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3. Pattern Separation in the Human Hippocampus: Response to Quiroga.

Author

Suthana, Nanthia, Ekstrom, Arne D, Yassa, Michael A, and Stark, Craig

Subjects
Hippocampus, Humans, Memory, Episodic, concept cells, episodic memory, human hippocampus, single-neuron recordings, Information and Computing Sciences, Medical and Health Sciences, Psychology and Cognitive Sciences, Experimental Psychology
Published
2021

5. Early Intervention via Stimulation of the Medial Septal Nucleus Improves Cognition and Alters Markers of Epileptogenesis in Pilocarpine-Induced Epilepsy

Author

Izadi, Ali, Schedlbauer, Amber, Ondek, Katelynn, Disse, Gregory, Ekstrom, Arne D, Cowen, Stephen L, Shahlaie, Kiarash, and Gurkoff, Gene G

Subjects
Biological Psychology, Biomedical and Clinical Sciences, Psychology, Epilepsy, Neurosciences, Neurodegenerative, Brain Disorders, Behavioral and Social Science, 2.1 Biological and endogenous factors, Neurological, deep brain stimulation, temporal lobe epilepsy, theta oscillations, cognition, pilocarpine, Clinical Sciences, Clinical sciences, Biological psychology
Abstract

Over one-third of patients with temporal lobe epilepsy are refractory to medication. In addition, anti-epileptic drugs often exacerbate cognitive comorbidities. Neuromodulation is an FDA treatment for refractory epilepsy, but patients often wait >20 years for a surgical referral for resection or neuromodulation. Using a rodent model, we test the hypothesis that 2 weeks of theta stimulation of the medial septum acutely following exposure to pilocarpine will alter the course of epileptogenesis resulting in persistent behavioral improvements. Electrodes were implanted in the medial septum, dorsal and ventral hippocampus, and the pre-frontal cortex of pilocarpine-treated rats. Rats received 30 min/day of 7.7 Hz or theta burst frequency on days 4-16 post-pilocarpine, prior to the development of spontaneous seizures. Seizure threshold, spikes, and oscillatory activity, as well as spatial and object-based learning, were assessed in the weeks following stimulation. Non-stimulated pilocarpine animals exhibited significantly decreased seizure threshold, increased spikes, and cognitive impairments as compared to vehicle controls. Furthermore, decreased ventral hippocampal power (6-10 Hz) correlated with both the development of spikes and impaired cognition. Measures of spikes, seizure threshold, and cognitive performance in both acute 7.7 Hz and theta burst stimulated animals were statistically similar to vehicle controls when tested during the chronic phase of epilepsy, weeks after stimulation was terminated. These data indicate that modulation of the septohippocampal circuit early after pilocarpine treatment alters the progression of epileptic activity, resulting in elevated seizure thresholds, fewer spikes, and improved cognitive outcome. Results from this study support that septal theta stimulation has the potential to serve in combination or as an alternative to high frequency thalamic stimulation in refractory cases and that further research into early intervention is critical.

Published
2021

7. The role of the fornix in human navigational learning

Author

Hodgetts, Carl J, Stefani, Martina, Williams, Angharad N, Kolarik, Branden S, Yonelinas, Andrew P, Ekstrom, Arne D, Lawrence, Andrew D, Zhang, Jiaxiang, and Graham, Kim S

Subjects
Biological Psychology, Psychology, Biomedical Imaging, Clinical Research, Mental Health, Behavioral and Social Science, Mental health, Animals, Diffusion Magnetic Resonance Imaging, Fornix, Brain, Hippocampus, Humans, Memory, Episodic, White Matter, Spatial navigation, Spatial learning, Episodic memory, Diffusion MRI, Neurosciences, Cognitive Sciences, Experimental Psychology, Biological psychology, Cognitive and computational psychology
Abstract

Experiments on rodents have demonstrated that transecting the white matter fibre pathway linking the hippocampus with an array of cortical and subcortical structures - the fornix - impairs flexible navigational learning in the Morris Water Maze (MWM), as well as similar spatial learning tasks. While diffusion magnetic resonance imaging (dMRI) studies in humans have linked inter-individual differences in fornix microstructure to episodic memory abilities, its role in human spatial learning is currently unknown. We used high-angular resolution diffusion MRI combined with constrained spherical deconvolution-based tractography, to ask whether inter-individual differences in fornix microstructure in healthy young adults would be associated with spatial learning in a virtual reality navigation task. To efficiently capture individual learning across trials, we adopted a novel curve fitting approach to estimate a single index of learning rate. We found a statistically significant correlation between learning rate and the microstructure (mean diffusivity) of the fornix, but not that of a comparison tract linking occipital and anterior temporal cortices (the inferior longitudinal fasciculus, ILF). Further, this correlation remained significant when controlling for both hippocampal volume and participant gender. These findings extend previous animal studies by demonstrating the functional relevance of the fornix for human spatial learning in a virtual reality environment, and highlight the importance of a distributed neuroanatomical network, underpinned by key white matter pathways, such as the fornix, in complex spatial behaviour.

Published
2020

8. Precision, binding, and the hippocampus: Precisely what are we talking about?

Author

Ekstrom, Arne D and Yonelinas, Andrew P

Subjects
Biological Psychology, Cognitive and Computational Psychology, Psychology, Neurosciences, Behavioral and Social Science, Mental Health, 1.2 Psychological and socioeconomic processes, 1.1 Normal biological development and functioning, Underpinning research, Mental health, Good Health and Well Being, Hippocampus, Humans, Memory, Episodic, Memory, Short-Term, Nerve Net, Space Perception, Time Perception, Episodic memory, Spatiotemporal context, Perception, Working memory, Network neuroscience, Cognitive Sciences, Experimental Psychology, Biological psychology, Cognitive and computational psychology
Abstract

Endel Tulving's proposal that episodic memory is distinct from other memory systems like semantic memory remains an extremely influential idea in cognitive neuroscience research. As originally suggested by Tulving, episodic memory involves three key components that differentiate it from all other memory systems: spatiotemporal binding, mental time travel, and autonoetic consciousness. Here, we focus on the idea of spatiotemporal binding in episodic memory and, in particular, how consideration of the precision of spatiotemporal context helps expand our understanding of episodic memory. Precision also helps shed light on another key issue in cognitive neuroscience, the role of the hippocampus outside of episodic memory in perception, attention, and working memory. By considering precision alongside item-context bindings, we attempt to shed new light on both the nature of how we represent context and what roles the hippocampus plays in episodic memory and beyond.

Published
2020

11. Recovery of Theta Frequency Oscillations in Rats Following Lateral Fluid Percussion Corresponds With a Mild Cognitive Phenotype

Author

Ondek, Katelynn, Pevzner, Aleksandr, Tercovich, Kayleen, Schedlbauer, Amber M, Izadi, Ali, Ekstrom, Arne D, Cowen, Stephen L, Shahlaie, Kiarash, and Gurkoff, Gene G

Subjects
Biological Psychology, Biomedical and Clinical Sciences, Neurosciences, Psychology, Basic Behavioral and Social Science, Rehabilitation, Traumatic Brain Injury (TBI), Behavioral and Social Science, Brain Disorders, Physical Injury - Accidents and Adverse Effects, Traumatic Head and Spine Injury, Injuries and accidents, Neurological, spatial learning, traumatic brain injury, theta oscillations, biomarker, in vivo electrophysiology, phase coherence, Clinical Sciences, Clinical sciences, Biological psychology
Abstract

Whether from a fall, sports concussion, or even combat injury, there is a critical need to identify when an individual is able to return to play or work following traumatic brain injury (TBI). Electroencephalogram (EEG) and local field potentials (LFP) represent potential tools to monitor circuit-level abnormalities related to learning and memory: specifically, theta oscillations can be readily observed and play a critical role in cognition. Following moderate traumatic brain injury in the rat, lasting changes in theta oscillations coincide with deficits in spatial learning. We hypothesized, therefore, that theta oscillations can be used as an objective biomarker of recovery, with a return of oscillatory activity corresponding with improved spatial learning. In the current study, LFP were recorded from dorsal hippocampus and anterior cingulate in awake, behaving adult Sprague Dawley rats in both a novel environment on post-injury days 3 and 7, and Barnes maze spatial navigation on post-injury days 8-11. Theta oscillations, as measured by power, theta-delta ratio, peak theta frequency, and phase coherence, were significantly altered on day 3, but had largely recovered by day 7 post-injury. Injured rats had a mild behavioral phenotype and were not different from shams on the Barnes maze, as measured by escape latency. Injured rats did use suboptimal search strategies. Combined with our previous findings that demonstrated a correlation between persistent alterations in theta oscillations and spatial learning deficits, these new data suggest that neural oscillations, and particularly theta oscillations, have potential as a biomarker to monitor recovery of brain function following TBI. Specifically, we now demonstrate that oscillations are depressed following injury, but as oscillations recover, so does behavior.

Published
2020

12. A contextual binding theory of episodic memory: systems consolidation reconsidered

Author

Yonelinas, Andrew P, Ranganath, Charan, Ekstrom, Arne D, and Wiltgen, Brian J

Subjects
Biological Psychology, Psychology, Neurosciences, Sleep Research, Underpinning research, 1.1 Normal biological development and functioning, Mental health, Animals, Hippocampus, Humans, Memory, Episodic, Mental Recall, Sleep, Cognitive Sciences, Neurology & Neurosurgery, Biological psychology
Abstract

Episodic memory reflects the ability to recollect the temporal and spatial context of past experiences. Episodic memories depend on the hippocampus but have been proposed to undergo rapid forgetting unless consolidated during offline periods such as sleep to neocortical areas for long-term storage. Here, we propose an alternative to this standard systems consolidation theory (SSCT) - a contextual binding account - in which the hippocampus binds item-related and context-related information. We compare these accounts in light of behavioural, lesion, neuroimaging and sleep studies of episodic memory and contend that forgetting is largely due to contextual interference, episodic memory remains dependent on the hippocampus across time, contextual drift produces post-encoding activity and sleep benefits memory by reducing contextual interference.

Published
2019

14. Age differences in spatial memory are mitigated during naturalistic navigation.

Author

Hill, Paul F., Bermudez, Skyelynn, McAvan, Andrew S., Garren, Joshua D., Grilli, Matthew D., Barnes, Carol A., and Ekstrom, Arne D.

Subjects
AGE differences, SPATIAL memory, OLDER people, VIRTUAL reality, ANIMAL locomotion
Abstract

Spatial navigation deficits are often observed among older adults on tasks that require navigating virtual reality (VR) environments on a computer screen. We investigated whether these age differences are attenuated when tested in more naturalistic and ambulatory virtual environments. In Experiment 1, young and older adults navigated a variant of the Morris Water Maze task in each of two VR conditions: a desktop VR condition which required using a mouse and keyboard to navigate, and an ambulatory VR condition which permitted unrestricted locomotion. In Experiment 2, we examined whether age- and VR-related differences in spatial performance were affected by the inclusion of additional spatial cues. In both experiments, older adults navigated to target locations less precisely than younger individuals in the desktop condition. Age differences were significantly attenuated, however, when tested in the ambulatory VR environment. These findings underscore the importance of developing naturalistic assessments of spatial memory and navigation. [ABSTRACT FROM AUTHOR]

Published
2024
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15. Rightward and leftward biases in temporal reproduction of objects represented in central and peripheral spaces.

Author

Isham, Eve A, Le, Cong-Huy, and Ekstrom, Arne D

Subjects
Humans, Time Perception, Visual Perception, Fixation, Ocular, Time Factors, Adolescent, Adult, Female, Male, Young Adult, Spatial Processing, Behavioral Science & Comparative Psychology, Medical and Health Sciences, Psychology and Cognitive Sciences
Abstract

The basis for how we represent temporal intervals in memory remains unclear. One proposal, the mental time line theory (MTL), posits that our representation of temporal duration depends on a horizontal mental time line, thus suggesting that the representation of time has an underlying spatial component. Recent work suggests that the MTL is a learned strategy, prompting new questions of when and why MTL is used to represent temporal duration, and whether time is always represented spatially. The current study examines the hypothesis that the MTL may be a time processing strategy specific to centrally-located stimuli. In two experiments (visual eccentricity and prismatic adaptation procedures), we investigated the magnitude of the rightward bias, an index of the MTL, in central and peripheral space. When participants performed a supra-second temporal interval reproduction task, we observed a rightward bias only in central vision (within 3° visual angle), but not in the peripheral space (approximately 6-8° visual angle). Instead, in the periphery, we observed a leftward bias. The results suggest that the MTL may be a learned strategy specific to central space and that strategies for temporal interval estimation that do not depend on MTL may exist for stimuli perceived peripherally.

Published
2018

18. CA1 and CA3 differentially support spontaneous retrieval of episodic contexts within human hippocampal subfields.

Author

Dimsdale-Zucker, Halle R, Ritchey, Maureen, Ekstrom, Arne D, Yonelinas, Andrew P, and Ranganath, Charan

Subjects
Humans, Magnetic Resonance Imaging, Brain Mapping, Mental Recall, Space Perception, Female, Male, Young Adult, CA1 Region, Hippocampal, CA3 Region, Hippocampal, Memory, Episodic, Dementia, Clinical Research, Neurodegenerative, Alzheimer's Disease, Aging, Neurosciences, Alzheimer's Disease including Alzheimer's Disease Related Dementias (AD/ADRD), Acquired Cognitive Impairment, Mental Health, Brain Disorders, 1.2 Psychological and socioeconomic processes, 1.1 Normal biological development and functioning, CA1 Region, Hippocampal, CA3 Region, Memory, Episodic
Abstract

The hippocampus plays a critical role in spatial and episodic memory. Mechanistic models predict that hippocampal subfields have computational specializations that differentially support memory. However, there is little empirical evidence suggesting differences between the subfields, particularly in humans. To clarify how hippocampal subfields support human spatial and episodic memory, we developed a virtual reality paradigm where participants passively navigated through houses (spatial contexts) across a series of videos (episodic contexts). We then used multivariate analyses of high-resolution fMRI data to identify neural representations of contextual information during recollection. Multi-voxel pattern similarity analyses revealed that CA1 represented objects that shared an episodic context as more similar than those from different episodic contexts. CA23DG showed the opposite pattern, differentiating between objects encountered in the same episodic context. The complementary characteristics of these subfields explain how we can parse our experiences into cohesive episodes while retaining the specific details that support vivid recollection.

Published
2018

19. Close but no cigar: Spatial precision deficits following medial temporal lobe lesions provide novel insight into theoretical models of navigation and memory

Author

Kolarik, Branden S, Baer, Trevor, Shahlaie, Kiarash, Yonelinas, Andrew P, and Ekstrom, Arne D

Subjects
Biological Psychology, Psychology, Neurosciences, Clinical Research, Behavioral and Social Science, Mental Health, 1.2 Psychological and socioeconomic processes, Underpinning research, 1.1 Normal biological development and functioning, Mental health, Neurological, Adult, Amnesia, Female, Hippocampus, Humans, Male, Maze Learning, Middle Aged, Models, Neurological, Models, Psychological, Spatial Memory, Spatial Navigation, Temporal Lobe, Lesions, Medial Temporal Lobe, Cognitive Sciences, Neurology & Neurosurgery, Biological psychology
Abstract

Increasing evidence suggests that the human hippocampus contributes to a range of different behaviors, including episodic memory, language, short-term memory, and navigation. A novel theoretical framework, the Precision and Binding Model, accounts for these phenomenon by describing a role for the hippocampus in high-resolution, complex binding. Other theories like Cognitive Map Theory, in contrast, predict a specific role for the hippocampus in allocentric navigation, while Declarative Memory Theory predicts a specific role in delay-dependent conscious memory. Navigation provides a unique venue for testing these predictions, with past results from research with humans providing inconsistent findings regarding the role of the human hippocampus in spatial navigation. Here, we tested five patients with lesions primarily restricted to the hippocampus and those extending out into the surrounding medial temporal lobe cortex on a virtual water maze task. Consistent with the Precision and Binding Model, we found partially intact allocentric memory in all patients, with impairments in the spatial precision of their searches for a hidden target. We found similar impairments at both immediate and delayed testing. Our findings are consistent with the Precision and Binding Model of hippocampal function, arguing for its role across domains in high-resolution, complex binding.Significance statementRemembering goal locations in one's environment is a critical skill for survival. How this information is represented in the brain is still not fully understood, but is believed to rely in some capacity on structures in the medial temporal lobe. Contradictory findings from studies of both humans and animals have been difficult to reconcile with regard to the role of the MTL, specifically the hippocampus. By assessing impairments observed during navigation to a goal in patients with medial temporal lobe damage we can better understand the role these structures play in such behavior. Utilizing virtual reality and novel analysis techniques, we have more precisely assessed the impact that medial temporal lobe damage has on spatial memory and navigation.

Published
2018

20. Human spatial navigation: Representations across dimensions and scales.

Author

Ekstrom, Arne D and Isham, Eve A

Subjects
Spatial navigation, allocentric, egocentric, electrophysiology, fMRI, hippocampus, lesion, neurophysiology, non-human primate, parahipopcampal cortex, place cell, retrosplenial cortex, rodent, virtual reality
Abstract

Humans, like many other species, employ three fundamental forms of strategies to navigate: allocentric, egocentric, and beacon. Here, we review each of these different forms of navigation with a particular focus on how our high-resolution visual system contributes to their unique properties. We also consider how we might employ allocentric and egocentric representations, in particular, across different spatial dimensions, such as 1-D vs. 2-D. Our high acuity visual system also leads to important considerations regarding the scale of space we are navigating (e.g., smaller, room-sized "vista" spaces or larger city-sized "environmental" spaces). We conclude that a hallmark of human spatial navigation is our ability to employ these representations systems in a parallel and flexible manner, which differ both as a function of dimension and spatial scale.

Published
2017

21. Low-frequency theta oscillations in the human hippocampus during real-world and virtual navigation.

Author

Bohbot, Véronique D, Copara, Milagros S, Gotman, Jean, and Ekstrom, Arne D

Subjects
Hippocampus, Temporal Lobe, Humans, Electroencephalography, Theta Rhythm, Electrodes, Implanted, Electrophysiology, Periodicity, Movement, User-Computer Interface, Adolescent, Adult, Middle Aged, Female, Male, Young Adult, Spatial Memory, Spatial Navigation, Mental Navigation Tests, Neurosciences, Clinical Research, 1.1 Normal biological development and functioning, 2.1 Biological and endogenous factors, Neurological, Electrodes, Implanted
Abstract

Low-Frequency Oscillations (LFO) in the range of 7-9 Hz, or theta rhythm, has been recorded in rodents ambulating in the real world. However, intra-hippocampus EEG recordings during virtual navigation in humans have consistently reported LFO that appear to predominate around 3-4 Hz. Here we report clear evidence of 7-9 Hz rhythmicity in raw intra-hippocampus EEG traces during real as well as virtual movement. Oscillations typically occur at a lower frequency in virtual than real world navigation. This study highlights the possibility that human and rodent hippocampal EEG activity are not as different as previously reported and this difference may arise, in part, due to the lack of actual movement in previous human navigation studies, which were virtual.

Published
2017

22. Learning-Dependent Evolution of Spatial Representations in Large-Scale Virtual Environments

Author

Starrett, Michael J., Stokes, Jared D., Huffman, Derek J., Ferrer, Emilio, and Ekstrom, Arne D.

Abstract

An important question regards how we use environmental boundaries to anchor spatial representations during navigation. Behavioral and neurophysiological models appear to provide conflicting predictions, and this question has been difficult to answer because of technical challenges with testing navigation in novel, large-scale, realistic spatial environments. We conducted an experiment in which participants freely ambulated on an omnidirectional treadmill while viewing novel, town-sized environments in virtual reality on a head-mounted display. Participants performed interspersed judgments of relative direction (JRD) to assay their spatial knowledge and to determine when during learning they employed environmental boundaries to anchor their spatial representations. We designed JRD questions that assayed directions aligned and misaligned with the axes of the surrounding rectangular boundaries and employed structural equation modeling to better understand the learning-dependent dynamics for aligned versus misaligned pointing. Pointing accuracy showed no initial directional bias to boundaries, although such "alignment effects" did emerge after the fourth block of learning. Preexposure to a map in Experiment 2 led to similar overall findings. A control experiment in which participants studied a map but did not navigate the environment, however, demonstrated alignment effects after a brief, initial learning experience. Our results help to bridge the gap between neurophysiological models of location-specific firing in rodents and human behavioral models of spatial navigation by emphasizing the experience-dependent accumulation of route-specific knowledge. In particular, our results suggest that the use of spatial boundaries as an organizing schema during navigation of large-scale space occurs in an experience-dependent fashion.

Published
2019
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27. A network approach for modulating memory processes via direct and indirect brain stimulation: Toward a causal approach for the neural basis of memory.

Author

Kim, Kamin, Ekstrom, Arne D, and Tandon, Nitin

Subjects
Brain, Nerve Net, Humans, Deep Brain Stimulation, Memory, Transcranial Magnetic Stimulation, Transcranial Direct Current Stimulation, Brain stimulation, DBS, Network, TMS, tDCS, Behavioral Science & Comparative Psychology, Medical and Health Sciences, Psychology and Cognitive Sciences
Abstract

Electrical stimulation of the brain is a unique tool to perturb endogenous neural signals, allowing us to evaluate the necessity of given neural processes to cognitive processing. An important issue, gaining increasing interest in the literature, is whether and how stimulation can be employed to selectively improve or disrupt declarative memory processes. Here, we provide a comprehensive review of both invasive and non-invasive stimulation studies aimed at modulating memory performance. The majority of past studies suggest that invasive stimulation of the hippocampus impairs memory performance; similarly, most non-invasive studies show that disrupting frontal or parietal regions also impairs memory performance, suggesting that these regions also play necessary roles in declarative memory. On the other hand, a handful of both invasive and non-invasive studies have also suggested modest improvements in memory performance following stimulation. These studies typically target brain regions connected to the hippocampus or other memory "hubs," which may affect endogenous activity in connected areas like the hippocampus, suggesting that to augment declarative memory, altering the broader endogenous memory network activity is critical. Together, studies reporting memory improvements/impairments are consistent with the idea that a network of distinct brain "hubs" may be crucial for successful memory encoding and retrieval rather than a single primary hub such as the hippocampus. Thus, it is important to consider neurostimulation from the network perspective, rather than from a purely localizationalist viewpoint. We conclude by proposing a novel approach to neurostimulation for declarative memory modulation that aims to facilitate interactions between multiple brain "nodes" underlying memory rather than considering individual brain regions in isolation.

Published
2016

28. Oscillations Go the Distance: Low-Frequency Human Hippocampal Oscillations Code Spatial Distance in the Absence of Sensory Cues during Teleportation

Author

Vass, Lindsay K, Copara, Milagros S, Seyal, Masud, Shahlaie, Kiarash, Farias, Sarah Tomaszewski, Shen, Peter Y, and Ekstrom, Arne D

Subjects
Biological Psychology, Biomedical and Clinical Sciences, Psychology, Neurosciences, Clinical Research, 1.1 Normal biological development and functioning, Neurological, Mental health, Adult, Brain Waves, Cues, Drug Resistant Epilepsy, Electroencephalography, Female, Hippocampus, Humans, Male, Movement, Photic Stimulation, Space Perception, Spatial Memory, Spatial Navigation, User-Computer Interface, Cognitive Sciences, Neurology & Neurosurgery, Biological psychology
Abstract

Low-frequency (delta/theta band) hippocampal neural oscillations play prominent roles in computational models of spatial navigation, but their exact function remains unknown. Some theories propose they are primarily generated in response to sensorimotor processing, while others suggest a role in memory-related processing. We directly recorded hippocampal EEG activity in patients undergoing seizure monitoring while they explored a virtual environment containing teleporters. Critically, this manipulation allowed patients to experience movement through space in the absence of visual and self-motion cues. The prevalence and duration of low-frequency hippocampal oscillations were unchanged by this manipulation, indicating that sensorimotor processing was not required to elicit them during navigation. Furthermore, the frequency-wise pattern of oscillation prevalence during teleportation contained spatial information capable of classifying the distance teleported. These results demonstrate that movement-related sensory information is not required to drive spatially informative low-frequency hippocampal oscillations during navigation and suggest a specific function in memory-related spatial updating.

Published
2016

29. Impairments in precision, rather than spatial strategy, characterize performance on the virtual Morris Water Maze: A case study

Author

Kolarik, Branden S, Shahlaie, Kiarash, Hassan, Abdul, Borders, Alyssa A, Kaufman, Kyle C, Gurkoff, Gene, Yonelinas, Andy P, and Ekstrom, Arne D

Subjects
Biological Psychology, Psychology, Mental Health, Clinical Research, 1.2 Psychological and socioeconomic processes, Mental health, Adult, Brain Injuries, Female, Hippocampus, Humans, Image Processing, Computer-Assisted, Magnetic Resonance Imaging, Male, Maze Learning, Neuropsychological Tests, Perceptual Disorders, Reaction Time, Space Perception, Spatial Navigation, User-Computer Interface, Verbal Learning, Young Adult, Memory, Spatial memory, Allocentric cognitive map, MTL lesion, Morris Water Maze, Neurosciences, Cognitive Sciences, Experimental Psychology, Biological psychology, Cognitive and computational psychology
Abstract

Damage to the medial temporal lobes produces profound amnesia, greatly impairing the ability of patients to learn about new associations and events. While studies in rodents suggest a strong link between damage to the hippocampus and the ability to navigate using distal landmarks in a spatial environment, the connection between navigation and memory in humans remains less clear. Past studies on human navigation have provided mixed findings about whether patients with damage to the medial temporal lobes can successfully acquire and navigate new spatial environments, possibly due, in part, to issues related to patient demographics and characterization of medial temporal lobe damage. Here, we report findings from a young, high functioning patient who suffered severe medial temporal lobe damage. Although the patient is densely amnestic, her ability to acquire and utilize new, but coarse, spatial "maps" appears largely intact. Specifically, a novel computational analysis focused on the precision of her spatial search revealed a significant deficit in spatial precision rather than spatial search strategy. These findings argue that an intact hippocampus in humans is not necessary for representing multiple external landmarks during spatial navigation of new environments. We suggest instead that the human hippocampus may store and represent complex high-resolution bindings of features in the environment as part of a larger role in perception, memory, and navigation.

Published
2016

30. Successful retrieval of competing spatial environments in humans involves hippocampal pattern separation mechanisms.

Author

Kyle, Colin T, Stokes, Jared D, Lieberman, Jennifer S, Hassan, Abdul S, and Ekstrom, Arne D

Subjects
Hippocampus, Humans, Magnetic Resonance Imaging, Brain Mapping, Space Perception, Female, Male, CA1, CA3, MVPA, Memory, Navigation, fMRI, human, neuroscience, Biochemistry and Cell Biology
Abstract

The rodent hippocampus represents different spatial environments distinctly via changes in the pattern of "place cell" firing. It remains unclear, though, how spatial remapping in rodents relates more generally to human memory. Here participants retrieved four virtual reality environments with repeating or novel landmarks and configurations during high-resolution functional magnetic resonance imaging (fMRI). Both neural decoding performance and neural pattern similarity measures revealed environment-specific hippocampal neural codes. Conversely, an interfering spatial environment did not elicit neural codes specific to that environment, with neural activity patterns instead resembling those of competing environments, an effect linked to lower retrieval performance. We find that orthogonalized neural patterns accompany successful disambiguation of spatial environments while erroneous reinstatement of competing patterns characterized interference errors. These results provide the first evidence for environment-specific neural codes in the human hippocampus, suggesting that pattern separation/completion mechanisms play an important role in how we successfully retrieve memories.

Published
2015

31. Septohippocampal Neuromodulation Improves Cognition after Traumatic Brain Injury.

Author

Lee, Darrin J, Gurkoff, Gene G, Izadi, Ali, Seidl, Stacey E, Echeverri, Angela, Melnik, Mikhail, Berman, Robert F, Ekstrom, Arne D, Muizelaar, J Paul, Lyeth, Bruce G, and Shahlaie, Kiarash

Subjects
Hippocampus, Septal Nuclei, Animals, Rats, Rats, Sprague-Dawley, Brain Injuries, Electroencephalography, Theta Rhythm, Electric Stimulation Therapy, Electrodes, Implanted, Exploratory Behavior, Maze Learning, Psychomotor Performance, Cognition Disorders, Male, Gamma Rhythm, cognition, deep brain stimulation, hippocampal theta oscillation, medial septal nucleus, traumatic brain injury, Behavioral and Social Science, Traumatic Head and Spine Injury, Physical Injury - Accidents and Adverse Effects, Mental Health, Traumatic Brain Injury (TBI), Neurosciences, Rehabilitation, Brain Disorders, Acquired Cognitive Impairment, Aetiology, 2.1 Biological and endogenous factors, Neurological, Mental health, Clinical Sciences, Neurology & Neurosurgery
Abstract

Traumatic brain injury (TBI) often results in persistent attention and memory deficits that are associated with hippocampal dysfunction. Although deep brain stimulation (DBS) is used to treat neurological disorders related to motor dysfunction, the effectiveness of stimulation to treat cognition remains largely unknown. In this study, adult male Harlan Sprague-Dawley rats underwent a lateral fluid percussion or sham injury followed by implantation of bipolar electrodes in the medial septal nucleus (MSN) and ipsilateral hippocampus. In the first week after injury, there was a significant decrease in hippocampal theta oscillations that correlated with decreased object exploration and impaired performance in the Barnes maze spatial learning task. Continuous 7.7 Hz theta stimulation of the medial septum significantly increased hippocampal theta oscillations, restored normal object exploration, and improved spatial learning in injured animals. There were no benefits with 100 Hz gamma stimulation, and stimulation of sham animals at either frequency did not enhance performance. We conclude, therefore, that there was a theta frequency-specific benefit of DBS that restored cognitive function in brain-injured rats. These data suggest that septal theta stimulation may be an effective and novel neuromodulatory therapy for treatment of persistent cognitive deficits following TBI.

Published
2015

32. Specific responses of human hippocampal neurons are associated with better memory.

Author

Suthana, Nanthia A, Parikshak, Neelroop N, Ekstrom, Arne D, Ison, Matias J, Knowlton, Barbara J, Bookheimer, Susan Y, and Fried, Itzhak

Subjects
Face, Hippocampus, Temporal Lobe, Neurons, Humans, Brain Mapping, Random Allocation, Reproducibility of Results, Photic Stimulation, Electrodes, Behavior, Learning, Memory, Neuropsychological Tests, Electrophysiology, Adult, Middle Aged, Female, Male, Young Adult, Recognition, Psychology, discrimination, hippocampus, invariance, memory, selectivity, Recognition, Psychology, Mental Health, Basic Behavioral and Social Science, Behavioral and Social Science, Acquired Cognitive Impairment, Clinical Research, Brain Disorders, Neurosciences, Neurological
Abstract

A population of human hippocampal neurons has shown responses to individual concepts (e.g., Jennifer Aniston) that generalize to different instances of the concept. However, recordings from the rodent hippocampus suggest an important function of these neurons is their ability to discriminate overlapping representations, or pattern separate, a process that may facilitate discrimination of similar events for successful memory. In the current study, we explored whether human hippocampal neurons can also demonstrate the ability to discriminate between overlapping representations and whether this selectivity could be directly related to memory performance. We show that among medial temporal lobe (MTL) neurons, certain populations of neurons are selective for a previously studied (target) image in that they show a significant decrease in firing rate to very similar (lure) images. We found that a greater proportion of these neurons can be found in the hippocampus compared with other MTL regions, and that memory for individual items is correlated to the degree of selectivity of hippocampal neurons responsive to those items. Moreover, a greater proportion of hippocampal neurons showed selective firing for target images in good compared with poor performers, with overall memory performance correlated with hippocampal selectivity. In contrast, selectivity in other MTL regions was not associated with memory performance. These findings show that a substantial proportion of human hippocampal neurons encode specific memories that support the discrimination of overlapping representations. These results also provide previously unidentified evidence consistent with a unique role of the human hippocampus in orthogonalization of representations in declarative memory.

Published
2015

33. High-resolution 7T fMRI of Human Hippocampal Subfields during Associative Learning.

Author

Suthana, Nanthia A, Donix, Markus, Wozny, David R, Bazih, Adam, Jones, Michael, Heidemann, Robin M, Trampel, Robert, Ekstrom, Arne D, Scharf, Maria, Knowlton, Barbara, Turner, Robert, and Bookheimer, Susan Y

Subjects
Hippocampus, Humans, Magnetic Resonance Imaging, Brain Mapping, Association Learning, Memory, Neuropsychological Tests, Adult, Female, Male, Young Adult, Mental Health, Brain Disorders, Neurosciences, Clinical Research, Neurodegenerative, 2.1 Biological and endogenous factors, Aetiology, Neurological, Mental health, Psychology, Cognitive Sciences, Experimental Psychology
Abstract

Examining the function of individual human hippocampal subfields remains challenging because of their small sizes and convoluted structures. Previous human fMRI studies at 3 T have successfully detected differences in activation between hippocampal cornu ammonis (CA) field CA1, combined CA2, CA3, and dentate gyrus (DG) region (CA23DG), and the subiculum during associative memory tasks. In this study, we investigated hippocampal subfield activity in healthy participants using an associative memory paradigm during high-resolution fMRI scanning at 7 T. We were able to localize fMRI activity to anterior CA2 and CA3 during learning and to the posterior CA2 field, the CA1, and the posterior subiculum during retrieval of novel associations. These results provide insight into more specific human hippocampal subfield functions underlying learning and memory and a unique opportunity for future investigations of hippocampal subfield function in healthy individuals as well as those suffering from neurodegenerative diseases.

Published
2015

37. Multiple interacting brain areas underlie successful spatiotemporal memory retrieval in humans.

Author

Schedlbauer, Amber M, Copara, Milagros S, Watrous, Andrew J, and Ekstrom, Arne D

Subjects
Hippocampus, Prefrontal Cortex, Visual Cortex, Humans, Magnetic Resonance Imaging, Brain Mapping, Memory, Image Processing, Computer-Assisted, User-Computer Interface, Adult, Female, Male, Radiography, Image Processing, Computer-Assisted
Abstract

Emerging evidence suggests that our memories for recent events depend on a dynamic interplay between multiple cortical brain regions, although previous research has also emphasized a primary role for the hippocampus in episodic memory. One challenge in determining the relative importance of interactions between multiple brain regions versus a specific brain region is a lack of analytic approaches to address this issue. Participants underwent neuroimaging while retrieving the spatial and temporal details of a recently experienced virtual reality environment; we then employed graph theory to analyze functional connectivity patterns across multiple lobes. Dense, large-scale increases in connectivity during successful memory retrieval typified network topology, with individual participant performance correlating positively with overall network density. Within this dense network, the hippocampus, prefrontal cortex, precuneus, and visual cortex served as "hubs" of high connectivity. Spatial and temporal retrieval were characterized by distinct but overlapping "subnetworks" with higher connectivity within posterior and anterior brain areas, respectively. Together, these findings provide new insight into the neural basis of episodic memory, suggesting that the interactions of multiple hubs characterize successful memory retrieval. Furthermore, distinct subnetworks represent components of spatial versus temporal retrieval, with the hippocampus acting as a hub integrating information between these two subnetworks.

Published
2014

38. Complementary Roles of Human Hippocampal Subregions during Retrieval of Spatiotemporal Context

Author

Copara, Milagros S, Hassan, Abdul S, Kyle, Colin T, Libby, Laura A, Ranganath, Charan, and Ekstrom, Arne D

Subjects
Clinical Research, Alzheimer's Disease including Alzheimer's Disease Related Dementias (AD/ADRD), Acquired Cognitive Impairment, Dementia, Behavioral and Social Science, Brain Disorders, Mental Health, Neurosciences, Basic Behavioral and Social Science, Aging, Alzheimer's Disease, Neurodegenerative, 1.2 Psychological and socioeconomic processes, 1.1 Normal biological development and functioning, Underpinning research, Neurological, Mental health, Adult, Brain Mapping, Female, Hippocampus, Humans, Image Processing, Computer-Assisted, Magnetic Resonance Imaging, Male, Memory, Episodic, Parahippocampal Gyrus, episodic memory, high-res fMRI, hippocampus, multivariate pattern analysis, parahippocampal cortex, spatiotemporal, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery
Abstract

Current evidence strongly supports the central involvement of the human medial temporal lobes (MTL) in storing and retrieving memories for recently experienced events. However, a critical remaining question regards exactly how the hippocampus and surrounding cortex represents spatiotemporal context defining an event in memory. Competing accounts suggest that this process may be accomplished by the following: (1) an overall increase in neural similarity of representations underlying spatial and temporal context, (2) a differentiation of competing spatiotemporal representations, or (3) a combination of the two processes, with different subregions performing these two functions within the MTL. To address these competing proposals, we used high-resolution functional magnetic resonance imaging targeting the MTL along with a multivariate pattern similarity approach with 19 participants. While undergoing imaging, participants performed a task in which they retrieved spatial and temporal contextual representations from a recently learned experience. Results showed that successfully retrieving spatiotemporal context defining an episode involved a decrease in pattern similarity between putative spatial and temporal contextual representations in hippocampal subfields CA2/CA3/DG, whereas the parahippocampal cortex (PHC) showed the opposite pattern. These findings could not be accounted for by differences in univariate activations for complete versus partial retrieval nor differences in correlations for correct or incorrect retrieval. Together, these data suggest that the CA2/CA3/DG serves to differentiate competing contextual representations, whereas the PHC stores a comparatively integrated trace of scene-specific context, both of which likely play important roles in successful episodic memory retrieval.

Published
2014

39. Towards Analysis of Multivariate Time Series Using Topological Data Analysis.

Author

Zheng, Jingyi, Feng, Ziqin, and Ekstrom, Arne D.

Subjects
TIME series analysis, HILBERT-Huang transform, DATA analysis, BRAIN-computer interfaces, PIPELINE inspection, TOPOLOGICAL entropy, TIME management
Abstract

Topological data analysis (TDA) has proven to be a potent approach for extracting intricate topological structures from complex and high-dimensional data. In this paper, we propose a TDA-based processing pipeline for analyzing multi-channel scalp EEG data. The pipeline starts with extracting both frequency and temporal information from the signals via the Hilbert–Huang Transform. The sequences of instantaneous frequency and instantaneous amplitude across all electrode channels are treated as approximations of curves in the high-dimensional space. TDA features, which represent the local topological structure of the curves, are further extracted and used in the classification models. Three sets of scalp EEG data, including one collected in a lab and two Brain–computer Interface (BCI) competition data, were used to validate the proposed methods, and compare with other state-of-art TDA methods. The proposed TDA-based approach shows superior performance and outperform the winner of the BCI competition. Besides BCI, the proposed method can also be applied to spatial and temporal data in other domains such as computer vision, remote sensing, and medical imaging. [ABSTRACT FROM AUTHOR]

Published
2024
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42. A critical review of the allocentric spatial representation and its neural underpinnings: toward a network-based perspective.

Author

Ekstrom, Arne D, Arnold, Aiden EGF, and Iaria, Giuseppe

Subjects
allocentric, cognitive map, egocentric, hippocampus, humans, path integration, spatial navigation, Neurosciences, Psychology, Cognitive Sciences, Experimental Psychology
Abstract

While the widely studied allocentric spatial representation holds a special status in neuroscience research, its exact nature and neural underpinnings continue to be the topic of debate, particularly in humans. Here, based on a review of human behavioral research, we argue that allocentric representations do not provide the kind of map-like, metric representation one might expect based on past theoretical work. Instead, we suggest that almost all tasks used in past studies involve a combination of egocentric and allocentric representation, complicating both the investigation of the cognitive basis of an allocentric representation and the task of identifying a brain region specifically dedicated to it. Indeed, as we discuss in detail, past studies suggest numerous brain regions important to allocentric spatial memory in addition to the hippocampus, including parahippocampal, retrosplenial, and prefrontal cortices. We thus argue that although allocentric computations will often require the hippocampus, particularly those involving extracting details across temporally specific routes, the hippocampus is not necessary for all allocentric computations. We instead suggest that a non-aggregate network process involving multiple interacting brain areas, including hippocampus and extra-hippocampal areas such as parahippocampal, retrosplenial, prefrontal, and parietal cortices, better characterizes the neural basis of spatial representation during navigation. According to this model, an allocentric representation does not emerge from the computations of a single brain region (i.e., hippocampus) nor is it readily decomposable into additive computations performed by separate brain regions. Instead, an allocentric representation emerges from computations partially shared across numerous interacting brain regions. We discuss our non-aggregate network model in light of existing data and provide several key predictions for future experiments.

Published
2014

43. The spectro-contextual encoding and retrieval theory of episodic memory.

Author

Watrous, Andrew J and Ekstrom, Arne D

Subjects
cell assembly, context reinstatement, cross-frequency coupling, episodic memory, hippocampus, neocortex, oscillations, phase-synchronization, Neurosciences, Psychology, Cognitive Sciences, Experimental Psychology
Abstract

The spectral fingerprint hypothesis, which posits that different frequencies of oscillations underlie different cognitive operations, provides one account for how interactions between brain regions support perceptual and attentive processes (Siegel etal., 2012). Here, we explore and extend this idea to the domain of human episodic memory encoding and retrieval. Incorporating findings from the synaptic to cognitive levels of organization, we argue that spectrally precise cross-frequency coupling and phase-synchronization promote the formation of hippocampal-neocortical cell assemblies that form the basis for episodic memory. We suggest that both cell assembly firing patterns as well as the global pattern of brain oscillatory activity within hippocampal-neocortical networks represents the contents of a particular memory. Drawing upon the ideas of context reinstatement and multiple trace theory, we argue that memory retrieval is driven by internal and/or external factors which recreate these frequency-specific oscillatory patterns which occur during episodic encoding. These ideas are synthesized into a novel model of episodic memory (the spectro-contextual encoding and retrieval theory, or "SCERT") that provides several testable predictions for future research.

Published
2014

44. Frequency-specific network connectivity increases underlie accurate spatiotemporal memory retrieval

Author

Watrous, Andrew J, Tandon, Nitin, Conner, Chris R, Pieters, Thomas, and Ekstrom, Arne D

Subjects
Biological Psychology, Psychology, Clinical Research, Mental Health, Neurosciences, Brain Disorders, Aetiology, 1.1 Normal biological development and functioning, 2.1 Biological and endogenous factors, Underpinning research, Neurological, Adult, Brain, Brain Mapping, Epilepsy, Functional Neuroimaging, Humans, Memory, Mental Recall, Nerve Net, Neuropsychological Tests, Space Perception, Cognitive Sciences, Neurology & Neurosurgery, Biological psychology
Abstract

The medial temporal lobes, prefrontal cortex and parts of parietal cortex form the neural underpinnings of episodic memory, which includes remembering both where and when an event occurred. However, the manner in which these three regions interact during retrieval of spatial and temporal context remains untested. We employed simultaneous electrocorticographical recordings across multilobular regions in patients undergoing seizure monitoring while they retrieved spatial and temporal context associated with an episode, and we used phase synchronization as a measure of network connectivity. Successful memory retrieval was characterized by greater global connectivity compared with incorrect retrieval, with the medial temporal lobe acting as a hub for these interactions. Spatial versus temporal context retrieval resulted in prominent differences in both the spectral and temporal patterns of network interactions. These results emphasize dynamic network interactions as being central to episodic memory retrieval, providing insight into how multiple contexts underlying a single event can be recreated in the same network.

Published
2013

45. Differential recruitment of brain networks following route and cartographic map learning of spatial environments.

Author

Zhang, Hui, Copara, Milagros, and Ekstrom, Arne D

Subjects
Brain, Nerve Net, Humans, Magnetic Resonance Imaging, Orientation, Spatial Behavior, Learning, Memory, Female, Male, Functional Neuroimaging, Geographic Mapping, General Science & Technology
Abstract

An extensive neuroimaging literature has helped characterize the brain regions involved in navigating a spatial environment. Far less is known, however, about the brain networks involved when learning a spatial layout from a cartographic map. To compare the two means of acquiring a spatial representation, participants learned spatial environments either by directly navigating them or learning them from an aerial-view map. While undergoing functional magnetic resonance imaging (fMRI), participants then performed two different tasks to assess knowledge of the spatial environment: a scene and orientation dependent perceptual (SOP) pointing task and a judgment of relative direction (JRD) of landmarks pointing task. We found three brain regions showing significant effects of route vs. map learning during the two tasks. Parahippocampal and retrosplenial cortex showed greater activation following route compared to map learning during the JRD but not SOP task while inferior frontal gyrus showed greater activation following map compared to route learning during the SOP but not JRD task. We interpret our results to suggest that parahippocampal and retrosplenial cortex were involved in translating scene and orientation dependent coordinate information acquired during route learning to a landmark-referenced representation while inferior frontal gyrus played a role in converting primarily landmark-referenced coordinates acquired during map learning to a scene and orientation dependent coordinate system. Together, our results provide novel insight into the different brain networks underlying spatial representations formed during navigation vs. cartographic map learning and provide additional constraints on theoretical models of the neural basis of human spatial representation.

Published
2012

50. Hippocampal contributions to novel spatial learning are both age-related and age-invariant.

Author

Li Zheng, Zhiyao Gao, Doner, Stephanie, Oyao, Alexis, Forloines, Martha, Grilli, Matthew D., Barnes, Carol A., and Ekstrom, Arne D.

Subjects
OLDER people, SPATIAL memory, YOUNG adults, HIPPOCAMPUS (Brain), FUNCTIONAL magnetic resonance imaging, CONTEXTUAL learning
Abstract

Older adults show declines in spatial memory, although the extent of these alterations is not uniform across the healthy older population. Here, we investigate the stability of neural representations for the same and different spatial environments in a sample of younger and older adults using high-resolution functional MRI of the medial temporal lobes. Older adults showed, on average, lower neural pattern similarity for retrieving the same environment and more variable neural patterns compared to young adults. We also found a positive association between spatial distance discrimination and the distinctiveness of neural patterns between environments. Our analyses suggested that one source for this association was the extent of informational connectivity to CA1 from other subfields, which was dependent on age, while another source was the fidelity of signals within CA1 itself, which was independent of age. Together, our findings suggest both age-dependent and independent neural contributions to spatial memory performance. [ABSTRACT FROM AUTHOR]

Published
2023
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