Search results for "Computational Neuroscience"

showing 10 items of 21 documents

26th Annual Computational Neuroscience Meeting (CNS*2017): Part 2

2017

International audience; No abstract available

0301 basic medicineCerebellumComputer science[SDV]Life Sciences [q-bio]General Neurosciencelcsh:QP351-495Meeting Abstractslcsh:RC321-57103 medical and health sciencesCellular and Molecular Neurosciencelcsh:Neurophysiology and neuropsychology030104 developmental biologymedicine.anatomical_structuremedicineNeuronlcsh:Neurosciences. Biological psychiatry. NeuropsychiatryNeuroscienceComputingMilieux_MISCELLANEOUScomputational neuroscienceBMC Neuroscience
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Network-Wide Adaptive Burst Detection Depicts Neuronal Activity with Improved Accuracy

2017

Neuronal networks are often characterized by their spiking and bursting statistics. Previously, we introducedan adaptive burst analysis methodwhich enhances the analysis power for neuronal networks with highly varying firing dynamics. The adaptation is based on single channels analyzing each element of a network separately. Such kind of analysis was adequate for the assessment of local behavior, where the analysis focuses on the neuronal activity in the vicinity of a single electrode. However, the assessment of the whole network may be hampered, if parts of the network are analyzed using different rules. Here, we test how using multiple channels and measurement time points affect adaptive b…

0301 basic medicineComputer scienceNeuroscience (miscellaneous)Interval (mathematics)Machine learningcomputer.software_genreta3112lcsh:RC321-57103 medical and health sciencesCellular and Molecular NeuroscienceBursting0302 clinical medicineMoving averageHistogramMethodsCluster analysislcsh:Neurosciences. Biological psychiatry. Neuropsychiatryta113network classificationbusiness.industryEmphasis (telecommunications)Pattern recognition217 Medical engineeringlaskennallinen neurotiede113 Computer and information sciencesPower (physics)030104 developmental biologymicroelectrode arraysburst detectionburst synchronySpike (software development)Artificial intelligenceneuronal networksbusinesscomputer030217 neurology & neurosurgeryNeurosciencecomputational neuroscienceFrontiers in Computational Neuroscience
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Topographic Independent Component Analysis reveals random scrambling of orientation in visual space

2017

Neurons at primary visual cortex (V1) in humans and other species are edge filters organized in orientation maps. In these maps, neurons with similar orientation preference are clustered together in iso-orientation domains. These maps have two fundamental properties: (1) retinotopy, i.e. correspondence between displacements at the image space and displacements at the cortical surface, and (2) a trade-off between good coverage of the visual field with all orientations and continuity of iso-orientation domains in the cortical space. There is an active debate on the origin of these locally continuous maps. While most of the existing descriptions take purely geometric/mechanistic approaches whi…

0301 basic medicineComputer scienceVisionVisual spaceStatistics as Topiclcsh:MedicineSocial SciencesSpace (mathematics)Scramblingchemistry.chemical_compound0302 clinical medicineCognitionLearning and MemoryAnimal CellsMedicine and Health SciencesPsychologylcsh:Sciencemedia_commonVisual CortexNeuronsMammalsObject RecognitionCoding MechanismsBrain MappingMultidisciplinaryGeographyOrientation (computer vision)Visual fieldmedicine.anatomical_structureVertebratesSensory PerceptionCellular TypesAnatomyNeuronal TuningResearch ArticleCartographyPrimatesmedia_common.quotation_subjectOcular AnatomyRetina03 medical and health sciencesTopographic MapsOcular SystemMemoryPerceptionOrientationNeuronal tuningmedicineAnimalsHumansCortical surfaceComputational NeuroscienceRetinabusiness.industrylcsh:ROrganismsCognitive PsychologyBiology and Life SciencesComputational BiologyRetinalPattern recognitionCell Biology030104 developmental biologyVisual cortexchemistryRetinotopyCellular NeuroscienceAmniotesEarth SciencesCognitive Sciencelcsh:QPerceptionArtificial intelligencebusiness030217 neurology & neurosurgeryNeurosciencePLoS ONE
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Flexible switching of feedback control mechanisms allows for learning of different task dynamics.

2013

To produce skilled movements, the brain flexibly adapts to different task requirements and movement contexts. Two core abilities underlie this flexibility. First, depending on the task, the motor system must rapidly switch the way it produces motor commands and how it corrects movements online, i.e. it switches between different (feedback) control policies. Second, it must also adapt to environmental changes for different tasks separately. Here we show these two abilities are related. In a bimanual movement task, we show that participants can switch on a movement-by-movement basis between two feedback control policies, depending only on a static visual cue. When this cue indicates that the …

AdultAnatomy and PhysiologyCognitive NeuroscienceMovementFeedback controlNeurophysiologylcsh:MedicineMotor ActivitySocial and Behavioral SciencesNeurological SystemFeedbackMotor ReactionsYoung Adult03 medical and health sciencesLearning and Memory0302 clinical medicineHuman–computer interactionTask Performance and AnalysisMotor systemReaction TimePsychologyLearningHumansMotor activitylcsh:ScienceBiologySensory cue030304 developmental biologyMotor SystemsComputational NeurosciencePhysics0303 health sciencesMultidisciplinarybusiness.industrylcsh:RCognitive PsychologyMotor commandsRoboticsMental HealthArmMedicinelcsh:QArtificial intelligenceCuesbusiness030217 neurology & neurosurgeryHuman learningResearch ArticleNeurosciencePLoS ONE
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An ensemble analysis of electromyographic activity during whole body pointing with the use of support vector machines.

2011

Import JabRef | WosArea Life Sciences and Biomedicine - Other Topics; International audience; We explored the use of support vector machines (SVM) in order to analyze the ensemble activities of 24 postural and focal muscles recorded during a whole body pointing task. Because of the large number of variables involved in motor control studies, such multivariate methods have much to offer over the standard univariate techniques that are currently employed in the field to detect modifications. The SVM was used to uncover the principle differences underlying several variations of the task. Five variants of the task were used. An unconstrained reaching, two constrained at the focal level and two …

AdultMaleSupport Vector MachineNeural NetworksComputer sciencePosturelcsh:MedicineElectromyographyKinematicsMotor ActivityDIAGNOSISCLASSIFICATIONTask (project management)03 medical and health sciences0302 clinical medicineDiscriminative modelmedicineHumanslcsh:ScienceMuscle SkeletalBiology030304 developmental biologyComputational NeuroscienceMotor Systems0303 health sciencesCOORDINATIONMultidisciplinaryMOVEMENTSmedicine.diagnostic_testbusiness.industryElectromyographylcsh:RUnivariateMotor controlPattern recognitionBiomechanical PhenomenaSupport vector machineKernel methodEQUILIBRIUMPATTERNSARM[SDV.NEU]Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]lcsh:QArtificial intelligencebusiness030217 neurology & neurosurgeryResearch ArticleNeurosciencePloS one
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Sparse Distributed Representation of Odors in a Large-scale Olfactory Bulb Circuit

2013

In the olfactory bulb, lateral inhibition mediated by granule cells has been suggested to modulate the timing of mitral cell firing, thereby shaping the representation of input odorants. Current experimental techniques, however, do not enable a clear study of how the mitral-granule cell network sculpts odor inputs to represent odor information spatially and temporally. To address this critical step in the neural basis of odor recognition, we built a biophysical network model of mitral and granule cells, corresponding to 1/100th of the real system in the rat, and used direct experimental imaging data of glomeruli activated by various odors. The model allows the systematic investigation and g…

Circuit ModelsMaleNerve net0302 clinical medicineLateral inhibitionOdorlcsh:QH301-705.5NeuronsFeedback PhysiologicalCoding Mechanisms0303 health sciencesNeuronal PlasticityEcologyAnatomyOlfactory BulbSynapseSensory Systemsmedicine.anatomical_structureComputational Theory and MathematicsModeling and SimulationExcitatory postsynaptic potentialResearch ArticleModels NeurologicalBiologyInhibitory postsynaptic potential03 medical and health sciencesCellular and Molecular NeuroscienceGeneticNeuroplasticityGeneticsmedicineAnimalsComputer SimulationBiologyMolecular BiologyEcology Evolution Behavior and Systematics030304 developmental biologyComputational NeuroscienceOlfactory SystemAnimalComputational BiologyNeuronEcology Evolution Behavior and SystematicRatsOlfactory bulbOdorlcsh:Biology (General)OdorantsSynapsesSynaptic plasticityRatNerve NetNeuroscience030217 neurology & neurosurgeryNeuroscience
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Implicit Perception Simplicity and Explicit Perception Complexity in Sensorimotor Comunication

2019

Cognitive scienceComputational neuroscienceactive perceptionActive perceptionComputer scienceSocial perceptionmedia_common.quotation_subjectGeneral Physics and Astronomysocial perceptionKinematicsArtificial IntelligencePerceptionSimplicityGeneral Agricultural and Biological Sciencesmedia_commoncomputational neuroscience
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Derivatives and inverse of a linear-nonlinear multi-layer spatial vision model

2016

Linear-nonlinear transforms are interesting in vision science because they are key in modeling a number of perceptual experiences such as color, motion or spatial texture. Here we first show that a number of issues in vision may be addressed through an analytic expression of the Jacobian of these linear-nonlinear transforms. The particular model analyzed afterwards (an extension of [Malo & Simoncelli SPIE 2015]) is illustrative because it consists of a cascade of standard linear-nonlinear modules. Each module roughly corresponds to a known psychophysical mechanism: (1) linear spectral integration and nonlinear brightness-from-luminance computation, (2) linear pooling of local brightness…

Computational NeuroscienceDeep NetworkQuantitative Biology - Neurons and CognitionFOS: Biological sciencesLinear-Nonlinear Model92B20Multi-Layer ModelNeurons and Cognition (q-bio.NC)InverseJacobian
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Towards a Functional Explanation of the Connectivity LGN - V1

2016

The principles behind the connectivity between LGN and V1 are not well understood. Models have to explain two basic experimental trends: (i) the combination of thalamic responses is local and it gives rise to a variety of oriented Gabor-like receptive felds in V1 [1], and (ii) these filters are spatially organized in orientation maps [2]. Competing explanations of orientation maps use purely geometrical arguments such as optimal wiring or packing from LGN [3-5], but they make no explicit reference to visual function. On the other hand, explanations based on func- tional arguments such as maximum information transference (infomax) [6,7] usually neglect a potential contribution from LGN local…

Computational NeuroscienceV1connectivityLGNinformation maximization
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Appropriate kernels for Divisive Normalization explained by Wilson-Cowan equations

2018

The interaction between wavelet-like sensors in Divisive Normalization is classically described through Gaussian kernels that decay with spatial distance, angular distance and frequency distance. However, simultaneous explanation of (a) distortion perception in natural image databases and (b) contrast perception of artificial stimuli requires very specific modifications in classical Divisive Normalization. First, the wavelet response has to be high-pass filtered before the Gaussian interaction is applied. Then, distinct weights per subband are also required after the Gaussian interaction. In summary, the classical Gaussian kernel has to be left- and right-multiplied by two extra diagonal ma…

Computational NeuroscienceWilson-Cowan modelQuantitative Biology::Neurons and CognitionDivisive Normalization modelFOS: Biological sciencesQuantitative Biology - Neurons and CognitionInteractions in V1Neurons and Cognition (q-bio.NC)
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