Your search keyword '"Alessandro Torcini"' showing total 7 results

1. Patterns of synchronized clusters in adaptive networks

Author

Matteo Lodi, Shirin Panahi, Francesco Sorrentino, Alessandro Torcini, and Marco Storace

Subjects

Astrophysics, QB460-466, Physics, QC1-999

Abstract

Abstract Adaptive networks with time-varying connectivity, often called plasticity, provide a fundamental paradigm to model complex dynamical systems. In these systems, different groups of elements frequently exhibit different yet synchronized dynamics within each group. Here we propose a framework to study patterns of synchronous solutions in a large class of plastic networks and derive a general approach to analyze the stability of these solutions. This approach decouples the role of the network topology from that of the dynamic, thus leading to a dimensionality reduction of the stability problem and allowing us to investigate how adaptation affects the emergence of multi-stable patterns of synchronized activity. To illustrate its potentialities, we apply our method to three networks of oscillators, with distinct topology, dynamics, and adaptation rules. Our working framework encompasses a large class of heterogeneous multi-layer dynamical networks, connected (even with delays) via different plastic links, and can have a broad impact on the analysis of complex plastic networks.

Published

2024

2. Gamma oscillatory complexity conveys behavioral information in hippocampal networks

Author

Vincent Douchamps, Matteo di Volo, Alessandro Torcini, Demian Battaglia, and Romain Goutagny

Subjects

Science

Abstract

Abstract The hippocampus and entorhinal cortex exhibit rich oscillatory patterns critical for cognitive functions. In the hippocampal region CA1, specific gamma-frequency oscillations, timed at different phases of the ongoing theta rhythm, are hypothesized to facilitate the integration of information from varied sources and contribute to distinct cognitive processes. Here, we show that gamma elements -a multidimensional characterization of transient gamma oscillatory episodes- occur at any frequency or phase relative to the ongoing theta rhythm across all CA1 layers in male mice. Despite their low power and stochastic-like nature, individual gamma elements still carry behavior-related information and computational modeling suggests that they reflect neuronal firing. Our findings challenge the idea of rigid gamma sub-bands, showing that behavior shapes ensembles of irregular gamma elements that evolve with learning and depend on hippocampal layers. Widespread gamma diversity, beyond randomness, may thus reflect complexity, likely functional but invisible to classic average-based analyses.

Published

2024

3. Inhibitory neurons control the consolidation of neural assemblies via adaptation to selective stimuli

Author

Raphaël Bergoin, Alessandro Torcini, Gustavo Deco, Mathias Quoy, and Gorka Zamora-López

Subjects

Medicine, Science

Abstract

Abstract Brain circuits display modular architecture at different scales of organization. Such neural assemblies are typically associated to functional specialization but the mechanisms leading to their emergence and consolidation still remain elusive. In this paper we investigate the role of inhibition in structuring new neural assemblies driven by the entrainment to various inputs. In particular, we focus on the role of partially synchronized dynamics for the creation and maintenance of structural modules in neural circuits by considering a network of excitatory and inhibitory $$\theta$$ θ -neurons with plastic Hebbian synapses. The learning process consists of an entrainment to temporally alternating stimuli that are applied to separate regions of the network. This entrainment leads to the emergence of modular structures. Contrary to common practice in artificial neural networks—where the acquired weights are typically frozen after the learning session—we allow for synaptic adaptation even after the learning phase. We find that the presence of inhibitory neurons in the network is crucial for the emergence and the post-learning consolidation of the modular structures. Indeed networks made of purely excitatory neurons or of neurons not respecting Dale’s principle are unable to form or to maintain the modular architecture induced by the stimuli. We also demonstrate that the number of inhibitory neurons in the network is directly related to the maximal number of neural assemblies that can be consolidated, supporting the idea that inhibition has a direct impact on the memory capacity of the neural network.

Published

2023

4. Coexistence of asynchronous and clustered dynamics in noisy inhibitory neural networks

Author

Yannick Feld, Alexander K Hartmann, and Alessandro Torcini

Subjects

spiking neural networks, inhibition, noise, neural mass model, quadratic integrate-and-fire neuron, cluster synchronisation, Science, Physics, QC1-999

Abstract

A regime of coexistence of asynchronous and clustered dynamics is analysed for globally coupled homogeneous and heterogeneous inhibitory networks of quadratic integrate-and-fire (QIF) neurons subject to Gaussian noise. The analysis is based on accurate extensive simulations and complemented by a mean-field description in terms of low-dimensional next generation neural mass models for heterogeneously distributed synaptic couplings. The asynchronous regime is observable at low noise and becomes unstable via a sub-critical Hopf bifurcation at sufficiently large noise. This gives rise to a coexistence region between the asynchronous and the clustered regime. The clustered phase is characterised by population bursts in the γ -range (30–120 Hz), where neurons are split in two equally populated clusters firing in alternation. This clustering behaviour is quite peculiar: despite the global activity being essentially periodic, single neurons display switching between the two clusters due to heterogeneity and/or noise.

Published

2024

5. Editorial: From Structure to Function in Neuronal Networks: Effects of Adaptation, Time-Delays, and Noise

Author

Joana Cabral, Viktor Jirsa, Oleksandr V. Popovych, Alessandro Torcini, and Serhiy Yanchuk

Subjects

neuronal networks, adaptation, structure and function, noise, time-delay, neuronal activity patterns, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Published

2022

6. Collective excitability in highly diluted random networks of oscillators

Author

Gabriele Paolini, Marzena Ciszak, Francesco Marino, Simona Olmi, and Alessandro Torcini

Subjects

Applied Mathematics, General Physics and Astronomy, Statistical and Nonlinear Physics, Computer Simulation, Mathematical Physics, Phase Transition

Abstract

We report on collective excitable events in a highly diluted random network of non-excitable nodes. Excitability arises thanks to a self-sustained local adaptation mechanism that drives the system on a slow timescale across a hysteretic phase transition involving states with different degrees of synchronization. These phenomena have been investigated for the Kuramoto model with bimodal distribution of the natural frequencies and for the Kuramoto model with inertia and a unimodal frequency distribution. We consider global and partial stimulation protocols and characterize the system response for different levels of dilution. We compare the results with those obtained in the fully coupled case showing that such collective phenomena are remarkably robust against network diluteness.

Published

2022

7. Population spiking and bursting in next generation neural masses with spike-frequency adaptation

Author

Alberto Ferrara, David Angulo-Garcia, Alessandro Torcini, and Simona Olmi

Subjects

Biological Physics (physics.bio-ph), FOS: Biological sciences, Quantitative Biology - Neurons and Cognition, FOS: Mathematics, FOS: Physical sciences, Neurons and Cognition (q-bio.NC), Disordered Systems and Neural Networks (cond-mat.dis-nn), Dynamical Systems (math.DS), Physics - Biological Physics, Condensed Matter - Disordered Systems and Neural Networks, Mathematics - Dynamical Systems, Adaptation and Self-Organizing Systems (nlin.AO), Nonlinear Sciences - Adaptation and Self-Organizing Systems

Abstract

Spike-frequency adaptation (SFA) is a fundamental neuronal mechanism taking into account the fatigue due to spike emissions and the consequent reduction of the firing activity. We have studied the effect of this adaptation mechanism on the macroscopic dynamics of excitatory and inhibitory networks of quadratic integrate-and-fire (QIF) neurons coupled via exponentially decaying post-synaptic potentials. In particular, we have studied the population activities by employing an exact mean field reduction, which gives rise to next generation neural mass models. This low-dimensional reduction allows for the derivation of bifurcation diagrams and the identification of the possible macroscopic regimes emerging both in a single and in two identically coupled neural masses. In single popukations SFA favours the emergence of population bursts in excitatory networks, while it hinders tonic population spiking for inhibitory ones. The symmetric coupling of two neural masses, in absence of adaptation, leads to the emergence of macroscopic solutions with broken symmetry : namely, chimera-like solutions in the inhibitory case and anti-phase population spikes in the excitatory one. The addition of SFA leads to new collective dynamical regimes exhibiting cross-frequency coupling (CFC) among the fast synaptic time scale and the slow adaptation one, ranging from anti-phase slow-fast nested oscillations to symmetric and asymmetric bursting phenomena. The analysis of these CFC rhythms in theθ-γrange has revealed that a reduction of SFA leads to an increase of theθfrequency joined to a decrease of theγone. This is analogous to what reported experimentally for the hippocampus and the olfactory cortex of rodents under cholinergic modulation, that is known to reduce SFA.

Published

2022