Dynamics of Mismatch Correction in the Hippocampal Ensemble Code for Space: Interaction between Path Integration and Environmental Cues

Gothard, Katalin M.; Skaggs, William E.; McNaughton, Bruce L.

doi:10.1523/jneurosci.16-24-08027.1996

Cited by 400 publications

(483 citation statements)

References 48 publications

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“…Firing fields were otherwise unaltered by such rigid rotations. This nearly ideal control of firing fields by specific stimuli is also in agreement with previous work (O'Keefe and Conway 1978; Muller and Kubie 1987; Sharp et al 1990; Gothard et al 1996; Cressant et al 1997). (c) The only effect of removing one card and rotating the other was to cause uniform rotations of all firing fields.…”

Section: Discussionsupporting

confidence: 92%

“…Additional studies by Sharp et al 1990 and Skaggs and McNaughton 1998 indicate that some place cells may have similar fields in two visually similar parts of an apparatus (in line with the combinatorial view), but that other cells may reliably fire in only one of the two regions, perhaps based on the use of position tracking by self-motion information (consistent with a spatial representation). Similar conclusions can be drawn from the study of Gothard et al 1996.…”

Section: Introductionsupporting

confidence: 85%

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Conjoint Control of Hippocampal Place Cell Firing by Two Visual Stimuli

Fenton

Csizmadia

Muller

2000

The Journal of General Physiology

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To better understand how hippocampal place cell activity is controlled by sensory stimuli, and to further elucidate the nature of the environmental representation provided by place cells, we have made recordings in the presence of two distinct visual stimuli under standard conditions and after several manipulations of these stimuli. In line with a great deal of earlier work, we find that place cell activity is constant when repeated recordings are made in the standard conditions in which the centers of the two stimuli, a black card and a white card, are separated by 135° on the wall of a cylindrical recording chamber. Rotating the two stimuli by 45° causes equal rotations of place cell firing fields. Removing either card and rotating the other card also causes fields to rotate equally, showing that the two stimuli are individually salient. Increasing or decreasing the card separation (card reconfiguration) causes a topological distortion of the representation of the cylinder floor such that field centers move relative to each other. We also found that either kind of reconfiguration induces a position-independent decrease in the intensity of place cell firing. We argue that these results are not compatible with either of two previously stated views of the place cell representation; namely, a nonspatial theory in which each place cell is tuned to an arbitrarily selected subset of available stimuli or a rigid map theory. We propose that our results imply that the representation is map-like but not rigid; it is capable of undergoing stretches without altering the local arrangement of firing fields.

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Section: Discussionsupporting

confidence: 92%

Section: Introductionsupporting

confidence: 85%

Conjoint Control of Hippocampal Place Cell Firing by Two Visual Stimuli

Fenton

Csizmadia

Muller

2000

The Journal of General Physiology

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“…On the neural level, these data have been related to the properties of place cells in the areas CA3-CA1 of the hippocampus, since their firing fields develop during unrewarded exploration (Hill, 1978;Wilson & McNaughton, 1993), persist in darkness (Quirk, Muller, & Kubie, 1990), and depend on multiple sensory stimuli (Gothard et al, 1996;O'Keefe & Burgess, 1996).…”

Section: Spatial Representationmentioning

confidence: 99%

Is there a geometric module for spatial orientation? Insights from a rodent navigation model.

Sheynikhovich¹,

Chavarriaga²,

Strösslin³

et al. 2009

Psychological Review

102

145

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Modern psychological theories of spatial cognition postulate the existence of a geometric module for reorientation. This concept is derived from experimental data showing that in rectangular arenas with distinct landmarks in the corners, disoriented rats often make diagonal errors, suggesting their preference for the geometric (arena shape) over the nongeometric (landmarks) cues. Moreover, sensitivity of hippocampal cell firing to changes in the environment layout was taken in support of the geometric module hypothesis. Using a computational model of rat navigation, the authors proposed and tested the alternative hypothesis that the influence of spatial geometry on both behavioral and neuronal levels can be explained by the properties of visual features that constitute local views of the environment. Their modeling results suggest that the pattern of diagonal errors observed in reorientation tasks can be understood by the analysis of sensory information processing that underlies the navigation strategy employed to solve the task. In particular, 2 navigation strategies were considered: (a) a place-based locale strategy that relies on a model of grid and place cells and (b) a stimulus-response taxon strategy that involves direct association of local views with action choices. The authors showed that the application of the 2 strategies in the reorientation tasks results in different patterns of diagonal errors, consistent with behavioral data. These results argue against the geometric module hypothesis by providing a simpler and biologically more plausible explanation for the related experimental data. Moreover, the same model also describes behavioral results in different types of water-maze tasks.

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“…Interestingly, spatial cues are sometimes represented discretely: on a linear track, cells differentiate the two directions of travel [67,101,109,174]. However, when allowed to experience all directions without limitations (such as when foraging within an open environment), cells do not show any directional dependence at all [101,128,130].…”

Section: Differences Between Spatial and Non-spatial Correlatesmentioning

confidence: 99%

“…On other alternation tasks (such as back-and-forth along a linear track, i.e. alternating directions), cells differentiate the two directions [67,101,109,174].…”

Section: The Delayed-non-match-to-sample Taskmentioning

confidence: 99%

The hippocampal debate: are we asking the right questions?

Redish

2001

Behavioural Brain Research

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For years, the debate has been: 'Is the hippocampus the cognitive map?' or 'Is the hippocampus the core of memory?' These two hypotheses derived their original power from two key experiments-the cognitive map theory from the remarkable spatial correlates seen in recordings of hippocampal pyramidal cells and the memory theory from the profound amnesias seen in the patient H.M. Both of these key experiments have been reinterpreted over the years: hippocampal cells are correlated with much more than place and H.M. is missing much more than just his hippocampus. However, both theories are still debated today. The hippocampus clearly plays a role in both navigation and memory processing. The question that must be addressed is rather: 'What is the role played by the hippocampus in the navigation and memory systems?' By looking at the navigation system as a whole, one can identify the major role played by the hippocampus as correcting for accumulation errors that occur within idiothetic navigation systems. This is most clearly experimentally evident as reorientation when an animal is lost. Carrying this over to a more general process, this becomes a role of recalling a context, bridging a contextual gap, or, in other words, it becomes a form of recognition memory. I will review recent experimental data which seems to support this theory over the more general spatial or memory theories traditionally applied to hippocampus.

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Dynamics of Mismatch Correction in the Hippocampal Ensemble Code for Space: Interaction between Path Integration and Environmental Cues

Cited by 400 publications

References 48 publications

Conjoint Control of Hippocampal Place Cell Firing by Two Visual Stimuli

Conjoint Control of Hippocampal Place Cell Firing by Two Visual Stimuli

Is there a geometric module for spatial orientation? Insights from a rodent navigation model.

The hippocampal debate: are we asking the right questions?

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