Percolation of spatially constrained Erdős-Rényi networks with degree correlations

Schmeltzer, Christian; Soriano, Jordi; Sokolov, Igor M.; Rüdiger, Stephan

doi:10.1103/physreve.89.012116

Cited by 30 publications

(19 citation statements)

References 58 publications

(93 reference statements)

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“…The above fδ; Λg regimes characterize the crossover that separates metric-free scenarios from metric-dominated ones. This crossover was also suggested by others [29][30][31]; however, they considered Λ → 0 (lattice-like networks), disregarding the crucial role of Λ.…”

Section: Fig 2 Comparison Between Experiments and Nnim Exper-supporting

confidence: 67%

Dominance of Metric Correlations in Two-Dimensional Neuronal Cultures Described through a Random Field Ising Model

et al. 2017

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We introduce a novel random field Ising model, grounded on experimental observations, to assess the importance of metric correlations in cortical circuits in vitro. Metric correlations arise from both the finite axonal length and the heterogeneity in the spatial arrangement of neurons. The experiments consider the response of neuronal cultures to an external electric stimulation for a gradually weaker connectivity strength between neurons, and in cultures with different spatial configurations. The model can be analytically solved in the metric-free, mean-field scenario. The presence of metric correlations precipitates a strong deviation from the mean field. Null models of the same networks that preserve the distribution of connections recover the mean field. Our results show that metric-inherited correlations in spatial networks dominate the connectivity blueprint, mask the actual distribution of connections, and may emerge as the asset that shapes network dynamics.

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Section: Fig 2 Comparison Between Experiments and Nnim Exper-supporting

confidence: 67%

Dominance of Metric Correlations in Two-Dimensional Neuronal Cultures Described through a Random Field Ising Model

et al. 2017

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“…Although in this work we have considered only purely random distance-independent topologies, neuronal cultures grow on a bi-dimensional domain, and excitatory connections are typically of shorter range than inhibitory ones. This kind of information could be integrated in the analysis of network models that include metric properties and accounts for spatial embedding (such as [27,70,71]), as well as different connectivity rules for the generation of excitatory and inhibitory sub-networks.…”

Section: Discussionmentioning

confidence: 99%

Transfer Entropy Reconstruction and Labeling of Neuronal Connections from Simulated Calcium Imaging

et al. 2014

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Neuronal dynamics are fundamentally constrained by the underlying structural network architecture, yet much of the details of this synaptic connectivity are still unknown even in neuronal cultures in vitro. Here we extend a previous approach based on information theory, the Generalized Transfer Entropy, to the reconstruction of connectivity of simulated neuronal networks of both excitatory and inhibitory neurons. We show that, due to the model-free nature of the developed measure, both kinds of connections can be reliably inferred if the average firing rate between synchronous burst events exceeds a small minimum frequency. Furthermore, we suggest, based on systematic simulations, that even lower spontaneous inter-burst rates could be raised to meet the requirements of our reconstruction algorithm by applying a weak spatially homogeneous stimulation to the entire network. By combining multiple recordings of the same in silico network before and after pharmacologically blocking inhibitory synaptic transmission, we show then how it becomes possible to infer with high confidence the excitatory or inhibitory nature of each individual neuron.

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“…Their accessibility and ease manipulation allow for a variety of preparations, from relatively simple homogeneous neuronal assemblies to intricate bioengineered designs [17]. Neuronal cultures are also ideally suited to study the role of spatial embedding and metric correlations in the formation, structure and dynamics of neuronal circuits [18], [19], [20]. Indeed, the analysis of spatial networks [21] has provided valuable insight in fields as diverse as transportation or epidemics [21], [22], [23], but it has been relatively poorly explored in the context of neuronal circuits.…”

Section: Introductionmentioning

confidence: 99%

Neuronal Spatial Arrangement Shapes Effective Connectivity Traits of in vitro Cortical Networks

Tibau

Ludl

Rüdiger

et al. 2020

IEEE Trans. Netw. Sci. Eng.

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We studied effective connectivity in rat cortical cultures with various degrees of spatial aggregation, ranging from homogeneous networks to highly aggregated ones. We considered small cultures 3 mm in diameter and that contained about 2000 neurons. Spatial inhomogeneity favored an increase of metric correlations and connectivity among neighboring neurons. Effective connectivity was determined from spontaneous activity recordings using calcium fluorescence imaging. We used generalized transfer entropy as tool to infer the effective connectivity. We carried out numerical simulations to build networks that mimicked the experimental ones and to test the reliability of the connectivity-inference algorithm. Effective connectivity traits were investigated during the development of the cultures over two weeks, and along the gradual blockade of excitatory connections through CNQX. We observed that the average effective connectivity rapidly increased during culture development. At DIV 15 the average excitatory in-degree was measured ask in E 50 for homogeneous and semi aggregated networks, andk in E 120 for aggregated ones, and with 20% inhibition. Aggregated cultures exhibited assortative traits and a high resilience to chemical damage, while the other cultures were dissassortative or neutral, and less resilient. Our work illustrates the role of metric correlations in spatially embedded networks in shaping connectivity and activity traits in living neuronal networks.

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Percolation of spatially constrained Erdős-Rényi networks with degree correlations

Cited by 30 publications

References 58 publications

Dominance of Metric Correlations in Two-Dimensional Neuronal Cultures Described through a Random Field Ising Model

Dominance of Metric Correlations in Two-Dimensional Neuronal Cultures Described through a Random Field Ising Model

Transfer Entropy Reconstruction and Labeling of Neuronal Connections from Simulated Calcium Imaging

Neuronal Spatial Arrangement Shapes Effective Connectivity Traits of in vitro Cortical Networks

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