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Analyzing Self-Similar and Fractal Properties of the C. elegans Neural Network
Author(s) -
Tyler M. Reese,
Antoni Brzoska,
Dylan T. Yott,
Daniel J. Kelleher
Publication year - 2012
Publication title -
plos one
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.99
H-Index - 332
ISSN - 1932-6203
DOI - 10.1371/journal.pone.0040483
Subject(s) - connectome , fractal , clustering coefficient , laplacian matrix , eigenfunction , computer science , artificial neural network , laplace operator , biological system , random graph , eigenvalues and eigenvectors , self similarity , complex network , average path length , mathematics , cluster analysis , shortest path problem , theoretical computer science , graph , artificial intelligence , biology , neuroscience , combinatorics , physics , functional connectivity , geometry , mathematical analysis , quantum mechanics
The brain is one of the most studied and highly complex systems in the biological world. While much research has concentrated on studying the brain directly, our focus is the structure of the brain itself: at its core an interconnected network of nodes (neurons). A better understanding of the structural connectivity of the brain should elucidate some of its functional properties. In this paper we analyze the connectome of the nematode Caenorhabditis elegans . Consisting of only 302 neurons, it is one of the better-understood neural networks. Using a Laplacian Matrix of the 279-neuron “giant component” of the network, we use an eigenvalue counting function to look for fractal-like self similarity. This matrix representation is also used to plot visualizations of the neural network in eigenfunction coordinates. Small-world properties of the system are examined, including average path length and clustering coefficient. We test for localization of eigenfunctions, using graph energy and spacial variance on these functions. To better understand results, all calculations are also performed on random networks, branching trees, and known fractals, as well as fractals which have been “rewired” to have small-world properties. We propose algorithms for generating Laplacian matrices of each of these graphs.

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