| scholarly article | Q13442814 |
| P50 | author | Christian Büchel | Q1079130 |
| Thomas Wolbers | Q48606682 | ||
| P2860 | cites work | Head direction, place, and movement correlates for cells in the rat retrosplenial cortex | Q28205368 |
| Cellular networks underlying human spatial navigation | Q28206275 | ||
| The medial temporal lobe | Q29615990 | ||
| The retrosplenial contribution to human navigation: a review of lesion and neuroimaging findings | Q30658417 | ||
| Bidimensional regression: assessing the configural similarity and accuracy of cognitive maps and other two-dimensional data sets | Q30885832 | ||
| Mental navigation in humans is processed in the anterior bank of the parieto-occipital sulcus | Q33444940 | ||
| Topographical disorientation: a synthesis and taxonomy | Q33723456 | ||
| Memory for places learned long ago is intact after hippocampal damage | Q33871839 | ||
| The Development of Spatial Representations of Large-Scale Environments | Q34052235 | ||
| Sustained mnemonic response in the human middle frontal gyrus during on-line storage of spatial memoranda | Q34139812 | ||
| The human hippocampus and spatial and episodic memory | Q34145961 | ||
| Dynamic analysis of learning in behavioral experiments. | Q34289966 | ||
| Memory for events and their spatial context: models and experiments. | Q34380496 | ||
| Knowing where and getting there: a human navigation network | Q34466707 | ||
| Hippocampal activations during repetitive learning and recall of geometric patterns | Q35041987 | ||
| Time, space and hippocampal functions. | Q35545443 | ||
| Differential effects of fornix and caudate nucleus lesions on two radial maze tasks: evidence for multiple memory systems. | Q41309618 | ||
| Multimodal representation of space in the posterior parietal cortex and its use in planning movements | Q41369764 | ||
| Neural correlates of encoding space from route and survey perspectives. | Q46726669 | ||
| Macaque monkey retrosplenial cortex: II. Cortical afferents | Q46751707 | ||
| Orientation and perspective dependence in route and survey learning | Q48089199 | ||
| Cognitive strategies dependent on the hippocampus and caudate nucleus in human navigation: variability and change with practice. | Q48262378 | ||
| The well-worn route and the path less traveled: distinct neural bases of route following and wayfinding in humans | Q48368621 | ||
| Viewpoint-specific scene representations in human parahippocampal cortex | Q48368632 | ||
| Neural basis of temporal context memory: a functional MRI study | Q48420691 | ||
| Long-term plasticity in hippocampal place-cell representation of environmental geometry | Q48667438 | ||
| Unilateral temporal lobectomy patients show lateralized topographical and episodic memory deficits in a virtual town | Q48716598 | ||
| Spatial coding of visual and somatic sensory information in body-centred coordinates | Q48792753 | ||
| The parahippocampus subserves topographical learning in man. | Q48878839 | ||
| Spatial cognition: evidence from visual neglect. | Q51949879 | ||
| A temporoparietal and prefrontal network for retrieving the spatial context of lifelike events. | Q51965005 | ||
| Memory for visuospatial location following selective hippocampal sclerosis: the use of different coordinate systems. | Q52003040 | ||
| Lesions of the caudate nucleus selectively impair "reference memory" acquisition in the radial maze. | Q52060097 | ||
| Neural foundations of emerging route knowledge in complex spatial environments. | Q52086160 | ||
| The acquisition of vector knowledge and its relation to self-rated direction sense. | Q52094743 | ||
| Individual differences in spatial learning from computer-simulated environments. | Q52139334 | ||
| Route navigating without place recognition: what is recognised in recognition-triggered responses? | Q52168234 | ||
| Brain activation during human navigation: gender-different neural networks as substrate of performance. | Q52169903 | ||
| Navigation and acquisition of spatial knowledge in a virtual maze. | Q52185161 | ||
| Differences in spatial knowledge acquired from maps and navigation. | Q52286289 | ||
| How Many Subjects Constitute a Study? | Q57004102 | ||
| Human navigation in nested environments | Q73457699 | ||
| Cognitive maps and the hippocampus | Q73783160 | ||
| P433 | issue | 13 | |
| P407 | language of work or name | English | Q1860 |
| P304 | page(s) | 3333-3340 | |
| P577 | publication date | 2005-03-01 | |
| P1433 | published in | Journal of Neuroscience | Q1709864 |
| P1476 | title | Dissociable retrosplenial and hippocampal contributions to successful formation of survey representations | |
| P478 | volume | 25 |
| Q36026737 | A central role for the retrosplenial cortex in de novo environmental learning |
| Q27024255 | A critical review of the allocentric spatial representation and its neural underpinnings: toward a network-based perspective |
| Q36073230 | A new neural framework for visuospatial processing |
| Q33812303 | A protocol for manual segmentation of medial temporal lobe subregions in 7 Tesla MRI. |
| Q34037148 | A virtual reality-based FMRI study of reward-based spatial learning |
| Q36850993 | Abstract representations of location and facing direction in the human brain. |
| Q43129552 | Acetylcholine efflux from retrosplenial areas and hippocampal sectors during maze exploration |
| Q38915950 | Activating Developmental Reserve Capacity Via Cognitive Training or Non-invasive Brain Stimulation: Potentials for Promoting Fronto-Parietal and Hippocampal-Striatal Network Functions in Old Age. |
| Q23991070 | Activation of the hippocampal complex during tactile maze solving in congenitally blind subjects |
| Q35021659 | Anchoring the neural compass: coding of local spatial reference frames in human medial parietal lobe |
| Q34593464 | Bayesian analysis of interleaved learning and response bias in behavioral experiments |
| Q96765576 | Behavior-dependent directional tuning in the human visual-navigation network |
| Q47996136 | Callosal responses in a retrosplenial column. |
| Q35954844 | Cardiovascular Fitness and Cognitive Spatial Learning in Rodents and in Humans |
| Q26823981 | Challenges for identifying the neural mechanisms that support spatial navigation: the impact of spatial scale |
| Q58765885 | Cholinergic modulation of spatial learning, memory and navigation |
| Q46498220 | Close but no cigar: Spatial precision deficits following medial temporal lobe lesions provide novel insight into theoretical models of navigation and memory |
| Q90629266 | Coding of Navigational Distance and Functional Constraint of Boundaries in the human scene-selective cortex |
| Q39224560 | Cognitive map recall test: A new specific test to assess topographical disorientation |
| Q43530019 | Cognitive mapping in humans and its relationship to other orientation skills |
| Q48987511 | Common Neural Representations for Visually Guided Reorientation and Spatial Imagery |
| Q30619390 | Complementary roles of human hippocampal subfields in differentiation and integration of spatial context |
| Q48513759 | Context-dependent place-selective responses of the neurons in the medial parietal region of macaque monkeys |
| Q38401855 | Cortical activation to indoor versus outdoor scenes: an fMRI study |
| Q37059458 | Cortical midline involvement in autobiographical memory |
| Q50481884 | Crowded environments reduce spatial memory in older but not younger adults. |
| Q38241531 | Cues, context, and long-term memory: the role of the retrosplenial cortex in spatial cognition |
| Q33689375 | Default network deactivations are correlated with psychopathic personality traits. |
| Q48687256 | Developmental topographical disorientation and decreased hippocampal functional connectivity. |
| Q34216924 | Different "routes" to a cognitive map: dissociable forms of spatial knowledge derived from route and cartographic map learning |
| Q30574413 | Differential hippocampal and retrosplenial involvement in egocentric-updating, rotation, and allocentric processing during online spatial encoding: an fMRI study |
| Q48414305 | Differential parahippocampal and retrosplenial involvement in three types of visual scene recognition |
| Q34427601 | Differential recruitment of brain networks following route and cartographic map learning of spatial environments |
| Q46898178 | Differential recruitment of the hippocampus, medial prefrontal cortex, and the human motion complex during path integration in humans. |
| Q51887198 | Differentiated forgetting rates of spatial knowledge in humans in the absence of repeated testing. |
| Q57804012 | Dissociable neural systems for recognizing places and navigating through them |
| Q47228000 | Dissociable representations of environmental size and complexity in the human hippocampus |
| Q50140724 | Dissociating Landmark Stability from Orienting Value Using Functional Magnetic Resonance Imaging |
| Q36997424 | Dissociation between dorsal and ventral posterior parietal cortical responses to incidental changes in natural scenes |
| Q34780058 | Distances between real-world locations are represented in the human hippocampus |
| Q34216470 | Distinct contributions of human hippocampal theta to spatial cognition and anxiety |
| Q90389277 | Distinct representations of spatial and categorical relationships across human scene-selective cortex |
| Q42131317 | Distributed cognitive maps reflecting real distances between places and views in the human brain |
| Q51943166 | Does the cingulate cortex contribute to spatial conditional associative learning in the rat? |
| Q48099546 | Dorso-medial and ventro-lateral functional specialization of the human retrosplenial complex in spatial updating and orienting |
| Q90263957 | Effects of Exercise Modes on Neural Processing of Working Memory in Late Middle-Aged Adults: An fMRI Study |
| Q37060153 | Effects of a cognitive training on spatial learning and associated functional brain activations |
| Q42375121 | Efficacy of navigation may be influenced by retrosplenial cortex-mediated learning of landmark stability |
| Q37133603 | Egocentric spatial learning in schizophrenia investigated with functional magnetic resonance imaging |
| Q58578523 | Embodiment of Spatial Reference Frames and Individual Differences in Reference Frame Proclivity |
| Q48825540 | Environmental layout complexity affects neural activity during navigation in humans. |
| Q35205663 | Episodic encoding is more than the sum of its parts: an fMRI investigation of multifeatural contextual encoding |
| Q48124809 | Event-based prospective remembering in a virtual world |
| Q42521985 | Evidence for direct projections from the basal nucleus of the amygdala to retrosplenial cortex in the Macaque monkey |
| Q48943929 | Familiar environments enhance object and spatial memory in both younger and older adults. |
| Q48427077 | Fixed versus dynamic orientations in environmental learning from ground-level and aerial perspectives |
| Q33600904 | Focal lesions of human hippocampal CA1 neurons in transient global amnesia impair place memory. |
| Q45805755 | From allo- to egocentric spatial ability in early Alzheimer's disease: a study with virtual reality spatial tasks |
| Q46359829 | From details to large scale: the representation of environmental positions follows a granularity gradient along the human hippocampal and entorhinal anterior-posterior axis |
| Q48805276 | Functional connectivity between posterior hippocampus and retrosplenial complex predicts individual differences in navigational ability. |
| Q45033712 | Functional correlates of likelihood and prior representations in a virtual distance task |
| Q38252399 | Functional organization of the hippocampal longitudinal axis |
| Q91637390 | Gender Differences in Large-Scale and Small-Scale Spatial Ability: A Systematic Review Based on Behavioral and Neuroimaging Research |
| Q64258904 | Hippocampal and Retrosplenial Goal Distance Coding After Long-term Consolidation of a Real-World Environment |
| Q36949706 | Hippocampal size predicts rapid learning of a cognitive map in humans |
| Q37362464 | Hippocampus and retrosplenial cortex combine path integration signals for successful navigation. |
| Q48253987 | How does horizontal and vertical navigation influence spatial memory of multifloored environments? |
| Q58694794 | Human V2A: A map of the peripheral visual hemifield with functional connections to scene-selective cortex |
| Q34060050 | Human brain dynamics accompanying use of egocentric and allocentric reference frames during navigation |
| Q36976930 | Human hippocampal and parahippocampal theta during goal-directed spatial navigation predicts performance on a virtual Morris water maze |
| Q46556935 | Human neural systems underlying rigid and flexible forms of allocentric spatial representation |
| Q38377157 | Impact of the virtual reality on the neural representation of an environment |
| Q33818185 | Impaired head direction cell representation in the anterodorsal thalamus after lesions of the retrosplenial cortex. |
| Q33567882 | Individual Differences in Human Path Integration Abilities Correlate with Gray Matter Volume in Retrosplenial Cortex, Hippocampus, and Medial Prefrontal Cortex |
| Q38089197 | Is navigation in virtual reality with FMRI really navigation? |
| Q30597320 | It's not all in your car: functional and structural correlates of exceptional driving skills in professional racers |
| Q34069640 | Lateralized human hippocampal activity predicts navigation based on sequence or place memory |
| Q60046845 | Learned Spatial Schemas and Prospective Hippocampal Activity Support Navigation After One-Shot Learning |
| Q36222091 | Learning New Sensorimotor Contingencies: Effects of Long-Term Use of Sensory Augmentation on the Brain and Conscious Perception |
| Q34571927 | London taxi drivers and bus drivers: a structural MRI and neuropsychological analysis |
| Q48201717 | Macaque monkey retrosplenial cortex: III. Cortical efferents |
| Q46195535 | Maladaptive bias for extrahippocampal navigation strategies in aging humans |
| Q92534962 | Manipulating the visibility of barriers to improve spatial navigation efficiency and cognitive mapping |
| Q51035762 | Medial Parietal Cortex Encodes Perceived Heading Direction in Humans |
| Q51971594 | Memory for familiar environments learned in the remote past: fMRI studies of healthy people and an amnesic person with extensive bilateral hippocampal lesions. |
| Q34630809 | Memory transformation and systems consolidation |
| Q28274265 | Multiple reference frames used by the human brain for spatial perception and memory |
| Q35112847 | Navigation experience and mental representations of the environment: do pilots build better cognitive maps? |
| Q40385013 | Navigation performance in virtual environments varies with fractal dimension of landscape |
| Q38999665 | Navigation strategy training using virtual reality in six chronic stroke patients: A novel and explorative approach to the rehabilitation of navigation impairment |
| Q55208778 | Neural Codes for One's Own Position and Direction in a Real-World "Vista" Environment. |
| Q33498983 | Neural decoding of goal locations in spatial navigation in humans with fMRI. |
| Q27438139 | Neural dynamics of learning sound-action associations |
| Q51864201 | Neural encoding of objects relevant for navigation and resting state correlations with navigational ability. |
| Q30581040 | Neural evidence supports a novel framework for spatial navigation |
| Q49018284 | Neural network configuration and efficiency underlies individual differences in spatial orientation ability |
| Q55689980 | Neural signatures of reinforcement learning correlate with strategy adoption during spatial navigation. |
| Q35086682 | Neuropsychology of environmental navigation in humans: review and meta-analysis of FMRI studies in healthy participants. |
| Q36951954 | Ongoing egocentric spatial processing during learning of non-spatial information results in temporal-parietal activity during retrieval |
| Q28250027 | Origins of landmark encoding in the brain |
| Q36254109 | Outside Looking In: Landmark Generalization in the Human Navigational System |
| Q37257456 | Parahippocampal and retrosplenial contributions to human spatial navigation |
| Q30481692 | Parallel striatal and hippocampal systems for landmarks and boundaries in spatial memory |
| Q48123187 | Posterior parahippocampal place learning in H.M. |
| Q83229384 | Processing of different spatial scales in the human brain |
| Q38766470 | Quantifying the variability of scene-selective regions: Interindividual, interhemispheric, and sex differences. |
| Q28315025 | Rapid and independent memory formation in the parietal cortex |
| Q34153919 | Reference frames in virtual spatial navigation are viewpoint dependent |
| Q38463832 | Remote spatial memory in aging: all is not lost |
| Q59136347 | Resting State Connectivity Between Medial Temporal Lobe Regions and Intrinsic Cortical Networks Predicts Performance in a Path Integration Task |
| Q26784151 | Retrosplenial Cortex and Long-Term Memory: Molecules to Behavior |
| Q28285512 | Retrosplenial cortex (BA 29) volumes in behavioral variant frontotemporal dementia and Alzheimer's disease |
| Q63479700 | Retrosplenial cortex and its role in spatial cognition |
| Q21090871 | Retrosplenial cortex codes for permanent landmarks |
| Q90159246 | Retrosplenial cortex damage impairs unimodal sensory preconditioning |
| Q28264587 | Retrosplenial cortex maps the conjunction of internal and external spaces |
| Q33731125 | Right-lateralized brain oscillations in human spatial navigation |
| Q48725553 | Role of low- and high-frequency oscillations in the human hippocampus for encoding environmental novelty during a spatial navigation task |
| Q44747199 | Route and survey processing of topographical memory during navigation. |
| Q92935770 | Scene Perception in the Human Brain |
| Q46572095 | Segregating cognitive functions within hippocampal formation: a quantitative meta-analysis on spatial navigation and episodic memory |
| Q64078948 | Self‐reported navigation ability is associated with optic flow‐sensitive regions’ functional connectivity patterns during visual path integration |
| Q40412644 | Sensory Substitution: The Spatial Updating of Auditory Scenes "Mimics" the Spatial Updating of Visual Scenes |
| Q38878236 | Sex Hormones and Cognition: Neuroendocrine Influences on Memory and Learning |
| Q61449555 | Shared and Distinct Neural Bases of Large- and Small-Scale Spatial Ability: A Coordinate-Based Activation Likelihood Estimation Meta-Analysis |
| Q33817393 | Short-term EEG dynamics and neural generators evoked by navigational images |
| Q36097333 | Spatial and temporal episodic memory retrieval recruit dissociable functional networks in the human brain |
| Q37133698 | Spatial cognition and the brain |
| Q26774800 | Spatial navigation by congenitally blind individuals |
| Q37939294 | Spatial separation of visual and vestibular processing in the human hippocampal formation |
| Q37638343 | Spontaneous fast gamma activity in the septal hippocampal region correlates with spatial learning in humans |
| Q90140179 | Stable Encoding of Visual Cues in the Mouse Retrosplenial Cortex |
| Q37514446 | Structural and functional neural correlates of spatial navigation: a combined voxel-based morphometry and functional connectivity study |
| Q37555032 | Structural differences in hippocampal and prefrontal gray matter volume support flexible context-dependent navigation ability. |
| Q41829305 | Structural organization of long-range GABAergic projection system of the hippocampus |
| Q35994864 | Tactile exploration of virtual objects for blind and sighted people: the role of beta 1 EEG band in sensory substitution and supramodal mental mapping. |
| Q48132574 | The Aging Navigational System |
| Q34886120 | The brain-derived neurotrophic factor Val66Met polymorphism is associated with reduced functional magnetic resonance imaging activity in the hippocampus and increased use of caudate nucleus-dependent strategies in a human virtual navigation task |
| Q47875532 | The cognitive map in humans: spatial navigation and beyond |
| Q47887316 | The functional role of human right hippocampal/parahippocampal theta rhythm in environmental encoding during virtual spatial navigation. |
| Q41638570 | The occipital place area represents first-person perspective motion information through scenes |
| Q21131070 | The relationship of topographical memory performance to regional neurodegeneration in Alzheimer's disease |
| Q39114037 | The role of the hippocampus in navigation is memory |
| Q53424798 | The role of the right temporo-parietal junction in social decision-making. |
| Q48426170 | Topographical short-term memory differentiates Alzheimer's disease from frontotemporal lobar degeneration |
| Q38216113 | Toward a conceptualization of retrohippocampal contributions to learning and memory |
| Q92637389 | Vestibular processing during natural self-motion: implications for perception and action |
| Q34542197 | View-based organization and interplay of spatial working and long-term memories |
| Q34577992 | Visual scene processing in familiar and unfamiliar environments |
| Q41521073 | Wakeful rest promotes the integration of spatial memories into accurate cognitive maps |
| Q28260803 | What does the retrosplenial cortex do? |
| Q48144268 | Where am I now? Distinct roles for parahippocampal and retrosplenial cortices in place recognition. |
| Q39726901 | Which way and how far? Tracking of translation and rotation information for human path integration |
| Q92145748 | Which way is the bookstore? A closer look at the judgments of relative directions task |
| Q38387945 | Why vision is important to how we navigate |
Search more.