Progressive transformation of hippocampal neuronal representations in "morphed" environments.
about
A process analysis of the CA3 subregion of the hippocampusFlexible kernel memoryA critical review of the allocentric spatial representation and its neural underpinnings: toward a network-based perspectiveGamma Synchronization Influences Map Formation Time in a Topological Model of Spatial LearningDynamic grouping of hippocampal neural activity during cognitive control of two spatial framesA mismatch-based model for memory reconsolidation and extinction in attractor networksInformation and the Origin of QualiaCell assemblies of the superficial cortexAuditory stimuli elicit hippocampal neuronal responses during sleep.Sound sensitivity of neurons in rat hippocampus during performance of a sound-guided task.Neural encoding of the concept of nest in the mouse brain.Mapping dynamic memories of gradually changing objectsExperience-dependent development of coordinated hippocampal spatial activity representing the similarity of related locationsComplementary roles of human hippocampal subfields in differentiation and integration of spatial contextEngagement of neural circuits underlying 2D spatial navigation in a rodent virtual reality system.Characterisation of sensitivity and orientation tuning for visually responsive ensembles in the zebrafish tectumA balanced memory network.Continuous attractors with morphed/correlated mapsInactivation of the Lateral Entorhinal Area Increases the Influence of Visual Cues on Hippocampal Place Cell ActivityHippocampal cells encode places by forming small anatomical clusters.Attention-like modulation of hippocampus place cell discharge.Human hippocampal CA1 involvement during allocentric encoding of spatial information.Attractor-map versus autoassociation based attractor dynamics in the hippocampal network.Unmasking the CA1 ensemble place code by exposures to small and large environments: more place cells and multiple, irregularly arranged, and expanded place fields in the larger space.Reconceiving the hippocampal map as a topological template.Multivariate pattern analysis of the human medial temporal lobe revealed representationally categorical cortex and representationally agnostic hippocampusAdult Hippocampal Neurogenesis, Fear Generalization, and Stress.Functional inactivation of the rat hippocampus disrupts avoidance of a moving object.Place cells in the hippocampus: eleven maps for eleven rooms.Cholinergic plasticity of oscillating neuronal assemblies in mouse hippocampal slices.Place cell rate remapping by CA3 recurrent collaterals.Pattern separation in the hippocampus.Statistical computations underlying the dynamics of memory updating.DISC1-mediated dysregulation of adult hippocampal neurogenesis in ratsThe influence of objects on place field expression and size in distal hippocampal CA1.Decoding representations of scenes in the medial temporal lobes.Brain State Is a Major Factor in Preseizure Hippocampal Network Activity and Influences Success of Seizure Intervention.Grid cell firing patterns signal environmental novelty by expansionTransient optogenetic inactivation of the medial entorhinal cortex biases the active population of hippocampal neurons.Odor representations in the rat olfactory bulb change smoothly with morphing stimuli.
P2860
Q21129484-2E781CCF-8491-4478-8F24-25E27874D9D9Q21136350-3167669A-1DB3-40CE-8567-B0870758B5CDQ27024255-DB1647AF-D04C-44B3-B54E-4C19FAB6B105Q27315890-594060E1-6CE8-4783-B126-845ECA900CBCQ27324163-575E4E8D-7373-465E-A02F-458E3908576BQ27325460-E9658532-7A98-492C-A5A6-3304E8DDC3B7Q30357036-79DF7F4A-B6E1-4894-BF4E-024177A2E75EQ30448198-41E8F4A6-74BC-46CF-A515-71EB99B8EF32Q30466022-76E26B51-7750-4475-82F8-D8FEF5FC74A3Q30468353-A8337FC3-B390-49EA-9DDA-617EE319EC51Q30479271-01DA3B6A-CCC0-40AD-87FA-8968DC0BF93AQ30486778-4AB94ABD-89BD-48DA-9CD2-3AF92266CB4FQ30497189-94A37D8C-D0A4-4285-BC3C-448B418A6788Q30619390-942AF936-FB24-4C96-9460-5D19F10282EAQ30653011-B01985EB-B1BA-4493-A203-CDA57BF3C8D1Q30819438-0EBFC88C-3E6D-46C4-AF60-04FBB25DBFDEQ33298401-CBB2F83C-22FC-4F78-8D8C-34FB1C43CAA7Q33654156-E62E78BF-A57E-46BE-B526-96FEB3FBD0F5Q33734641-8DC17048-2AD2-4CD1-AF33-6A3E335610BDQ33797899-F00E6268-B89B-4779-A17C-B3DECC4E2250Q33804899-E5356391-9A13-48AA-A041-74A200DD3DC5Q33865057-8C62CED9-18B4-4EBC-8854-C95277742DFAQ33995353-E06529C3-7112-4B0F-8BC8-3F6DC081A96AQ34014471-930CCCEA-6B7D-4DF7-BCEC-BAB33327908EQ34169558-CF6FE504-619E-4358-BBAB-ABCC7677C5EFQ34339150-D559E1ED-F909-47BE-9EE6-7654924FED01Q34480465-3ACBB255-43DD-4069-857B-637F42647613Q34750333-2BCB1926-B04B-4DB5-955E-399E76191096Q34831874-3BEBE318-D192-456B-A015-4AB0A9BBFD75Q35049214-8A2C4CEC-3DC8-43C6-9899-1E71394633ACQ35182357-301EEA3F-F1E5-428C-BE6E-9297DB3A11BBQ35242845-4259375D-FB81-4BE3-A416-B592C47EB1A2Q35399827-78535325-78FE-43F7-9229-540FE7FF081CQ35777839-990889A9-373B-416A-BEA6-807E010C4D94Q35857441-DCC9232D-E017-4FB1-982E-63AD5D9573C7Q36316109-F7A46433-1AE5-4D64-84B3-BA34559A04F9Q36319842-6F474CF3-C82F-47DD-97C5-A5FBE8675309Q36378411-315AAA01-E42D-42EA-901A-F2CCAB624C12Q36479852-5924F83F-33E3-470F-9C88-80D0129B739EQ36482406-40AB87D2-5726-4023-BBD5-2F71AB05C29C
P2860
Progressive transformation of hippocampal neuronal representations in "morphed" environments.
description
2005 nî lūn-bûn
@nan
2005年の論文
@ja
2005年学术文章
@wuu
2005年学术文章
@zh
2005年学术文章
@zh-cn
2005年学术文章
@zh-hans
2005年学术文章
@zh-my
2005年学术文章
@zh-sg
2005年學術文章
@yue
2005年學術文章
@zh-hant
name
Progressive transformation of ...... ons in "morphed" environments.
@en
Progressive transformation of ...... ons in "morphed" environments.
@nl
type
label
Progressive transformation of ...... ons in "morphed" environments.
@en
Progressive transformation of ...... ons in "morphed" environments.
@nl
prefLabel
Progressive transformation of ...... ons in "morphed" environments.
@en
Progressive transformation of ...... ons in "morphed" environments.
@nl
P2093
P50
P1433
P1476
Progressive transformation of ...... ons in "morphed" environments.
@en
P2093
Bruce L McNaughton
Carol A Barnes
Retsina Meyer
Stefan Leutgeb
P304
P356
10.1016/J.NEURON.2005.09.007
P407
P577
2005-10-01T00:00:00Z