The Neural Basis of Head Direction and Spatial Context in the Insect Central Complex

The Neural Basis of Head Direction and Spatial Context in the Insect Central Complex

Bibliographic Details
Main Author: Varga, Adrienn Gabriella
Language:English
Published: Case Western Reserve University School of Graduate Studies / OhioLINK 2017
Subjects:
Anatomy and Physiology
Biology
Comparative
Experiments
Histology
Neurobiology
Neurosciences
Physiology
Systems Science
insect brain
central complex
navigation
head direction cells
spatial code
place cells
grid cells
orientation
neuroethology
neurobiology
electrophysiology
extracellular recordings
local field potentials
oscillation
cognition
Online Access:http://rave.ohiolink.edu/etdc/view?acc_num=case1487249074487484
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spelling ndltd-OhioLink-oai-etd.ohiolink.edu-case14872490744874842021-08-03T06:52:13Z The Neural Basis of Head Direction and Spatial Context in the Insect Central Complex Varga, Adrienn Gabriella Anatomy and Physiology Biology Comparative Experiments Histology Neurobiology Neurosciences Physiology Systems Science insect brain central complex navigation head direction cells spatial code place cells grid cells orientation neuroethology neurobiology electrophysiology extracellular recordings local field potentials oscillation cognition A question of wide importance in neuroscience is how the brain controls behavior. How does sensory information get transformed into a spatially organized representation about our current state in the world and how is this abstract representation utilized when producing motor commands that lead to successful navigation? When navigating in a complex environment, all animals must encode information about their position and orientation in a rich sensory environment. In vertebrates this may occur by means of distributed activity across several navigation circuits located in the hippocampal formation. Arthropods, however, lack a hippocampal formation and thus it is unclear what circuits mediate navigation. A wide range of studies indicate that the central complex (CX), is not only involved in directional sensory information processing and the control of motor commands, but also plays a role in orientation coding in polarized light guided navigation and landmark orientation. All of these neural mechanisms point in the direction that single neurons in the CX might be directly involved in head direction coding, as well as other aspects of adaptive navigation. In the work described in this dissertation I used multi-channel extracellular recording techniques to uncover the neural correlates of head direction coding and spatial context cues in the cockroach CX. Specifically, I used tetrodes to record the activity of single neurons in the CX while the animal was passively rotated around on a platform surrounded by a circular arena (Chapter 2). In the same setting I also recorded local field potentials (LPFs) in the CX to uncover how navigational information modulates the network’s activity in a more global manner (Chapter 3). I found that single units, as well as LFPs in the cockroach CX encode the animal’s head direction relative to a salient visual cue. However, when landmarks are not available to the animal, both single neuron and network-level activity can rely upon idiothetic motion cues to update the animal’s relative heading in a landmark-free setting. In addition to these results, I found that a subpopulation of single neurons and some of the LFP frequency bands encoded the rotation direction history of the animal, a common spatial context cue. These results suggest that the CX navigation circuit is involved in environmental context discrimination processes that might be utilized by spatial memory circuits in the insect brain.Taken together, these results provide a solid foundation for future studies on the neural basis of adaptive navigation in insects. By placing these results in a wider context of adaptive navigation in all animals and by comparing them to the mechanisms described in mammalian navigation circuits, these data also contribute to a broad comparative approach to understand the general principles of navigation, as well as the diversity of the neural substrates of navigation across evolutionarily distinct animals. 2017-06-05 English text Case Western Reserve University School of Graduate Studies / OhioLINK http://rave.ohiolink.edu/etdc/view?acc_num=case1487249074487484 http://rave.ohiolink.edu/etdc/view?acc_num=case1487249074487484 unrestricted This thesis or dissertation is protected by copyright: all rights reserved. It may not be copied or redistributed beyond the terms of applicable copyright laws.
collection NDLTD
language English
sources NDLTD
topic Anatomy and Physiology
Biology
Comparative
Experiments
Histology
Neurobiology
Neurosciences
Physiology
Systems Science
insect brain
central complex
navigation
head direction cells
spatial code
place cells
grid cells
orientation
neuroethology
neurobiology
electrophysiology
extracellular recordings
local field potentials
oscillation
cognition
spellingShingle Anatomy and Physiology
Biology
Comparative
Experiments
Histology
Neurobiology
Neurosciences
Physiology
Systems Science
insect brain
central complex
navigation
head direction cells
spatial code
place cells
grid cells
orientation
neuroethology
neurobiology
electrophysiology
extracellular recordings
local field potentials
oscillation
cognition
Varga, Adrienn Gabriella
The Neural Basis of Head Direction and Spatial Context in the Insect Central Complex
author Varga, Adrienn Gabriella
author_facet Varga, Adrienn Gabriella
author_sort Varga, Adrienn Gabriella
title The Neural Basis of Head Direction and Spatial Context in the Insect Central Complex
title_short The Neural Basis of Head Direction and Spatial Context in the Insect Central Complex
title_full The Neural Basis of Head Direction and Spatial Context in the Insect Central Complex
title_fullStr The Neural Basis of Head Direction and Spatial Context in the Insect Central Complex
title_full_unstemmed The Neural Basis of Head Direction and Spatial Context in the Insect Central Complex
title_sort neural basis of head direction and spatial context in the insect central complex
publisher Case Western Reserve University School of Graduate Studies / OhioLINK
publishDate 2017
url http://rave.ohiolink.edu/etdc/view?acc_num=case1487249074487484
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