Geometry of spiking patterns in early visual cortex: a topological data analytic approach
Geometry of spiking patterns in early visual cortex: a topological data analytic approach
In the brain, spiking patterns live in a high-dimensional space of neurons and time. Thus, determining the intrinsic structure of this space presents a theoretical and experimental challenge. To address this challenge, we introduce a new framework for applying topological data analysis (TDA) to spike train data and use it to determine the geometry of spiking patterns in the visual cortex. Key to our approach is a parametrized family of distances based on the timing of spikes that quantifies the dissimilarity between neuronal responses. We applied TDA to visually driven single-unit and multiple single-unit spiking activity in macaque V1 and V2. TDA across timescales reveals a common geometry for spiking patterns in V1 and V2 which, among simple models, is most similar to that of a low-dimensional space endowed with Euclidean or hyperbolic geometry with modest curvature. Remarkably, the inferred geometry depends on timescale and is clearest for the timescales that are important for encoding contrast, orientation and spatial correlations.
Guidolin, Andrea
40011dc4-77ce-4d11-90bd-02e76c0b375a
Desroches, Mathieu
c13d1ce2-40b4-4711-b79f-9514accb100a
Victor, Jonathan D.
84eae2f7-16c0-4d18-ad72-053555b922e4
Purpura, Keith P.
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Rodrigues, Serafim
3e00849e-2ed1-483a-9621-dbdb3ed39165
16 November 2022
Guidolin, Andrea
40011dc4-77ce-4d11-90bd-02e76c0b375a
Desroches, Mathieu
c13d1ce2-40b4-4711-b79f-9514accb100a
Victor, Jonathan D.
84eae2f7-16c0-4d18-ad72-053555b922e4
Purpura, Keith P.
820189b5-07f3-4ead-b40c-dcccb19bdd83
Rodrigues, Serafim
3e00849e-2ed1-483a-9621-dbdb3ed39165
Guidolin, Andrea, Desroches, Mathieu, Victor, Jonathan D., Purpura, Keith P. and Rodrigues, Serafim
(2022)
Geometry of spiking patterns in early visual cortex: a topological data analytic approach.
Journal of the Royal Society Interface, 19 (196), [20220677].
(doi:10.1098/rsif.2022.0677).
Abstract
In the brain, spiking patterns live in a high-dimensional space of neurons and time. Thus, determining the intrinsic structure of this space presents a theoretical and experimental challenge. To address this challenge, we introduce a new framework for applying topological data analysis (TDA) to spike train data and use it to determine the geometry of spiking patterns in the visual cortex. Key to our approach is a parametrized family of distances based on the timing of spikes that quantifies the dissimilarity between neuronal responses. We applied TDA to visually driven single-unit and multiple single-unit spiking activity in macaque V1 and V2. TDA across timescales reveals a common geometry for spiking patterns in V1 and V2 which, among simple models, is most similar to that of a low-dimensional space endowed with Euclidean or hyperbolic geometry with modest curvature. Remarkably, the inferred geometry depends on timescale and is clearest for the timescales that are important for encoding contrast, orientation and spatial correlations.
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Accepted/In Press date: 21 October 2022
Published date: 16 November 2022
Identifiers
Local EPrints ID: 500358
URI: http://eprints.soton.ac.uk/id/eprint/500358
ISSN: 1742-5689
PURE UUID: 877b273b-9fe9-4849-8aed-32387de3cd6c
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Date deposited: 28 Apr 2025 16:36
Last modified: 29 Apr 2025 02:13
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Contributors
Author:
Andrea Guidolin
Author:
Mathieu Desroches
Author:
Jonathan D. Victor
Author:
Keith P. Purpura
Author:
Serafim Rodrigues
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