Complementary Roles of Human Hippocampal Subfields in Differentiation and Integration of Spatial Context

Stokes, Jared; Kyle, Colin T.; Ekstrom, Arne D.

doi:10.1162/jocn_a_00736

Cited by 68 publications

(99 citation statements)

References 73 publications

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“…Although it is infeasible to register place cell activity in humans using fMRI, given that the distribution of place cells in rodent hippocampus is nontopographic with respect to the spatial distribution of their firing fields [37], the aforementioned rodent place cell pattern shows striking similarities with our data. Our data are consistent with the absence of sigmoidal neural response patterns in the human hippocampus when participants view highly similar visual scenes [38,39] and a linear scaling of hippocampal responses with changes in the configuration of landmarks in four virtual environments [40]. The attractor-like behavior of place cells also accords with observations in rodents that repeated exposure to less-distinct environments is accompanied by a slower, gradual development of distinct place cell representations [41].…”

Section: Discussionsupporting

confidence: 89%

Hippocampal Attractor Dynamics Predict Memory-Based Decision Making

Steemers

Vicente-Grabovetsky

Barry³

et al. 2016

Current Biology

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Memories are thought to be retrieved by attractor dynamics if a given input is sufficiently similar to a stored attractor state [1-5]. The hippocampus, a region crucial for spatial navigation [6-12] and episodic memory [13-18], has been associated with attractor-based computations [5, 9], receiving support from the way rodent place cells "remap" nonlinearly between spatial representations [19-22]. In humans, nonlinear response patterns have been reported in perceptual categorization tasks [23-25]; however, it remains elusive whether human memory retrieval is driven by attractor dynamics and what neural mechanisms might underpin them. To test this, we used a virtual reality [7, 11, 26-28] task where participants learned object-location associations within two distinct virtual reality environments. Participants were subsequently exposed to four novel intermediate environments, generated by linearly morphing the background landscapes of the familiar environments, while tracking fMRI activity. We show that linear changes in environmental context cause linear changes in activity patterns in sensory cortex but cause dynamic, nonlinear changes in both hippocampal activity pattern and remembered locations. Furthermore, the sigmoidal response in the hippocampus scaled with the strength of the sigmoidal pattern in spatial memory. These results indicate that mnemonic decisions in an ambiguous novel context relate to putative attractor dynamics in the hippocampus, which support the dynamic remapping of memories.

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Section: Discussionsupporting

confidence: 89%

Hippocampal Attractor Dynamics Predict Memory-Based Decision Making

Steemers

Vicente-Grabovetsky

Barry³

et al. 2016

Current Biology

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“…This unified account of spatial context, temporal context and spatiotemporal context aligns well with recent fMRI studies virtual reality suggesting not only that similar regions participate in recovery of spatial and temporal context [66, 67, 64] (see also Fig. 2B).…”

Section: Advances In the Theory Of Temporal And Spatial Contextsupporting

confidence: 88%

Temporal and spatial context in the mind and brain

Howard

2017

Current Opinion in Behavioral Sciences

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Theories of episodic memory have long hypothesized that recollection of a specific instance from one’s life is mediated by recovery of a neural state of spatiotemporal context. This paper reviews recent theoretical advances in formal models of spatiotemporal context and a growing body of neurophysiological evidence from human imaging studies and animal work that neural populations in the hippocampus and other brain regions support a representation of spatiotemporal context.

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“…Overall, convergent data have suggested that CA3 is capable of exhibiting pattern completion or pattern separation, depending on the magnitude of the change in sensory input. The CA1 subfield generally appears to respond linearly to incremental changes in sensory input; however, under some conditions it may respond with an abrupt nonlinear change, perhaps reflecting a switch in its dominant input from the entorhinal cortex to CA3 18–20 (but see Stokes et al 21 ). This could be a result of explicit task influences or the requirement for a mnemonic judgment instead of free exploration 19,22 .…”

Section: Empirical Evidence For Pattern Separation In the Hippocampusmentioning

confidence: 99%

Integrating new findings and examining clinical applications of pattern separation

2018

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Pattern separation, the ability to independently represent and store similar experiences, is a crucial facet of episodic memory. Growing evidence suggests that the hippocampus possesses unique circuitry that is computationally capable of resolving mnemonic interference by using pattern separation. In this Review, we discuss recent advances in the understanding of this process and evaluate the caveats and limitations of linking across animal and human studies. We summarize clinical and translational studies using methods that are sensitive to pattern separation impairments, an approach that stems from the fact that the hippocampus is a major site of disruption in many brain disorders. We critically evaluate the assumptions that guide fundamental and translational studies in this area. Finally, we suggest guidelines for future research and offer ways to overcome potential interpretational challenges to increase the utility of pattern separation as a construct that can further understanding of both memory processes and brain disease.

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Complementary Roles of Human Hippocampal Subfields in Differentiation and Integration of Spatial Context

Cited by 68 publications

References 73 publications

Hippocampal Attractor Dynamics Predict Memory-Based Decision Making

Hippocampal Attractor Dynamics Predict Memory-Based Decision Making

Temporal and spatial context in the mind and brain

Integrating new findings and examining clinical applications of pattern separation

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