review article | Q7318358 |
scholarly article | Q13442814 |
P50 | author | Neil Burgess | Q23657268 |
Daniel Bush | Q89742659 | ||
Caswell Barry | Q91329879 | ||
Daniel Manson | Q123501845 | ||
P2860 | cites work | Accurate path integration in continuous attractor network models of grid cells | Q21145367 |
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Conjunctive representation of position, direction, and velocity in entorhinal cortex | Q28238425 | ||
Grid cells generate an analog error-correcting code for singularly precise neural computation | Q28247736 | ||
The hippocampus as a spatial map. Preliminary evidence from unit activity in the freely-moving rat | Q28250476 | ||
Path integration and the neural basis of the 'cognitive map' | Q28253248 | ||
Microstructure of a spatial map in the entorhinal cortex | Q28257459 | ||
Optimal population codes for space: grid cells outperform place cells | Q28266824 | ||
Head-direction cells recorded from the postsubiculum in freely moving rats. I. Description and quantitative analysis | Q28276444 | ||
Hippocampus-independent phase precession in entorhinal grid cells | Q28280152 | ||
Grid cells in pre- and parasubiculum | Q28288739 | ||
Remembering the past and imagining the future: a neural model of spatial memory and imagery | Q28302192 | ||
Place navigation impaired in rats with hippocampal lesions | Q29547869 | ||
Place cells and silent cells in the hippocampus of freely-behaving rats | Q30460249 | ||
Distinct error-correcting and incidental learning of location relative to landmarks and boundaries | Q30481690 | ||
Linear look-ahead in conjunctive cells: an entorhinal mechanism for vector-based navigation | Q30513830 | ||
Hippocampal place-cell sequences depict future paths to remembered goals | Q30576341 | ||
Hippocampal replay of extended experience | Q30629051 | ||
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. | Q34014471 | ||
The effects of changes in the environment on the spatial firing of hippocampal complex-spike cells | Q34050288 | ||
The human hippocampus and spatial and episodic memory | Q34145961 | ||
Knowing where and getting there: a human navigation network | Q34466707 | ||
The medial temporal lobe memory system | Q34599469 | ||
Cognitive maps in rats and men. | Q34854072 | ||
Grid cells in rat entorhinal cortex encode physical space with independent firing fields and phase precession at the single-trial level | Q35924955 | ||
Place cell discharge is extremely variable during individual passes of the rat through the firing field | Q35982399 | ||
Neural representations of location composed of spatially periodic bands | Q36077906 | ||
Dendritic computation | Q36201603 | ||
Dual phase and rate coding in hippocampal place cells: theoretical significance and relationship to entorhinal grid cells | Q36250584 | ||
Grid cell firing patterns signal environmental novelty by expansion | Q36378411 | ||
An oscillatory interference model of grid cell firing | Q36863655 | ||
Inactivation of hippocampus or caudate nucleus with lidocaine differentially affects expression of place and response learning. | Q51583690 | ||
Grid cell hexagonal patterns formed by fast self-organized learning within entorhinal cortex. | Q51627233 | ||
A model of grid cells based on a twisted torus topology. | Q51908043 | ||
A model of hippocampally dependent navigation, using the temporal difference learning rule. | Q52028576 | ||
Absence of overshadowing and blocking between landmarks and the geometric cues provided by the shape of a test arena. | Q52108238 | ||
Theory of rodent navigation based on interacting representations of space. | Q52203610 | ||
A model of spatial map formation in the hippocampus of the rat. | Q52204021 | ||
Latent learning in a water maze. | Q52368436 | ||
Evidence for entorhinal and parietal cortices involvement in path integration in the rat. | Q53841203 | ||
Cosine directional tuning of theta cell burst frequencies: evidence for spatial coding by oscillatory interference | Q37135708 | ||
Hippocampus and retrosplenial cortex combine path integration signals for successful navigation. | Q37362464 | ||
Phase coding by grid cells in unconstrained environments: two-dimensional phase precession | Q37550797 | ||
What do grid cells contribute to place cell firing? | Q38184137 | ||
Grid cells and theta as oscillatory interference: theory and predictions | Q38750183 | ||
Hippocampal place cells construct reward related sequences through unexplored space | Q38991391 | ||
Controlling phase noise in oscillatory interference models of grid cell firing | Q39065567 | ||
The hippocampus and entorhinal cortex encode the path and Euclidean distances to goals during navigation. | Q39178844 | ||
Does the entorhinal cortex use the Fourier transform? | Q39283048 | ||
Simulation of spatial learning in the Morris water maze by a neural network model of the hippocampal formation and nucleus accumbens | Q40407493 | ||
Grid cells form a global representation of connected environments. | Q40471051 | ||
Neuronal computations underlying the firing of place cells and their role in navigation | Q40954798 | ||
Grid cell mechanisms and function: contributions of entorhinal persistent spiking and phase resetting | Q41863371 | ||
Independent rate and temporal coding in hippocampal pyramidal cells | Q42017437 | ||
A goal-directed spatial navigation model using forward trajectory planning based on grid cells | Q42051157 | ||
A biologically inspired hierarchical goal directed navigation model | Q42063689 | ||
Theta phase precession of grid and place cell firing in open environments | Q42634712 | ||
Neural activity in human hippocampal formation reveals the spatial context of retrieved memories | Q42641488 | ||
Grid cell symmetry is shaped by environmental geometry. | Q43245130 | ||
Multiscale codes in the nervous system: the problem of noise correlations and the ambiguity of periodic scales. | Q43420583 | ||
What grid cells convey about rat location | Q44445827 | ||
Visual images preserve metric spatial information: Evidence from studies of image scanning | Q45155505 | ||
Synaptic integration in an excitable dendritic tree. | Q46019695 | ||
Finite scale of spatial representation in the hippocampus | Q46503015 | ||
Beyond the mental number line: A neural network model of number-space interactions | Q47409456 | ||
Position reconstruction from an ensemble of hippocampal place cells: contribution of theta phase coding | Q47899559 | ||
Neural network modeling of the hippocampal formation spatial signals and their possible role in navigation: a modular approach | Q47918633 | ||
Hippocampal place units in the freely moving rat: why they fire where they fire | Q47963837 | ||
Distinct roles of medial and lateral entorhinal cortex in spatial cognition | Q48007307 | ||
Experience-dependent rescaling of entorhinal grids | Q48175917 | ||
Delay-dependent impairment of a matching-to-place task with chronic and intrahippocampal infusion of the NMDA-antagonist D-AP5. | Q48221570 | ||
Fragmentation of grid cell maps in a multicompartment environment | Q48257746 | ||
The entorhinal grid map is discretized | Q48261763 | ||
Cognitive strategies dependent on the hippocampus and caudate nucleus in human navigation: variability and change with practice. | Q48262378 | ||
Space, time and learning in the hippocampus: how fine spatial and temporal scales are expanded into population codes for behavioral control | Q48310598 | ||
Shearing-induced asymmetry in entorhinal grid cells | Q48333701 | ||
Entorhinal cortex grid cells can map to hippocampal place cells by competitive learning | Q48340587 | ||
The well-worn route and the path less traveled: distinct neural bases of route following and wayfinding in humans | Q48368621 | ||
From grid cells to place cells: a mathematical model | Q48375025 | ||
Reverse replay of behavioural sequences in hippocampal place cells during the awake state | Q48513304 | ||
A spin glass model of path integration in rat medial entorhinal cortex. | Q48577761 | ||
Spatial memory deficits in patients with unilateral damage to the right hippocampal formation | Q48824223 | ||
A controlled attractor network model of path integration in the rat. | Q49044670 | ||
Spatial memory in the rat requires the dorsolateral band of the entorhinal cortex | Q49124853 | ||
P275 | copyright license | Creative Commons Attribution 4.0 International | Q20007257 |
P6216 | copyright status | copyrighted | Q50423863 |
P433 | issue | 3 | |
P407 | language of work or name | English | Q1860 |
P921 | main subject | artificial neural network | Q192776 |
grid neuron | Q863495 | ||
orientation | Q1937869 | ||
neuron | Q43054 | ||
hippocampus | Q48360 | ||
P304 | page(s) | 507-20 | |
P577 | publication date | 2015-08-05 | |
P1433 | published in | Neuron | Q3338676 |
P1476 | title | Using Grid Cells for Navigation | |
P478 | volume | 87 |
Q64079217 | A Computational Model of Visual Recognition Memory via Grid Cells |
Q61449186 | A Framework for Intelligence and Cortical Function Based on Grid Cells in the Neocortex |
Q38690263 | A map of abstract relational knowledge in the human hippocampal-entorhinal cortex. |
Q26748549 | A moving observer in a three-dimensional world |
Q56529246 | A neural-level model of spatial memory and imagery |
Q42703015 | A single-cell spiking model for the origin of grid-cell patterns |
Q89742661 | Advantages and detection of phase coding in the absence of rhythmicity |
Q46155671 | Complete coverage of space favors modularity of the grid system in the brain |
Q42004235 | Connecting multiple spatial scales to decode the population activity of grid cells. |
Q40970662 | Contracted time and expanded space: The impact of circumnavigation on judgements of space and time. |
Q50519655 | Coordinated grid and place cell replay during rest. |
Q91329882 | Deforming the metric of cognitive maps distorts memory |
Q64930799 | Differentiation of mild cognitive impairment using an entorhinal cortex-based test of virtual reality navigation. |
Q89722300 | Distance and Direction Codes Underlie Navigation of a Novel Semantic Space in the Human Brain |
Q38584898 | Distorted Grids as a Spatial Label and Metric |
Q99561797 | Environmental deformations dynamically shift human spatial memory |
Q37558413 | Familiarity expands space and contracts time |
Q37610626 | Framing of grid cells within and beyond navigation boundaries. |
Q91335613 | Grid coding, spatial representation, and navigation: Should we assume an isomorphism? |
Q38826824 | Grid-cell representations in mental simulation |
Q36761590 | Grid-like Processing of Imagined Navigation |
Q47833898 | Hippocampal CA1 activity correlated with the distance to the goal and navigation performance. |
Q64258904 | Hippocampal and Retrosplenial Goal Distance Coding After Long-term Consolidation of a Real-World Environment |
Q50766083 | How environment and self-motion combine in neural representations of space. |
Q58122521 | Human Vicarious Trial and Error Is Predictive of Spatial Navigation Performance |
Q92705578 | Identifying Core Regions for Path Integration on Medial Entorhinal Cortex of Hippocampal Formation |
Q90394111 | Is hippocampal remapping the physiological basis for context? |
Q97590031 | Lessons from reinforcement learning for biological representations of space |
Q83230569 | Mapping sequence structure in the human lateral entorhinal cortex |
Q61448806 | Modeling the Effect of Environmental Geometries on Grid Cell Representations |
Q47610519 | Models of spatial and temporal dimensions of memory |
Q57793701 | Navigating Social Space |
Q58571483 | Navigating cognition: Spatial codes for human thinking |
Q92591681 | Navigating with grid and place cells in cluttered environments |
Q50014892 | Neural mechanisms of navigation involving interactions of cortical and subcortical structures. |
Q48469583 | On Decoding Grid Cell Population Codes Using Approximate Belief Propagation. |
Q38682053 | Place and Grid Cells in a Loop: Implications for Memory Function and Spatial Coding. |
Q53426918 | Planning and navigation as active inference. |
Q42694585 | Predictive Place-Cell Sequences for Goal-Finding Emerge from Goal Memory and the Cognitive Map: A Computational Model |
Q92687588 | Remembered reward locations restructure entorhinal spatial maps |
Q33364725 | Spatial Navigation and the Central Complex: Sensory Acquisition, Orientation, and Motor Control |
Q47828403 | Stellate Cells in the Medial Entorhinal Cortex Are Required for Spatial Learning. |
Q47141072 | Task Demands Predict a Dynamic Switch in the Content of Awake Hippocampal Replay |
Q47188480 | The Role of Hippocampal Replay in Memory and Planning |
Q47875532 | The cognitive map in humans: spatial navigation and beyond |
Q90130201 | The effects of developmental alcohol exposure on the neurobiology of spatial processing |
Q52990529 | Vector-based navigation using grid-like representations in artificial agents |
Q48360037 | Vectorial representation of spatial goals in the hippocampus of bats. |
Q90155484 | Visual cue-related activity of cells in the medial entorhinal cortex during navigation in virtual reality |
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