The Geometry and Dimensionality of Brain-wide Activity

Zezhen Wang; Weihao Mai; Yuming Chai; Kexin Qi; Hongtai Ren; Chen Shen; Shiwu Zhang; Guodong Tan; Yu Hu; Quan Wen

doi:10.7554/eLife.100666.1

The Geometry and Dimensionality of Brain-wide Activity

Zezhen Wang
, Weihao Mai
, Yuming Chai
, Kexin Qi
, Hongtai Ren
, Chen Shen
, Shiwu Zhang
, Guodong Tan
, Yu Hu^*
, Quan Wen^*

^*Corresponding author for this work

Research output: Contribution to journal › Journal Article › peer-review

Abstract

Understanding neural activity organization is vital for deciphering brain function. By recording whole-brain calcium activity in larval zebrafish during hunting and spontaneous behaviors, we find that the shape of the neural activity space, described by the neural covariance spectrum, is scale-invariant: a smaller, randomly sampled cell assembly resembles the entire brain. This phenomenon can be explained by Euclidean Random Matrix theory, where neurons are reorganized from anatomical to functional positions based on their correlations. Three factors contribute to the observed scale invariance: slow neural correlation decay, higher functional space dimension, and neural activity heterogeneity. In addition to matching data from zebrafish and mice, our theory and analysis demonstrate how the geometry of neural activity space evolves with population sizes and sampling methods, thus revealing an organizing principle of brain-wide activity.

Original language	English
Journal	eLife
Volume	1
DOIs	https://doi.org/10.7554/eLife.100666.1
Publication status	Published - Jan 2025

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10.7554/eLife.100666.1Licence: CC BY

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title = "The Geometry and Dimensionality of Brain-wide Activity",

abstract = "Understanding neural activity organization is vital for deciphering brain function. By recording whole-brain calcium activity in larval zebrafish during hunting and spontaneous behaviors, we find that the shape of the neural activity space, described by the neural covariance spectrum, is scale-invariant: a smaller, randomly sampled cell assembly resembles the entire brain. This phenomenon can be explained by Euclidean Random Matrix theory, where neurons are reorganized from anatomical to functional positions based on their correlations. Three factors contribute to the observed scale invariance: slow neural correlation decay, higher functional space dimension, and neural activity heterogeneity. In addition to matching data from zebrafish and mice, our theory and analysis demonstrate how the geometry of neural activity space evolves with population sizes and sampling methods, thus revealing an organizing principle of brain-wide activity.",

author = "Zezhen Wang and Weihao Mai and Yuming Chai and Kexin Qi and Hongtai Ren and Chen Shen and Shiwu Zhang and Guodong Tan and Yu Hu and Quan Wen",

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AU - Wang, Zezhen

AU - Mai, Weihao

AU - Chai, Yuming

AU - Qi, Kexin

AU - Ren, Hongtai

AU - Shen, Chen

AU - Zhang, Shiwu

AU - Tan, Guodong

AU - Hu, Yu

AU - Wen, Quan

PY - 2025/1

Y1 - 2025/1

N2 - Understanding neural activity organization is vital for deciphering brain function. By recording whole-brain calcium activity in larval zebrafish during hunting and spontaneous behaviors, we find that the shape of the neural activity space, described by the neural covariance spectrum, is scale-invariant: a smaller, randomly sampled cell assembly resembles the entire brain. This phenomenon can be explained by Euclidean Random Matrix theory, where neurons are reorganized from anatomical to functional positions based on their correlations. Three factors contribute to the observed scale invariance: slow neural correlation decay, higher functional space dimension, and neural activity heterogeneity. In addition to matching data from zebrafish and mice, our theory and analysis demonstrate how the geometry of neural activity space evolves with population sizes and sampling methods, thus revealing an organizing principle of brain-wide activity.

AB - Understanding neural activity organization is vital for deciphering brain function. By recording whole-brain calcium activity in larval zebrafish during hunting and spontaneous behaviors, we find that the shape of the neural activity space, described by the neural covariance spectrum, is scale-invariant: a smaller, randomly sampled cell assembly resembles the entire brain. This phenomenon can be explained by Euclidean Random Matrix theory, where neurons are reorganized from anatomical to functional positions based on their correlations. Three factors contribute to the observed scale invariance: slow neural correlation decay, higher functional space dimension, and neural activity heterogeneity. In addition to matching data from zebrafish and mice, our theory and analysis demonstrate how the geometry of neural activity space evolves with population sizes and sampling methods, thus revealing an organizing principle of brain-wide activity.

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DO - 10.7554/eLife.100666.1

M3 - Journal Article

SN - 2050-084X

VL - 1

JO - eLife

JF - eLife

ER -

The Geometry and Dimensionality of Brain-wide Activity

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