex, *POPULATION dynamics, *INFORMATION processing, *NEURAL circuitry, *BEHAVIORAL neuroscience

Abstract

Animals live in a complex and changing environment with various degrees of behavioral demands. In rodents, the behavioral states can change from sleep and quiet wakefulness to active exploration of the environment which is often manifested by whisking and locomotion. Efficient information processing is more important in some of these behavioral states such as during episodes of sensory decision-making, and specific cortical areas are expected to receive priority of processing depending on the behavioral context. It is therefore not surprising that the behavioral state affects the responsiveness of individual cortical neurons and the dynamics of neuronal population activity. Here, we review the circuit mechanisms that determine the operating mode of the sensory cortex. We explore state modulations across multiple sensory modalities, but maintain a focus on whisker-mediated behaviors, the processing of information in the vibrissal somatosensory cortex and its transfer to higher order areas. Finally, we suggest a rodent sensory prioritization paradigm to further probe the link between behavioral state, neuronal population dynamics and coding efficiency. [ABSTRACT FROM AUTHOR]

Published

2018

289. Representation of tactile scenes in the rodent barrel cortex.

Author

Estebanez, Luc, Férézou, Isabelle, Ego-Stengel, Valérie, and Shulz, Daniel E.

Subjects

*TACTILE sensors, *STIMULUS & response (Biology), *VISUAL cortex, *SENSORIMOTOR integration, *WHISKERS

Abstract

After half a century of research, the sensory features coded by neurons of the rodent barrel cortex remain poorly understood. Still, views of the sensory representation of whisker information are increasingly shifting from a labeled line representation of single-whisker deflections to a selectivity for specific elements of the complex statistics of the multi-whisker deflection patterns that take place during spontaneous rodent behavior – so called natural tactile scenes. Here we review the current knowledge regarding the coding of patterns of whisker stimuli by barrel cortex neurons, from responses to single-whisker deflections to the representation of complex tactile scenes. A number of multi-whisker tunings have already been identified, including center-surround feature extraction, angular tuning during edge-like multi-whisker deflections, and even tuning to specific statistical properties of the tactile scene such as the level of correlation across whiskers. However, a more general model of the representation of multi-whisker information in the barrel cortex is still missing. This is in part because of the lack of a human intuition regarding the perception emerging from a whisker system, but also because in contrast to other primary sensory cortices such as the visual cortex, the spatial feature selectivity of barrel cortex neurons rests on highly nonlinear interactions that remained hidden to classical receptive field approaches. [ABSTRACT FROM AUTHOR]

Published

2018

290. Toward a unified theory of efficient, predictive, and sparse coding.

Author

Chalk, Matthew, Marre, Olivier, and Tkačik, Gašper

Subjects

*NEURAL codes, *INFORMATION theory, *SENSORY neurons, *NEUROSCIENCES, *RANDOM noise theory, *DECODING algorithms, *SIGNAL-to-noise ratio

Abstract

A central goal in theoretical neuroscience is to predict the response properties of sensory neurons from first principles. To this end, "efficient coding" posits that sensory neurons encode maximal information about their inputs given internal constraints. There exist, however, many variants of efficient coding (e.g., redundancy reduction, different formulations of predictive coding, robust coding, sparse coding, etc.), differing in their regimes of applicability, in the relevance of signals to be encoded, and in the choice of constraints. It is unclear how these types of efficient coding relate or what is expected when different coding objectives are combined. Here we present a unified framework that encompasses previously proposed efficient coding models and extends to unique regimes. We show that optimizing neural responses to encode predictive information can lead them to either correlate or decorrelate their inputs, depending on the stimulus statistics; in contrast, at low noise, efficiently encoding the past always predicts decorrelation. Later, we investigate coding of naturalistic movies and show that qualitatively different types of visual motion tuning and levels of response sparsity are predicted, depending on whether the objective is to recover the past or predict the future. Our approach promises a way to explain the observed diversity of sensory neural responses, as due to multiple functional goals and constraints fulfilled by different cell types and/or circuits. [ABSTRACT FROM AUTHOR]

Published

2018

291. The Precision of Neuronal Coding in the Auditory Brainstem and Implications for Cochlear Implants

Author

Wang, H., Holmberg, M., Hemmert, W., Magjarevic, Ratko, editor, Dössel, Olaf, editor, and Schlegel, Wolfgang C., editor

Published

2009

292. Methodological considerations for a chronic neural interface with the cuneate nucleus of macaques.

Author

Suresh, Aneesha K., Winberry, Jeremy E., Versteeg, Christopher, Chowdhury, Raeed, Tomlinson, Tucker, Rosenow, Joshua M., Miller, Lee E., and Bensmaia, Sliman J.

Abstract

While the response properties of neurons in the somatosensory nerves and anterior parietal cortex have been extensively studied, little is known about the encoding of tactile and proprioceptive information in the cuneate nucleus (CN) or external cuneate nucleus (ECN), the first recipients of upper limb somatosensory afferent signals. The major challenge in characterizing neural coding in CN/ECN has been to record from these tiny, difficult-to-access brain stem structures. Most previous investigations of CN response properties have been carried out in decerebrate or anesthetized animals, thereby eliminating the well-documented top-down signals from cortex, which likely exert a strong influence on CN responses. Seeking to fill this gap in our understanding of somatosensory processing, we describe an approach to chronically implanting arrays of electrodes in the upper limb representation in the brain stem in primates. First, we describe the topography of CN/ECN in rhesus macaques, including its somatotopic organization and the layout of its submodalities (touch and proprioception). Second, we describe the design of electrode arrays and the implantation strategy to obtain stable recordings. Third, we show sample responses of CN/ECN neurons in brain stem obtained from awake, behaving monkeys. With this method, we are in a position to characterize, for the first time, somatosensory representations in CN and ECN of primates. NEW & NOTEWORTHY In primates, the neural basis of touch and of our sense of limb posture and movements has been studied in the peripheral nerves and in somatosensory cortex, but coding in the cuneate and external cuneate nuclei, the first processing stage for these signals in the central nervous system, remains an enigma. We have developed a method to record from these nuclei, thereby paving the way to studying how sensory information from the limb is encoded there. [ABSTRACT FROM AUTHOR]

Published

2017

293. Measures of Neural Similarity

Author

Bobadilla-Suarez, S., Ahlheim, C., Mehrotra, A., Panos, A., and Love, B. C.

Published

2020

294. Sparse coding and improved dark channel prior-based deep CNN model for enhancing visibility of foggy images

Author

R. Suganya and R. Kanagavalli

Subjects

Channel (digital image), Pixel, Computer Networks and Communications, business.industry, Computer science, Applied Mathematics, Mean opinion score, Visibility (geometry), ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Overfitting, Computer Science Applications, Wavelet, Computational Theory and Mathematics, Artificial Intelligence, Pattern recognition (psychology), Computer vision, Artificial intelligence, Electrical and Electronic Engineering, business, Neural coding, Information Systems

Abstract

The images captured in an outdoor environment have the possibility of being degraded in the presence of air particles that scatters and absorbs light. This degradation of images introduces pixel distortion, blurring, contrast attenuation that results in poor visibility. The foggy images also restrict the efficiency associated with the computer vision systems that concentrates on pattern recognition, surveillance and target tracking. In this paper, sparse coding and improved dark channel prior-based deep CNN (SP-IDCP-DCNN) model is proposed for enhancing the visibility of foggy Images that attributes towards efficiency improvement of computer vision systems. In specific, sparse coding is inherited with the merits of regularization and dropout layer for minimizing the overfitting problem achieved based on dimension reduction. This sparse coding is used for generating ridgelet-based components through the utilization of Ricker Wavelet functions. It included an adaptive modification process in the dark channel prior computer for significantly minimizing the need of generating artifacts involved in the process of restoring the image’s visibility. The sparse coding is also responsible for potentially extracting sparse-coded features that attributes towards image visibility enhancement. The simulation results of the proposed SP-IDCP-DCNN Model confirmed its predominance over the existing CNN-based image visibility enhancement schemes in terms of mean opinion score and fog reduction factor.

Published

2021

295. Convolutional Sparse Coding Using Pathfinder Algorithm-Optimized Orthogonal Matching Pursuit With Asymmetric Gaussian Chirplet Model in Bearing Fault Detection

Author

Cai Yi, Liu He, Qiwei Hu, Yuhui Zhang, Qiuyang Zhou, and Jianhui Lin

Subjects

Computer science, Convolutional code, Wavelet transform, Waveform, Sparse approximation, Electrical and Electronic Engineering, Fault (power engineering), Neural coding, Instrumentation, Matching pursuit, Algorithm, Convolution

Abstract

Sparse representation has been widely used in bearing fault impact detection, which can find the impact that best matches the fault waveform from the pre-defined dictionary and recover the fault impulse waveform. However, the current dictionary of sparse representation and the efficiency of sparse representation algorithm need to be improved. In order to accurately detect the fault impulse in the original signal, a convolutional sparse coding using pathfinder algorithm-optimized orthogonal matching pursuit with asymmetric Gaussian chirplet model (CSC-OAGCM) is proposed in this paper. A new time-frequency atom prototype, AGCM, is used to match the fault impulse waveform. The specific application steps of the proposed algorithm are as follows: Firstly, a convolution dictionary is constructed with atoms generated by AGCM. Subsequently, based on the convolution dictionary, a pathfinder algorithm-optimized orthogonal matching pursuit algorithm is used to solve the sparse representation and optimize the atomic parameters to achieve the best approximation of the original signal. In other words, the proposed method detects the convolutional sparse patterns in the signal. A simulation signal, two sets of mixed signals of experimental data collected from the experimental platform and an axle box vibration signal collected from the actual operating train are used to verify the effectiveness of proposed method. Additionally, the spectral kurtosis and empirical wavelet transform are also used to process these signals, and their processing results are compared with those obtained by the proposed method to demonstrate the superiority of the proposed method.

Published

2021

296. LPNN‐based approach for LASSO problem via a sequence of regularized minimizations

Author

HoumiaAnouar, AlouiRadhouane, ZeglaouiAnis, and MejaiMaher

Subjects

Lyapunov stability, Sequence, Computer science, Statistics::Computation, Constraint (information theory), Compressed sensing, Lasso (statistics), Control and Systems Engineering, Signal Processing, Convergence (routing), Statistics::Methodology, Electrical and Electronic Engineering, Neural coding, Selection operator, Algorithm

Abstract

Summary In compressive sampling theory, the least absolute shrinkage and selection operator (LASSO) is a representative problem. Nevertheless, the non‐differentiable constraint impedes the use of L...

Published

2021

297. How environmental movement constraints shape the neural code for space

Author

Kate J. Jeffery

Subjects

Computer science, Cognitive Neuroscience, Place cell, Experimental and Cognitive Psychology, Space (commercial competition), Key Note Paper, Hippocampus, Place cells, 03 medical and health sciences, Motion, 0302 clinical medicine, Spatial memory, Cognition, Artificial Intelligence, Human–computer interaction, Code (cryptography), Animals, Humans, 030304 developmental biology, Neurons, 0303 health sciences, Representation (systemics), General Medicine, Spatial cognition, Construct (python library), Navigation, Affordance, Neural encoding, Space Perception, Mental representation, Grid cells, Neural coding, 030217 neurology & neurosurgery

Abstract

Study of the neural code for space in rodents has many insights to offer for how mammals, including humans, construct a mental representation of space. This code is centered on the hippocampal place cells, which are active in particular places in the environment. Place cells are informed by numerous other spatial cell types including grid cells, which provide a signal for distance and direction and are thought to help anchor the place cell signal. These neurons combine self-motion and environmental information to create and update their map-like representation. Study of their activity patterns in complex environments of varying structure has revealed that this "cognitive map" of space is not a fixed and rigid entity that permeates space, but rather is variably affected by the movement constraints of the environment. These findings are pointing toward a more flexible spatial code in which the map is adapted to the movement possibilities of the space. An as-yet-unanswered question is whether these different forms of representation have functional consequences, as suggested by an enactivist view of spatial cognition.

Published

2021

298. Asynchronous and Non-Stationary Interference Cancellation in Multiuser Interference Channels

Author

Zhitao Huang, Xin Cai, and Baoguo Li

Subjects

business.industry, Computer science, Applied Mathematics, Signal, Computer Science Applications, Single antenna interference cancellation, Interference (communication), Asynchronous communication, Encoding (memory), Wireless, Electrical and Electronic Engineering, business, Neural coding, Environmental noise, Algorithm

Abstract

A single antenna interference cancellation (SAIC) scheme is proposed. The scheme is motivated by the challenging asynchronous and non-stationary interference cancellation problem in wireless communications. Suppose the existence of the single-user region (SUR) of the desired signal, we propose to first recognize the SUR via a novel detection scheme. The SUR detection scheme proposed consists of the pseudo-observation matrix construction and the information theoretic criterion-based source number estimation. A basis set for the desired signal is then learnt over the SUR, via dictionary learning techniques. In the final signal recovery stage, a novel constrained sparse coding (CSC) process is proposed. The CSC reforms the conventional sparse coding (SC) via incorporating signal-specific constraints. Unlike existing SAIC algorithms, the proposed scheme is completely independent of a prior knowledge on the interferences. Numerical results are provided to demonstrate the effectiveness of the above proposed schemes under varied interference intensities and environmental noise levels. The proposed scheme outperformed competing SAIC schemes by about 5dB signal-to-interference-plus-noise ratio (SINR) improvement. The proposed CSC scheme outperformed the conventional SC by about 9dB SINR improvement, besides the superior recovery fidelity of signal property.

Published

2021

299. Neural burst codes disguised as rate codes

Author

Richard Naud, Albert Gidon, Alexandre Payeur, and Ezekiel Williams

Subjects

Information transfer, Computer science, Science, Information theory, Article, 03 medical and health sciences, 0302 clinical medicine, Feature (machine learning), Neural decoding, 030304 developmental biology, 0303 health sciences, Multidisciplinary, business.industry, Computational science, Pattern recognition, Applied mathematics, Degree (music), Neural encoding, Burstiness, Medicine, Spike (software development), Artificial intelligence, business, Neural coding, 030217 neurology & neurosurgery, Coding (social sciences)

Abstract

The burst coding hypothesis posits that the occurrence of sudden high-frequency patterns of action potentials constitutes a salient syllable of the neural code. Many neurons, however, do not produce clearly demarcated bursts, an observation invoked to rule out the pervasiveness of this coding scheme across brain areas and cell types. Here we ask how detrimental ambiguous spike patterns, those that are neither clearly bursts nor isolated spikes, are for neuronal information transfer. We addressed this question using information theory and computational simulations. By quantifying how information transmission depends on firing statistics, we found that the information transmitted is not strongly influenced by the presence of clearly demarcated modes in the interspike interval distribution, a feature often used to identify the presence of burst coding. Instead, we found that neurons having unimodal interval distributions were still able to ascribe different meanings to bursts and isolated spikes. In this regime, information transmission depends on dynamical properties of the synapses as well as the length and relative frequency of bursts. Furthermore, we found that common metrics used to quantify burstiness were unable to predict the degree with which bursts could be used to carry information. Our results provide guiding principles for the implementation of coding strategies based on spike-timing patterns, and show that even unimodal firing statistics can be consistent with a bivariate neural code.

Published

2021

300. Fast Dictionary Learning for High-Dimensional Seismic Reconstruction

Author

Quan Zhang, Yangkang Chen, Xingye Liu, Hang Wang, Wei Chen, and Shaohuan Zu

Subjects

Matrix (mathematics), Computer science, Event (computing), Encoding (memory), Singular value decomposition, Process (computing), General Earth and Planetary Sciences, Iterative reconstruction, Electrical and Electronic Engineering, Neural coding, Algorithm, Sparse matrix

Abstract

A sparse dictionary is more adaptive than a sparse fixed-basis transform since it can learn the features directly from the input data in a data-driven way. However, learning a sparse dictionary is time-consuming because a large number of iterations are required in order to obtain the dictionary atoms that best represent the features of input data. The computational cost becomes unaffordable when it comes to high-dimensional problems, e.g., 3-D or even 5-D applications. We propose an efficient high-dimensional dictionary learning (DL) method by avoiding the singular value decomposition (SVD) calculation in each dictionary update step that is required by the classic $K$ -singular value decomposition (KSVD) algorithm. Besides, due to the special structure of the sparse coefficient matrix, it requires a much less expensive sparse coding process. The overall computational efficiency of the new DL method is much higher, while the results are still comparable or event better than those from the traditional KSVD method. We apply the proposed method to both 3-D and 5-D seismic data reconstructions and demonstrate successful and efficient performance.

Published

2021