Neural Mechanisms of Spatial Representations Beyond the Self

Part of paid clinical trials in Boston, Massachusetts.

Sponsor
Boston University Charles River Campus
Study ID
NCT05406349
Status
Recruiting
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Conditions

  • Epilepsy Intractable

Eligibility Criteria

Sex
ALL
Age
18 Years - 70 Years
Healthy Volunteers
Not accepted

Interventions

  • Self-navigation task — BEHAVIORAL
    Participants will perform a self-navigation task with two experimental conditions: Either they will be asked to walk towards a visible wall-mounted sign, or they will be asked to find and learn a hidden target location within the experimental room.
  • Observation task — BEHAVIORAL
    Participants will sit on a chair in a corner of the room (RNS participants) or watch a video that was recorded from the corner of the room (EMU participants). They will be asked to keep track of another person's location who is walking around the room, and to press a button whenever the other person crosses a previously-learned target location.

Study Details

Spatial navigation is a fundamental human behavior, and deficits in navigational functions are among the hallmark symptoms of severe neurological disorders such as Alzheimer's disease. Understanding how the human brain processes and encodes spatial information is thus of critical importance for the development of therapies for affected patients. Previous studies have shown that the brain forms neural representations of spatial information, via spatially-tuned activity of single neurons (e.g., place cells, grid cells, or head direction cells), and by the coordinated oscillatory activity of cell populations. The vast majority of these studies have focused on the encoding of self-related spatial information, such as one's own location, orientation, and movements. However, everyday tasks in social settings require the encoding of spatial information not only for oneself, but also for other people in the environment. At present, it is largely unknown how the human brain accomplishes this important function, and how aspects of human cognition may affect these spatial encoding mechanisms. This project therefore aims to elucidate the neural mechanisms that underlie the encoding of spatial information and awareness of others. Specifically, the proposed research plan will determine how human deep brain oscillations and single-neuron activity allow us to keep track of other individuals as they move through our environment. Next, the project will determine whether these spatial encoding mechanisms are specific to the encoding of another person, or whether they can be used more flexibly to support the encoding of moving inanimate objects and even more abstract cognitive functions such as imagined navigation. Finally, the project will determine how spatial information is encoded in more complex real-world scenarios, when multiple information sources (e.g., multiple people) are present. To address these questions, intracranial medial temporal lobe activity will be recorded from two rare participant groups: (1) Participants with permanently implanted depth electrodes for the treatment of focal epilepsy through responsive neurostimulation (RNS), who provide a unique opportunity to record deep brain oscillations during free movement and naturalistic behavior; and (2) hospitalized epilepsy patients with temporarily implanted intracranial electrodes in the epilepsy monitoring unit (EMU), from whom joint oscillatory and single-neuron activity can be recorded.

Key Dates

Start date
Aug 6, 2022
Status verified
Mar 2025
Primary completion
Apr 30, 2027
Completion
Apr 30, 2027

Study Design

Enrollment
60 participants (estimated)
Allocation
NA
Intervention model
SINGLE_GROUP
Primary purpose
BASIC_SCIENCE

Arms

  • Other: Electrophysiological recordings in participants with intracranially implanted electrodes
    All participants will perform behavioral tasks that test their spatial navigation and memory performance in self-navigation and observation tasks.

Primary Outcome Measure

Oscillatory power [ Time Frame: Continuous measurement during task performance on day 1 and all subsequent measurement days (up to 14 days per participant) ]

Central Contacts

Locations (1)

FacilityCityStateZIPSite coordinators
Boston UniversityBostonMassachusetts02215
Matthias Stangl, PhD
[email protected]
617-353-0879

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By research site
Boston University· Boston, MA

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