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30 results on '"Skatchkovsky, Nicolas"'

1. Energy-Efficient On-Board Radio Resource Management for Satellite Communications via Neuromorphic Computing

Author

Ortiz, Flor, Skatchkovsky, Nicolas, Lagunas, Eva, Martins, Wallace A., Eappen, Geoffrey, Daoud, Saed, Simeone, Osvaldo, Rajendran, Bipin, and Chatzinotas, Symeon

Subjects
Electrical Engineering and Systems Science - Systems and Control, Computer Science - Machine Learning
Abstract

The latest satellite communication (SatCom) missions are characterized by a fully reconfigurable on-board software-defined payload, capable of adapting radio resources to the temporal and spatial variations of the system traffic. As pure optimization-based solutions have shown to be computationally tedious and to lack flexibility, machine learning (ML)-based methods have emerged as promising alternatives. We investigate the application of energy-efficient brain-inspired ML models for on-board radio resource management. Apart from software simulation, we report extensive experimental results leveraging the recently released Intel Loihi 2 chip. To benchmark the performance of the proposed model, we implement conventional convolutional neural networks (CNN) on a Xilinx Versal VCK5000, and provide a detailed comparison of accuracy, precision, recall, and energy efficiency for different traffic demands. Most notably, for relevant workloads, spiking neural networks (SNNs) implemented on Loihi 2 yield higher accuracy, while reducing power consumption by more than 100$\times$ as compared to the CNN-based reference platform. Our findings point to the significant potential of neuromorphic computing and SNNs in supporting on-board SatCom operations, paving the way for enhanced efficiency and sustainability in future SatCom systems., Comment: currently under review at IEEE Transactions on Machine Learning in Communications and Networking

Published
2023

2. Bayesian Inference on Binary Spiking Networks Leveraging Nanoscale Device Stochasticity

Author

Katti, Prabodh, Skatchkovsky, Nicolas, Simeone, Osvaldo, Rajendran, Bipin, and Al-Hashimi, Bashir M.

Subjects
Computer Science - Neural and Evolutionary Computing, Computer Science - Hardware Architecture, Computer Science - Emerging Technologies, Computer Science - Machine Learning
Abstract

Bayesian Neural Networks (BNNs) can overcome the problem of overconfidence that plagues traditional frequentist deep neural networks, and are hence considered to be a key enabler for reliable AI systems. However, conventional hardware realizations of BNNs are resource intensive, requiring the implementation of random number generators for synaptic sampling. Owing to their inherent stochasticity during programming and read operations, nanoscale memristive devices can be directly leveraged for sampling, without the need for additional hardware resources. In this paper, we introduce a novel Phase Change Memory (PCM)-based hardware implementation for BNNs with binary synapses. The proposed architecture consists of separate weight and noise planes, in which PCM cells are configured and operated to represent the nominal values of weights and to generate the required noise for sampling, respectively. Using experimentally observed PCM noise characteristics, for the exemplary Breast Cancer Dataset classification problem, we obtain hardware accuracy and expected calibration error matching that of an 8-bit fixed-point (FxP8) implementation, with projected savings of over 9$\times$ in terms of core area transistor count., Comment: Submitted and Accepted in ISCAS 2023

Published
2023
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3. Neuromorphic Integrated Sensing and Communications

Author

Chen, Jiechen, Skatchkovsky, Nicolas, and Simeone, Osvaldo

Subjects
Electrical Engineering and Systems Science - Signal Processing, Computer Science - Neural and Evolutionary Computing
Abstract

Neuromorphic computing is an emerging technology that support event-driven data processing for applications requiring efficient online inference and/or control. Recent work has introduced the concept of neuromorphic communications, whereby neuromorphic computing is integrated with impulse radio (IR) transmission to implement low-energy and low-latency remote inference in wireless Internet-of-Things (IoT) networks. In this paper, we introduce neuromorphic integrated sensing and communications (N-ISAC), a novel solution that enables efficient online data decoding and radar sensing. N-ISAC leverages a common IR waveform for the dual purpose of conveying digital information and of detecting the presence or absence of a radar target. A spiking neural network (SNN) is deployed at the receiver to decode digital data and to detect the radar target using directly the received signal. The SNN operation is optimized by balancing performance metrics for data communications and radar sensing, highlighting synergies and trade-offs between the two applications., Comment: Published on IEEE Wireless Communications Letters

Published
2022

4. Bayesian Continual Learning via Spiking Neural Networks

Author

Skatchkovsky, Nicolas, Jang, Hyeryung, and Simeone, Osvaldo

Subjects
Computer Science - Neural and Evolutionary Computing, Computer Science - Artificial Intelligence, Computer Science - Machine Learning
Abstract

Among the main features of biological intelligence are energy efficiency, capacity for continual adaptation, and risk management via uncertainty quantification. Neuromorphic engineering has been thus far mostly driven by the goal of implementing energy-efficient machines that take inspiration from the time-based computing paradigm of biological brains. In this paper, we take steps towards the design of neuromorphic systems that are capable of adaptation to changing learning tasks, while producing well-calibrated uncertainty quantification estimates. To this end, we derive online learning rules for spiking neural networks (SNNs) within a Bayesian continual learning framework. In it, each synaptic weight is represented by parameters that quantify the current epistemic uncertainty resulting from prior knowledge and observed data. The proposed online rules update the distribution parameters in a streaming fashion as data are observed. We instantiate the proposed approach for both real-valued and binary synaptic weights. Experimental results using Intel's Lava platform show the merits of Bayesian over frequentist learning in terms of capacity for adaptation and uncertainty quantification., Comment: Accepted for publication in Frontiers in Computational Neuroscience

Published
2022

5. Neuromorphic Wireless Cognition: Event-Driven Semantic Communications for Remote Inference

Author

Chen, Jiechen, Skatchkovsky, Nicolas, and Simeone, Osvaldo

Subjects
Computer Science - Information Theory, Computer Science - Machine Learning, Computer Science - Neural and Evolutionary Computing
Abstract

Neuromorphic computing is an emerging computing paradigm that moves away from batched processing towards the online, event-driven, processing of streaming data. Neuromorphic chips, when coupled with spike-based sensors, can inherently adapt to the "semantics" of the data distribution by consuming energy only when relevant events are recorded in the timing of spikes and by proving a low-latency response to changing conditions in the environment. This paper proposes an end-to-end design for a neuromorphic wireless Internet-of-Things system that integrates spike-based sensing, processing, and communication. In the proposed NeuroComm system, each sensing device is equipped with a neuromorphic sensor, a spiking neural network (SNN), and an impulse radio transmitter with multiple antennas. Transmission takes place over a shared fading channel to a receiver equipped with a multi-antenna impulse radio receiver and with an SNN. In order to enable adaptation of the receiver to the fading channel conditions, we introduce a hypernetwork to control the weights of the decoding SNN using pilots. Pilots, encoding SNNs, decoding SNN, and hypernetwork are jointly trained across multiple channel realizations. The proposed system is shown to significantly improve over conventional frame-based digital solutions, as well as over alternative non-adaptive training methods, in terms of time-to-accuracy and energy consumption metrics., Comment: Published on IEEE Transactions on Cognitive Communications and Networking

Published
2022

6. Communication-efficient and neuromorphic edge intelligence

Author

Skatchkovsky, Nicolas, Simeone, Osvaldo, and Nakhai, Mohammad Reza

Abstract

Two technologies are predicted to enable the third industrial revolution in this beginning of the 21st century: evolutions of mobile communication networks, and artificial intelligence (AI). As 5G is being deployed commercially, and 6G is being investigated by researchers, making full use of the possibilities offered by recent network technologies remains an open challenge. With an unprecedented number of devices connected to one another, new methods are required to design communication systems. On the other hand, AI and its variants (including 'machine learning' - ML, and 'deep learning') have made tremendous progress in recent years, leading the advances in fields ranging from image recognition to natural language processing. Two research directions naturally arise from the connections between those fields, that is, to use communications for machine learning, and to use machine learning to improve communication systems. The former stems from considering that the main training paradigm for ML models still involves performing computations at a single location, with centrally localized data, using supercomputers equipped with sometimes thousands of GPUs. This is problematic in practical situations where data is distributed over many battery-powered devices, with issues both in terms of privacy and efficiency: communication networks are therefore key enablers to deploy distributed machine learning models. We first investigate this aspect by devising an offloading strategy to train machine learning models at the network edge. We then devise a collaborative learning algorithm for highly energy-efficient machine learning models, and show advantages in terms of communication load. On the other hand, AI now appears as a promising alternative to improve communication systems which have so far mostly relied on handcrafted algorithms and approximations of wireless channels dynamics. We demonstrate this by deriving an end-to-end communication system where source and channel coding are jointly learned. Furthermore, both mobile communications and machine learning are ever more energy intensive, creating novel challenges that we aim to tackle by leveraging energy-efficient methods inspired by the workings of biological brains. Using these, we design highly efficient edge AI applications with on-device training, with practical applications in real-world situations.

Published
2022

7. Learning to Time-Decode in Spiking Neural Networks Through the Information Bottleneck

Author

Skatchkovsky, Nicolas, Simeone, Osvaldo, and Jang, Hyeryung

Subjects
Computer Science - Neural and Evolutionary Computing, Computer Science - Artificial Intelligence, Computer Science - Information Theory
Abstract

One of the key challenges in training Spiking Neural Networks (SNNs) is that target outputs typically come in the form of natural signals, such as labels for classification or images for generative models, and need to be encoded into spikes. This is done by handcrafting target spiking signals, which in turn implicitly fixes the mechanisms used to decode spikes into natural signals, e.g., rate decoding. The arbitrary choice of target signals and decoding rule generally impairs the capacity of the SNN to encode and process information in the timing of spikes. To address this problem, this work introduces a hybrid variational autoencoder architecture, consisting of an encoding SNN and a decoding Artificial Neural Network (ANN). The role of the decoding ANN is to learn how to best convert the spiking signals output by the SNN into the target natural signal. A novel end-to-end learning rule is introduced that optimizes a directed information bottleneck training criterion via surrogate gradients. We demonstrate the applicability of the technique in an experimental settings on various tasks, including real-life datasets., Comment: Accepted at NeuRIPS 2021

Published
2021

8. BiSNN: Training Spiking Neural Networks with Binary Weights via Bayesian Learning

Author

Jang, Hyeryung, Skatchkovsky, Nicolas, and Simeone, Osvaldo

Subjects
Computer Science - Machine Learning, Computer Science - Neural and Evolutionary Computing, Electrical Engineering and Systems Science - Signal Processing
Abstract

Artificial Neural Network (ANN)-based inference on battery-powered devices can be made more energy-efficient by restricting the synaptic weights to be binary, hence eliminating the need to perform multiplications. An alternative, emerging, approach relies on the use of Spiking Neural Networks (SNNs), biologically inspired, dynamic, event-driven models that enhance energy efficiency via the use of binary, sparse, activations. In this paper, an SNN model is introduced that combines the benefits of temporally sparse binary activations and of binary weights. Two learning rules are derived, the first based on the combination of straight-through and surrogate gradient techniques, and the second based on a Bayesian paradigm. Experiments validate the performance loss with respect to full-precision implementations, and demonstrate the advantage of the Bayesian paradigm in terms of accuracy and calibration., Comment: Submitted

Published
2020

9. Spiking Neural Networks -- Part II: Detecting Spatio-Temporal Patterns

Author

Skatchkovsky, Nicolas, Jang, Hyeryung, and Simeone, Osvaldo

Subjects
Computer Science - Neural and Evolutionary Computing, Computer Science - Machine Learning, Electrical Engineering and Systems Science - Signal Processing
Abstract

Inspired by the operation of biological brains, Spiking Neural Networks (SNNs) have the unique ability to detect information encoded in spatio-temporal patterns of spiking signals. Examples of data types requiring spatio-temporal processing include logs of time stamps, e.g., of tweets, and outputs of neural prostheses and neuromorphic sensors. In this paper, the second of a series of three review papers on SNNs, we first review models and training algorithms for the dominant approach that considers SNNs as a Recurrent Neural Network (RNN) and adapt learning rules based on backpropagation through time to the requirements of SNNs. In order to tackle the non-differentiability of the spiking mechanism, state-of-the-art solutions use surrogate gradients that approximate the threshold activation function with a differentiable function. Then, we describe an alternative approach that relies on probabilistic models for spiking neurons, allowing the derivation of local learning rules via stochastic estimates of the gradient. Finally, experiments are provided for neuromorphic data sets, yielding insights on accuracy and convergence under different SNN models., Comment: The first two authors have equally contributed to this work. This version corrects some errors in the published paper

Published
2020

10. Spiking Neural Networks -- Part I: Detecting Spatial Patterns

Author

Jang, Hyeryung, Skatchkovsky, Nicolas, and Simeone, Osvaldo

Subjects
Computer Science - Neural and Evolutionary Computing, Computer Science - Machine Learning, Electrical Engineering and Systems Science - Signal Processing
Abstract

Spiking Neural Networks (SNNs) are biologically inspired machine learning models that build on dynamic neuronal models processing binary and sparse spiking signals in an event-driven, online, fashion. SNNs can be implemented on neuromorphic computing platforms that are emerging as energy-efficient co-processors for learning and inference. This is the first of a series of three papers that introduce SNNs to an audience of engineers by focusing on models, algorithms, and applications. In this first paper, we first cover neural models used for conventional Artificial Neural Networks (ANNs) and SNNs. Then, we review learning algorithms and applications for SNNs that aim at mimicking the functionality of ANNs by detecting or generating spatial patterns in rate-encoded spiking signals. We specifically discuss ANN-to-SNN conversion and neural sampling. Finally, we validate the capabilities of SNNs for detecting and generating spatial patterns through experiments., Comment: Submitted

Published
2020

11. Spiking Neural Networks -- Part III: Neuromorphic Communications

Author

Skatchkovsky, Nicolas, Jang, Hyeryung, and Simeone, Osvaldo

Subjects
Computer Science - Neural and Evolutionary Computing, Computer Science - Machine Learning, Electrical Engineering and Systems Science - Signal Processing
Abstract

Synergies between wireless communications and artificial intelligence are increasingly motivating research at the intersection of the two fields. On the one hand, the presence of more and more wirelessly connected devices, each with its own data, is driving efforts to export advances in machine learning (ML) from high performance computing facilities, where information is stored and processed in a single location, to distributed, privacy-minded, processing at the end user. On the other hand, ML can address algorithm and model deficits in the optimization of communication protocols. However, implementing ML models for learning and inference on battery-powered devices that are connected via bandwidth-constrained channels remains challenging. This paper explores two ways in which Spiking Neural Networks (SNNs) can help address these open problems. First, we discuss federated learning for the distributed training of SNNs, and then describe the integration of neuromorphic sensing, SNNs, and impulse radio technologies for low-power remote inference., Comment: Submitted

Published
2020

12. End-to-End Learning of Neuromorphic Wireless Systems for Low-Power Edge Artificial Intelligence

Author

Skatchkovsky, Nicolas, Jang, Hyeryung, and Simeone, Osvaldo

Subjects
Computer Science - Neural and Evolutionary Computing, Computer Science - Information Theory, Computer Science - Machine Learning, Electrical Engineering and Systems Science - Signal Processing
Abstract

This paper introduces a novel "all-spike" low-power solution for remote wireless inference that is based on neuromorphic sensing, Impulse Radio (IR), and Spiking Neural Networks (SNNs). In the proposed system, event-driven neuromorphic sensors produce asynchronous time-encoded data streams that are encoded by an SNN, whose output spiking signals are pulse modulated via IR and transmitted over general frequence-selective channels; while the receiver's inputs are obtained via hard detection of the received signals and fed to an SNN for classification. We introduce an end-to-end training procedure that treats the cascade of encoder, channel, and decoder as a probabilistic SNN-based autoencoder that implements Joint Source-Channel Coding (JSCC). The proposed system, termed NeuroJSCC, is compared to conventional synchronous frame-based and uncoded transmissions in terms of latency and accuracy. The experiments confirm that the proposed end-to-end neuromorphic edge architecture provides a promising framework for efficient and low-latency remote sensing, communication, and inference., Comment: To be presented at Asilomar 2020

Published
2020

13. VOWEL: A Local Online Learning Rule for Recurrent Networks of Probabilistic Spiking Winner-Take-All Circuits

Author

Jang, Hyeryung, Skatchkovsky, Nicolas, and Simeone, Osvaldo

Subjects
Computer Science - Machine Learning, Computer Science - Neural and Evolutionary Computing, Electrical Engineering and Systems Science - Signal Processing, Statistics - Machine Learning
Abstract

Networks of spiking neurons and Winner-Take-All spiking circuits (WTA-SNNs) can detect information encoded in spatio-temporal multi-valued events. These are described by the timing of events of interest, e.g., clicks, as well as by categorical numerical values assigned to each event, e.g., like or dislike. Other use cases include object recognition from data collected by neuromorphic cameras, which produce, for each pixel, signed bits at the times of sufficiently large brightness variations. Existing schemes for training WTA-SNNs are limited to rate-encoding solutions, and are hence able to detect only spatial patterns. Developing more general training algorithms for arbitrary WTA-SNNs inherits the challenges of training (binary) Spiking Neural Networks (SNNs). These amount, most notably, to the non-differentiability of threshold functions, to the recurrent behavior of spiking neural models, and to the difficulty of implementing backpropagation in neuromorphic hardware. In this paper, we develop a variational online local training rule for WTA-SNNs, referred to as VOWEL, that leverages only local pre- and post-synaptic information for visible circuits, and an additional common reward signal for hidden circuits. The method is based on probabilistic generalized linear neural models, control variates, and variational regularization. Experimental results on real-world neuromorphic datasets with multi-valued events demonstrate the advantages of WTA-SNNs over conventional binary SNNs trained with state-of-the-art methods, especially in the presence of limited computing resources., Comment: 14 pages, submitted for possible conference publication

Published
2020

14. Federated Neuromorphic Learning of Spiking Neural Networks for Low-Power Edge Intelligence

Author

Skatchkovsky, Nicolas, Jang, Hyeryung, and Simeone, Osvaldo

Subjects
Computer Science - Machine Learning, Computer Science - Neural and Evolutionary Computing, Electrical Engineering and Systems Science - Signal Processing, Statistics - Machine Learning
Abstract

Spiking Neural Networks (SNNs) offer a promising alternative to conventional Artificial Neural Networks (ANNs) for the implementation of on-device low-power online learning and inference. On-device training is, however, constrained by the limited amount of data available at each device. In this paper, we propose to mitigate this problem via cooperative training through Federated Learning (FL). To this end, we introduce an online FL-based learning rule for networked on-device SNNs, which we refer to as FL-SNN. FL-SNN leverages local feedback signals within each SNN, in lieu of backpropagation, and global feedback through communication via a base station. The scheme demonstrates significant advantages over separate training and features a flexible trade-off between communication load and accuracy via the selective exchange of synaptic weights., Comment: submitted for conference publication

Published
2019

15. Optimizing Pipelined Computation and Communication for Latency-Constrained Edge Learning

Author

Skatchkovsky, Nicolas and Simeone, Osvaldo

Subjects
Computer Science - Machine Learning, Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Information Theory, Computer Science - Networking and Internet Architecture, Statistics - Machine Learning
Abstract

Consider a device that is connected to an edge processor via a communication channel. The device holds local data that is to be offloaded to the edge processor so as to train a machine learning model, e.g., for regression or classification. Transmission of the data to the learning processor, as well as training based on Stochastic Gradient Descent (SGD), must be both completed within a time limit. Assuming that communication and computation can be pipelined, this letter investigates the optimal choice for the packet payload size, given the overhead of each data packet transmission and the ratio between the computation and the communication rates. This amounts to a tradeoff between bias and variance, since communicating the entire data set first reduces the bias of the training process but it may not leave sufficient time for learning. Analytical bounds on the expected optimality gap are derived so as to enable an effective optimization, which is validated in numerical results., Comment: to be published in IEEE Communication Letters

Published
2019

20. Towards the Application of Neuromorphic Computing to Satellite Communications

Author

Ortiz Gomez, Flor de Guadalupe, Lagunas, Eva, Alves Martins, Wallace, Dinh, Thinh, Skatchkovsky, Nicolas, Simeone, Osvaldo, Rajendran, Bipin, Navarro, Tomas, Chatzinotas, Symeon, Ortiz Gomez, Flor de Guadalupe, Lagunas, Eva, Alves Martins, Wallace, Dinh, Thinh, Skatchkovsky, Nicolas, Simeone, Osvaldo, Rajendran, Bipin, Navarro, Tomas, and Chatzinotas, Symeon

Abstract

Artificial intelligence (AI) has recently received significant attention as a key enabler for future 5G-and-beyond terrestrial wireless networks. The applications of AI to satellite communications is also gaining momentum to realize a more autonomous operation with reduced requirements in terms of human intervention. The adoption of AI for satellite communications will set new requirements on computing processors, which will need to support large workloads as efficiently as possible under harsh environmental conditions. In this context, neuromorphic processing (NP) is emerging as a bio-inspired solution to address pattern recognition tasks involving multiple, possibly unstructured, temporal signals and/or requiring continual learning. The key merits of the technology are energy efficiency and capacity for on-device adaptation. In this paper, we highlight potential use cases and applications of NP to satellite communications. We also explore major technical challenges for the implementation of space-based NP focusing on the available NP chipsets.

Published
2022

30. Identifying neural substrates of competitive interactions and sequence transitions during mechanosensory responses in Drosophila

Author

Marta Zlatic, Jean-Baptiste Masson, François Laurent, Nicolas Skatchkovsky, Albert Cardona, Tihana Jovanic, Chloé Barré, Décision et processus Bayesiens - Decision and Bayesian Computation, Institut Pasteur [Paris]-Centre National de la Recherche Scientifique (CNRS), Janelia Research Campus [Ashburn] (HHMI Janelia), Howard Hughes Medical Institute (HHMI), University of Cambridge [UK] (CAM), Institut des Neurosciences Paris-Saclay (NeuroPSI), Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), We thank Howard Hughes Medical Institute for funding (M.Z.). We acknowledge funding from the Pasteur Institute (J.B.M), the sponsorship of CRPCEN (J.B.M), the ANR-17-CE23-0016 TRamWAy (J.B.M), the INCEPTION project (PIA/ANR- 16-CONV-0005, OG) (J.B.M), the Institut 3IA Prairie (J.B.M), MSCA 79805 (T.J.) and ANR-17-CE37-0019-01 (T.J.)., ANR-17-CE23-0016,TRamWAy,L'Analyseur Automatique de Marches Aléatoires Biomoléculaires: La Science des molécules uniques à l'époque des données massives(2017), ANR-16-CONV-0005,INCEPTION,Institut Convergences pour l'étude de l'Emergence des Pathologies au Travers des Individus et des populatiONs(2016), ANR-17-CE37-0019,DECISIONSEQ,Base neuronale de la prise de decision et de sequences compartementales(2017), ANR-19-P3IA-0001,PRAIRIE,PaRis Artificial Intelligence Research InstitutE(2019), Institut Pasteur [Paris] (IP)-Centre National de la Recherche Scientifique (CNRS), Centre de Bioinformatique, Biostatistique et Biologie Intégrative (C3BI), Masson, Jean-Baptiste [0000-0002-5484-9056], Laurent, François [0000-0002-1615-6400], Cardona, Albert [0000-0003-4941-6536], Skatchkovsky, Nicolas [0000-0002-9111-7479], Zlatic, Marta [0000-0002-3149-2250], Jovanic, Tihana [0000-0002-0525-8620], and Apollo - University of Cambridge Repository

Subjects
Nervous system, Life Cycles, Cancer Research, [SDV.NEU.NB]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]/Neurobiology, Social Sciences, Action Potentials, QH426-470, Nervous System, Mechanotransduction, Cellular, Synaptic Transmission, Brain mapping, Animals, Genetically Modified, Larvae, Cognition, 0302 clinical medicine, Animal Cells, Neural Pathways, Medicine and Health Sciences, Psychology, Electron Microscopy, Research article, Mechanotransduction, Genetics (clinical), Motor Neurons, Neurons, Microscopy, Brain Mapping, 0303 health sciences, [SDV.NEU.PC]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]/Psychology and behavior, biology, [SDV.NEU.SC]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]/Cognitive Sciences, Eukaryota, Brain, Animal Models, Phenotype, Insects, Drosophila melanogaster, medicine.anatomical_structure, Experimental Organism Systems, Drosophila, Cellular Types, Anatomy, Cues, Research Article, Arthropoda, Sensory Receptor Cells, Decision Making, Research and Analysis Methods, Binding, Competitive, 03 medical and health sciences, Model Organisms, medicine, Genetics, Animals, Molecular Biology, Sensory cue, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Sequence (medicine), Cognitive Psychology, Organisms, Biology and Life Sciences, Cell Biology, biology.organism_classification, Invertebrates, Cellular Neuroscience, Animal Studies, Cognitive Science, Sensory Neurons, Neuroscience, 030217 neurology & neurosurgery, Developmental Biology
Abstract

Nervous systems have the ability to select appropriate actions and action sequences in response to sensory cues. The circuit mechanisms by which nervous systems achieve choice, stability and transitions between behaviors are still incompletely understood. To identify neurons and brain areas involved in controlling these processes, we combined a large-scale neuronal inactivation screen with automated action detection in response to a mechanosensory cue in Drosophila larva. We analyzed behaviors from 2.9x105 larvae and identified 66 candidate lines for mechanosensory responses out of which 25 for competitive interactions between actions. We further characterize in detail the neurons in these lines and analyzed their connectivity using electron microscopy. We found the neurons in the mechanosensory network are located in different regions of the nervous system consistent with a distributed model of sensorimotor decision-making. These findings provide the basis for understanding how selection and transition between behaviors are controlled by the nervous system., Author summary All animals are constantly confronted with multiple behavioral options that they need to choose from in response to various stimuli. Yet how the brain controls the sensorimotor decision-making process and ensures that appropriate actions are chosen and correctly ordered remains a mystery. This is largely due to the difficulty in establishing causal relationships between neurons and sensorimotor decisions and determining the connectivity between the neurons underlying sensorimotor decisions. In this study, we used automated action detection to analyze behaviors of hundreds of thousands of Drosophila larvae in which we systematically silenced small subsets of neurons in response to a mechanosensory cue and identified candidate neurons for competitive interactions and transitions between different actions. We further analyzed the connectivity between these neurons using electron microscopy reconstruction and identified a putative network underlying sensorimotor decision-making during mechanosensory responses. We found this mechanosensory network is distributed in the nervous system from the first order interneuron on the sensory side to the motor side and higher order brain regions.

Published
2020

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