The brain can be described as a network of nodes and links between them, the connectome, either anatomic or functional, containing information on the neural pathways and the sig- nal exchanged across them. Recent studies proposed the Krankheit-operator (K-operator) acting on the connectome and modelling the effect of neurological disorders, while Koop- man operators K describe neural dynamics through lifted linear representations. This is a position paper where we propose a coupled node-network model of brain dynamics. Structural changes on the functional connectome are induced by K, whose information is injected within the Koopman operators on each node. As a first, simple proof-of-concept, we propose a computational approximation of the model, imposing the network dynam- ics modelled by the K-operator on the local, node-level Koopman operators. We show an improvement in time-series reconstruction by using K as a nonlinear correction, rather than injecting it within linear Koopman frameworks. We also find a small, yet statistically significant effect of a Krankheit-Koopman coupling.

A coupled node-network dynamics with Koopman and Krankheit-operators

Mannone, M
2026

Abstract

The brain can be described as a network of nodes and links between them, the connectome, either anatomic or functional, containing information on the neural pathways and the sig- nal exchanged across them. Recent studies proposed the Krankheit-operator (K-operator) acting on the connectome and modelling the effect of neurological disorders, while Koop- man operators K describe neural dynamics through lifted linear representations. This is a position paper where we propose a coupled node-network model of brain dynamics. Structural changes on the functional connectome are induced by K, whose information is injected within the Koopman operators on each node. As a first, simple proof-of-concept, we propose a computational approximation of the model, imposing the network dynam- ics modelled by the K-operator on the local, node-level Koopman operators. We show an improvement in time-series reconstruction by using K as a nonlinear correction, rather than injecting it within linear Koopman frameworks. We also find a small, yet statistically significant effect of a Krankheit-Koopman coupling.
2026
Istituto di Calcolo e Reti ad Alte Prestazioni - ICAR
nonlinear dynamics
brain data
koopman operator
Krankheit-operator
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/20.500.14243/591006
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