Encoding Brain Networks Through Geodesic Clustering of Functional Connectivity for Multiple Sclerosis Classification

Muhammad Abubakar Yamin; Paola Valsasina; Michael Dayan; Sebastiano Vascon; Jacopo Tessadori; Massimo Filippi; Vittorio Murino; Maria A. Rocca; Diego Sona

doi:10.1109/icpr48806.2021.9412939

Abstract

1 min read

An important task in brain connectivity research is the classification of patients from healthy subjects. In this work, we present a two-step mathematical framework allowing to discriminate between two groups of people with an application to multiple sclerosis. The proposed approach exploits the properties of the connectivity matrices determined using the covariances between signals of a fixed set of brain areas. These positive semidefinite matrices lay on a Riemannian manifold, allowing to use a geodesic distance defined on this space. In order to generate a vector representation useful for classification purposes, but still preserving the network structure, we encoded the data exploiting the network attractors determined by a geodesic clustering of connectivity matrices. Then clustering centroids were used as a dictionary allowing to encode subject's connectivity matrices as a vector of geodesic distances. A Linear Support Vector Machine was then used to perform classification between subjects. To demonstrate the advantage of using geodesic metrics in this framework, we conducted the same analysis using Euclidean metric. Experimental results validate the fact that employing geodesic metric in this framework leads to a higher classification performance, whereas performance with a Euclidean metric was sub-optimal.

Related publications

Article2024

Searching for Functional Neuromarkers of Multiple Sclerosis: A Geodesic Distance-Based Framework on Riemannian Manifolds of Brain Connectivity

Muhammad Abubakar Yamin, Paola Valsasina, Massimo Filippi, Maria A. Rocca, Diego Sona

Article2021

Dynamic Functional Connectivity For The Classification Of Multiple Sclerosis Phenotype: A Hidden Markov Model Approach

Jacopo Tessadori, Muhammad Abubakar Yamin, Paola Valsasina, Massimo Filippi, Maria A. Rocca, Diego Sona

Article2020

Multivariate Brain Functional Connectivity Through Regularized Estimators

Raymond Salvador, Norma Verdolini, Beatriz García-Ruiz, Esther Jiménez, Salvador Sarró, Elisabet Vilella, Eduard Vieta, Erick J. Canales‐Rodríguez, Edith Pomarol‐Clotet, Aristotle N. Voineskos

Preprint2023

Diffusion-based structural connectivity patterns of multiple sclerosis phenotypes

Eloy Martínez‐Heras, Elisabeth Solana, Francesc Vivó, Elisabet López-Soley, Alberto Calvi, Salut Albà-Arbalat, Menno M. Schoonheim, Eva Strijbis, Hugo Vrenken, Frederik Barkhof, Maria A. Rocca, Massimo Filippi, Elisabetta Pagani, Sergiu Groppa, Vinzenz Fleischer, Robert A. Dineen, B Ballenberg, Carsten Lukas, Deborah Pareto, Àlex Rovira, Jaume Sastre‐Garriga, Sara Collorone, Ferrán Prados, AT Toosy,

Article1996

Functional Topography: Multidimensional Scaling and Functional Connectivity in the Brain

Karl Friston, Chris Frith, Paul C. Fletcher, P. F. Liddle, R. S. J. Frackowiak