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Main Authors: Pentek, Balazs, Ercsey-Ravasz, Maria
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2410.01269
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author Pentek, Balazs
Ercsey-Ravasz, Maria
author_facet Pentek, Balazs
Ercsey-Ravasz, Maria
contents Studying structural brain networks has witnessed significant advancement in recent decades. Findings have revealed a geometric principle, the exponential distance rule (EDR) showing that the number of neurons decreases exponentially with the length of their axons. An EDR based network model explained various characteristics of inter-areal cortical networks in macaques, mice, and rats. The complete connectome of the Drosophila fruit fly has recently been mapped at the neuronal level. Our study demonstrates that the EDR holds true in Drosophila, and the EDR model effectively accounts for numerous binary and weighted properties of neuropil networks, also called projectome. Our study illustrates that the EDR model is a suitable null model for analyzing networks of brain regions, as it captures geometric and physical constraints in very different species. The importance of the null model lies in its ability to facilitate the identification of functionally significant features that are not caused by inevitable geometric constraints, as we illustrate with the pronounced asymmetry of connection weights important for functional hierarchy.
format Preprint
id arxiv_https___arxiv_org_abs_2410_01269
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle The exponential distance rule based network model predicts topology and reveals functionally relevant properties of the Drosophila projectome
Pentek, Balazs
Ercsey-Ravasz, Maria
Neurons and Cognition
Biological Physics
Studying structural brain networks has witnessed significant advancement in recent decades. Findings have revealed a geometric principle, the exponential distance rule (EDR) showing that the number of neurons decreases exponentially with the length of their axons. An EDR based network model explained various characteristics of inter-areal cortical networks in macaques, mice, and rats. The complete connectome of the Drosophila fruit fly has recently been mapped at the neuronal level. Our study demonstrates that the EDR holds true in Drosophila, and the EDR model effectively accounts for numerous binary and weighted properties of neuropil networks, also called projectome. Our study illustrates that the EDR model is a suitable null model for analyzing networks of brain regions, as it captures geometric and physical constraints in very different species. The importance of the null model lies in its ability to facilitate the identification of functionally significant features that are not caused by inevitable geometric constraints, as we illustrate with the pronounced asymmetry of connection weights important for functional hierarchy.
title The exponential distance rule based network model predicts topology and reveals functionally relevant properties of the Drosophila projectome
topic Neurons and Cognition
Biological Physics
url https://arxiv.org/abs/2410.01269