Access the full text.
Sign up today, get DeepDyve free for 14 days.
S. Wiener, V. Korshunov, R. Garcia, A. Berthoz (1995)
Inertial, Substratal and Landmark Cue Control of Hippocampal CA1 Place Cell ActivityEuropean Journal of Neuroscience, 7
L. Swanson, P. Sawchenko, W. Cowan (1980)
Evidence that the commissural, associational and septal projections of the regio inferior of the hippocampus arise from the same neuronsBrain Research, 197
R. O’Reilly, James McClelland (1994)
Hippocampal conjunctive encoding, storage, and recall: Avoiding a trade‐offHippocampus, 4
A. Lavoie, S.J.Y. Mizumori (1994)
Spatial, movement- and reward-sensitive discharge by medial ventral striatum neurons of ratsBrain Research, 638
L. Swanson, P. Sawchenko, W. Cowan (1981)
Evidence for collateral projections by neurons in Ammon's horn, the dentate gyrus, and the subiculum: a multiple retrograde labeling study in the rat, 1
(1985)
Cognitive maps and environmental context
S. Wiener, C. Paul, H. Eichenbaum, Neal Cohen, Matthew Shapiro, Nestor Schmajuk, Cindy (1989)
Spatial and behavioral correlates of hippocampal neuronal activity.The Journal of neuroscience : the official journal of the Society for Neuroscience, 9 8
LT Chen, L‐H Lin, Green, CA Barnes, BL McNaughton (1994)
Head‐direction cells in the rat posterior cortex I. anatomical distribution and behavioral modulation, 101
BL McNaughton, CA Barnes, J O'Keefe (1983)
The contributions of position, direction and velocity to single unit activity in the hippocampus of freely‐moving rat, 52
S. Mizumori, B. Mcnaughton, C. Barnes, K. Fox (1989)
Preserved spatial coding in hippocampal CA1 pyramidal cells during reversible suppression of CA3c output: evidence for pattern completion in hippocampus, 9
E. Markus, Yu Qin, B. Leonard, W. Skaggs, B. McNaughton, C. Barnes (1995)
Interactions between location and task affect the spatial and directional firing of hippocampal neurons, 15
J. O’Keefe, N. Burgess (1996)
Geometric determinants of the place fields of hippocampal neuronsNature, 381
D. Olton, J. Becker, G. Handelmann (1979)
Hippocampus, space, and memoryBehavioral and Brain Sciences, 2
W. Pratt, S. Mizumori (1998)
Characteristics of basolateral amygdala neuronal firing on a spatial memory task involving differential reward.Behavioral neuroscience, 112 3
(1998)
Complementary roles of caudate and hippocampus during navigation: evidence from parallel single unit recordings
S. O'Mara, E. Rolls, A. Berthoz, R. Kesner (1994)
Neurons responding to whole-body motion in the primate hippocampus, 14
R. Hampson, C. Heyser, S. Deadwyler (1993)
Hippocampal cell firing correlates of delayed-match-to-sample performance in the rat.Behavioral neuroscience, 107 5
J. O’Keefe (1976)
Place units in the hippocampus of the freely moving ratExperimental Neurology, 51
S.J.Y. Mizumori, A. Kalyani (1997)
Age and Experience-Dependent Representational Reorganization During Spatial LearningNeurobiology of Aging, 18
J. Taube (1995)
Head direction cells recorded in the anterior thalamic nuclei of freely moving rats, 15
R. Kesner (1991)
Neurobiological Views of Memory
SJY Mizumori, A Kalyani (1997)
Age and experience‐dependent reorganization during spatial learning, 18
M. Wilson, S. Tonegawa (1997)
Synaptic plasticity, place cells and spatial memory: study with second generation knockoutsTrends in Neurosciences, 20
(1995)
Spatial representations of dorsal caudate neurons of freely-behaing rats
A. Samsonovich, B. McNaughton (1997)
Path Integration and Cognitive Mapping in a Continuous Attractor Neural Network ModelThe Journal of Neuroscience, 17
M. Merzenich, R. DeCharms (1996)
Neural representations, experience, and change.
WE Skaggs, BL McNaughton, KM Gothard, EF Markus (1993)
Advances in neural information processing systems
JJ Knierim, HS Kudrimoti, B. Mcnaughton (1995)
Place cells, head direction cells, and the learning of landmark stability, 15
C. Barnes, B. McNaughton, S. Mizumori, Brian Leonard, Lin Lin (1990)
Comparison of spatial and temporal characteristics of neuronal activity in sequential stages of hippocampal processing.Progress in brain research, 83
K. Gothard, W. Skaggs, B. McNaughton (1996)
Dynamics of Mismatch Correction in the Hippocampal Ensemble Code for Space: Interaction between Path Integration and Environmental CuesThe Journal of Neuroscience, 16
O. Paulsen, E. Moser (1998)
A model of hippocampal memory encoding and retrieval: GABAergic control of synaptic plasticityTrends in Neurosciences, 21
E. Rolls (1996)
A theory of hippocampal function in memoryHippocampus, 6
LR Squire, NJ Cohen, L Nadel (1984)
Memory consolidation
L. Squire, N. Cohen, L. Nadel (2014)
The medial temporal region and memory consolidation: A new hypothesis
M. Wilson, B. McNaughton (1993)
Dynamics of the hippocampal ensemble code for space.Science, 261 5124
S. Mizumori, JD Williams (1993)
Directionally selective mnemonic properties of neurons in the lateral dorsal nucleus of the thalamus of rats, 13
R. Llinás, P. Churchland (1996)
The Mind-Brain Continuum: Sensory Processes
P. Hetherington, Matthew Shapiro (1997)
Hippocampal place fields are altered by the removal of single visual cues in a distance-dependent manner.Behavioral neuroscience, 111 1
R. Vertes, A. Crane, L. Colom, B. Bland (1995)
Ascending projections of the posterior nucleus of the hypothalamus: PHA‐L analysis in the ratJournal of Comparative Neurology, 359
J. Feigenbaum, E. Rolls (1991)
Allocentric and egocentric spatial information processing in the hippocampal formation of the behaving primatePsychobiology
G. Wallenstein, M. Hasselmo (1997)
GABAergic modulation of hippocampal population activity: sequence learning, place field development, and the phase precession effect.Journal of neurophysiology, 78 1
S. Mizumori, A. Lavoie, Anjali Kalyani (1996)
Redistribution of spatial representation in the hippocampus of aged rats performing a spatial memory task.Behavioral neuroscience, 110 5
R. Muller, J. Kubie (1987)
The effects of changes in the environment on the spatial firing of hippocampal complex-spike cells, 7
P. Sharp (1997)
Subicular cells generate similar spatial firing patterns in two geometrically and visually distinctive environments: Comparison with hippocampal place cellsBehavioural Brain Research, 85
S. Wiener, V. Korshunov (1995)
Place-independent behavioural correlates of hippocampal neurones in ratsNeuroReport, 7
J. Martinez, R. Kesner (1986)
Learning and memory : a biological view
J. Rawlins (1985)
Associations across time: The hippocampus as a temporary memory storeBehavioral and Brain Sciences, 8
G. Wallenstein, M. Hasselmo, H. Eichenbaum (1998)
The hippocampus as an associator of discontiguous eventsTrends in Neurosciences, 21
B. Cooper, D. Miya, S.J.Y. Mizumori (1998)
Superior colliculus and active navigation: Role of visual and non‐visual cues in controlling cellular representations of spaceHippocampus, 8
R. Vertes (1992)
PHA‐L analysis of projections from the supramammillary nucleus in the ratJournal of Comparative Neurology, 326
B. McNaughton, C. Barnes, J. Gerrard, K. Gothard, M. Jung, J. Knierim, H. Kudrimoti, Yu Qin, W. Skaggs, M. Suster, K. Weaver (1996)
Deciphering the hippocampal polyglot: the hippocampus as a path integration system.The Journal of experimental biology, 199 Pt 1
W. Skaggs, B. McNaughton, K. Gothard (1992)
An Information-Theoretic Approach to Deciphering the Hippocampal Code
P. Balsam, A. Tomie (1985)
Context and Learning
The hippocampus appears to undergo continual representational reorganization as animals navigate their environments. This reorganization is postulated to be reflected spatially in terms of changes in the ensemble of place cells activated, as well as changes in place field specificity and reliability for cells recorded in both hilar/CA3 and CA1 regions. The specific contribution of the hilar/CA3 region is suggested to be to compare the expected spatial context with that currently being experienced, then relay discrepancies to CA1. The properties of CA1 place fields in part reflect the spatial comparisons made in the hilar/CA3 area. In addition, CA1 organizes the input received from the hilar/CA3 place cells according to different temporal algorithms that are unique to different tasks. In this way, hippocampus helps to distinguish temporally one spatial context from another, thereby contributing to episodic memories. Hippocampus 1999;9:444–451. © 1999 Wiley‐Liss, Inc.
Hippocampus – Wiley
Published: Jan 1, 1999
Keywords: ; ;
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.