Techniques for extracting single-trial activity patterns from large-scale neural recordings - Wikidata - wikimedia - TriplyDB

Techniques for extracting single-trial activity patterns from large-scale neural recordings

Techniques for extracting single-trial activity patterns from large-scale neural recordings

http://www.wikidata.org/entity/Q36453626

about

Representation of Muscle Synergies in the Primate Brain Limb apraxia and the "affordance competition hypothesis"3D in vitro modeling of the central nervous system Attracting dynamics of frontal cortex ensembles during memory-guided decision-making Autonomous head-mounted electrophysiology systems for freely behaving primates.Dual dimensionality reduction reveals independent encoding of motor features in a muscle synergy for insect flight control Dynamic Structure of Neural Variability in the Cortical Representation of Speech Sounds.Neural population coding: combining insights from microscopic and mass signals Control of spoken vowel acoustics and the influence of phonetic context in human speech sensorimotor cortex.Behavioral states, network states, and sensory response variability SORN: a self-organizing recurrent neural network.Stimulus onset quenches neural variability: a widespread cortical phenomenon Roles of monkey premotor neuron classes in movement preparation and execution Single-trial neural correlates of arm movement preparation.Reversible large-scale modification of cortical networks during neuroprosthetic control.Changes in the response rate and response variability of area V4 neurons during the preparation of saccadic eye movements.Spike train SIMilarity Space (SSIMS): a framework for single neuron and ensemble data analysis Rapid face adaptation distributes representation in inferior-temporal cortex across time and neuronal dimensions Mouse visual neocortex supports multiple stereotyped patterns of microcircuit activity.How advances in neural recording affect data analysis A study on decoding models for the reconstruction of hand trajectories from the human magnetoencephalography.One month in the life of a neuron: longitudinal single-unit electrophysiology in the monkey visual system.Cortical preparatory activity: representation of movement or first cog in a dynamical machine?State-dependent computations: spatiotemporal processing in cortical networks.Applying the multivariate time-rescaling theorem to neural population models.Future developments in brain-machine interface research Quality metrics to accompany spike sorting of extracellular signals.Mapping brain activity at scale with cluster computing.Vacillation, indecision and hesitation in moment-by-moment decoding of monkey motor cortex.Spatiotemporal conditional inference and hypothesis tests for neural ensemble spiking precision Microelectrode arrays fabricated using a novel hybrid microfabrication method.Emergent bursting and synchrony in computer simulations of neuronal cultures Linking Objects to Actions: Encoding of Target Object and Grasping Strategy in Primate Ventral Premotor Cortex.Reprogramming movements: extraction of motor intentions from cortical ensemble activity when movement goals change.Neural Population Dynamics during Reaching Are Better Explained by a Dynamical System than Representational Tuning Dissociation of response variability from firing rate effects in frontal eye field neurons during visual stimulation, working memory, and attention.Capturing the temporal evolution of choice across prefrontal cortex.Prefrontal spatial working memory network predicts animal's decision making in a free choice saccade task.A recurrent neural network for closed-loop intracortical brain-machine interface decoders A dynamical systems view of motor preparation: implications for neural prosthetic system design

P2860

Q26786060-080DF1D8-1B2A-4341-AA97-9C653BEF8230 Q26797389-78748DB7-75DB-4982-A6F1-08549BE81A13 Q27026457-57012097-15DE-4F0D-9DE4-CDEE123BC370 Q27333501-C0F46037-AC17-4AEA-894C-55929FE74C69 Q27690665-93659F6C-ACD3-40EB-BF45-6FE8DCE9049E Q28648327-8161442F-C163-437D-ADC8-48CA9E304282 Q30365749-F054413F-A1D2-4E4D-8600-E4069EF93793 Q30415032-01D0035E-F58B-4C0F-AA2A-F5D730B20F33 Q30416620-704AF324-8814-4058-9C88-A4F3601F07B9 Q30487221-7C37FDE8-8F35-4903-B184-A4496BE2C824 Q30491428-D6CFE646-ECAF-473B-AA7D-C0534A1A3299 Q30493353-22E9370B-2EB6-47D8-BE89-503FC1242717 Q30496473-49B11E4D-DA58-41E5-A4DD-05634C280D7E Q30503458-CE4CF631-5808-4FCC-8018-7DE48646021F Q30519503-2EEC1DC2-5BA1-4BEB-9C86-BDF232BD99AB Q30544903-3B9BE479-F2CE-46B4-BFE8-CA82EA720A5E Q30868412-F1A3BD40-2D23-49BC-A5CD-19A49020CAB1 Q33687440-E1C2B881-044D-4877-955E-24578863B3BC Q33707848-607496E6-E701-4594-9B31-70A3926A9AB0 Q33804881-CFFE0485-D4A9-45D1-9C70-CF0F5197F694 Q33876574-2F7A830D-A59C-425E-BEAF-1C12BFE27E22 Q34146958-0F89AEDF-A6A5-44EC-9947-736348DE292F Q34346797-B06C2BA0-19D6-4796-BC57-D02A4F829E10 Q34922174-38CDD098-3A1D-4C14-A5FF-292A796305A8 Q34958946-3EF436FC-9ED3-4B27-8ACB-9208643CB49C Q35054969-014CE6B6-8EE8-43DC-801F-46BD7C9ECE9F Q35069780-FC1B06D4-B9D3-42D3-B7A9-28DFF9731A6C Q35214217-9C7CF80C-1DA3-4B73-A21B-ED5E776C271C Q35555417-847F91DD-4A4A-4350-ADF6-CBF3CA5BB9D6 Q35687856-05B805BE-8A0E-4A08-9044-062529042684 Q35788442-A0626843-F89B-4E7A-8744-3E6668E44B35 Q35878227-E811A8AD-0D1D-4374-8E03-124F4F06C00E Q35897758-30692B71-D2CB-4010-86DB-F1F3CACF5E31 Q36101388-05C9E964-F2F8-4EF2-B72B-8E60C656DF9D Q36182782-E812823B-9584-44AA-8646-6EC1F81DE7F7 Q36227194-DE5DF627-F957-4E2C-9BA2-9F9A6F95A02F Q36479677-0813939A-0255-4135-95FF-20910A16EE44 Q36598072-F04AD566-2BB8-41B8-B9C5-21EFFB91CF8B Q36800301-E354CCF8-A93B-4F76-8B4A-074559BF8722 Q36880800-5C333DD7-326C-4C95-B40C-050C2D5BDD34

P2860

Techniques for extracting single-trial activity patterns from large-scale neural recordings

http://www.wikidata.org/entity/Q36453626

description

2007 nî lūn-bûn

@nan

2007年の論文

@ja

2007年学术文章

@wuu

2007年学术文章

@zh-cn

2007年学术文章

@zh-hans

2007年学术文章

@zh-my

2007年学术文章

@zh-sg

2007年學術文章

@yue

2007年學術文章

@zh

2007年學術文章

@zh-hant

name

Techniques for extracting sing ...... large-scale neural recordings

@ast

Techniques for extracting sing ...... large-scale neural recordings

@en

type

label

Techniques for extracting sing ...... large-scale neural recordings

@ast

Techniques for extracting sing ...... large-scale neural recordings

@en

prefLabel

Techniques for extracting sing ...... large-scale neural recordings

@ast

Techniques for extracting sing ...... large-scale neural recordings

@en

P1433

Q36453626-9AA10F85-C234-49D0-AF2F-EF34D678580E

P1476

Q36453626-6958B5DA-E64C-4AB8-B624-ECA39EECA842

P2093

Q36453626-11126252-38F5-466B-8C03-68F8A8432AB2

Q36453626-6DFA348C-2008-4897-A220-BEEAE62C507B

Q36453626-73949DFC-7F90-49B8-95DA-7ABA6EC24F23

Q36453626-FF061BB4-6CAF-465B-A5DF-72C2A67049C8

P2860

Q36453626-062503D3-A2AF-4F42-AAE1-3063B5E644E4

Q36453626-0D7B102B-317D-4E0F-B885-6D2B0B7C1A5A

Q36453626-112ED302-1A25-409A-B23D-8A4CD6039A8F

Q36453626-11FD752B-5BA8-444E-A110-E3775AA47C67

Q36453626-129A2B0B-8AEB-4AC5-982C-8F2EF3269922

Q36453626-24876F62-2014-48BA-8C03-78E3A9FB738C

Q36453626-27D1BF65-EBC9-4464-B09B-4B52E2BB1713

Q36453626-2AE3B527-97CE-4145-8950-6602DA108BA1

Q36453626-3BC23EB6-4B68-4FCC-907E-6794BFFBBD3D

Q36453626-3C642D28-C589-41E7-B176-7731A99A38F7

P304

Q36453626-CBF0DE54-13D9-4BCC-BF21-55627EB793DB

P31

Q36453626-C186CDCB-7AAC-4208-99C2-170F8EF659F0

P356

Q36453626-47683B08-25E3-460E-A466-EAC572FEC2E0

P433

Q36453626-BA88E8ED-3326-4558-AFBA-B0F3C154C488

P478

Q36453626-CA2A9CE4-AC1D-4850-83E2-0974AFD979B3

P577

Q36453626-51A754C3-61DC-461D-9507-D9789D3452FA

P5875

Q36453626-E5128A4A-34FA-4E15-B2C3-CA8E5F4906D1

P698

Q36453626-24E1E5F9-89B1-4723-A850-CB3FC3C85F95

P932

Q36453626-5FF45B62-EE9F-4964-95B6-987B345D8EFA

P356

J.CONB.2007.11.001

P1433

Current Opinion in Neurobiology

P1476

Techniques for extracting sing ...... large-scale neural recordings

@en

P2093

Byron M Yu

http://www.w3.org/2001/XMLSchema#string

Krishna V Shenoy

http://www.w3.org/2001/XMLSchema#string

Maneesh Sahani

http://www.w3.org/2001/XMLSchema#string

Mark M Churchland

http://www.w3.org/2001/XMLSchema#string

P2860

Learning to control a brain-machine interface for reaching and grasping by primates

Large-scale recording of neuronal ensembles

Multiple neural spike train data analysis: state-of-the-art and future challenges

Weak pairwise correlations imply strongly correlated network states in a neural population

Temporal binding and the neural correlates of sensory awareness

Intensity versus identity coding in an olfactory system

Chronic, multisite, multielectrode recordings in macaque monkeys

Synchronization in monkey motor cortex during a precision grip task. I. Task-dependent modulation in single-unit synchrony.

Multiple single unit recording in the cortex of monkeys using independently moveable microelectrodes.

Correlated neuronal discharge rate and its implications for psychophysical performance.

P304

609-618

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1016/J.CONB.2007.11.001

http://www.w3.org/2001/XMLSchema#string

P433

5

http://www.w3.org/2001/XMLSchema#string

P478

17

http://www.w3.org/2001/XMLSchema#string

P577

2007-10-01T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

5754878

http://www.w3.org/2001/XMLSchema#string

P698

18093826

http://www.w3.org/2001/XMLSchema#string

P932

2238690

http://www.w3.org/2001/XMLSchema#string