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15 results on '"Stetter, Olav"'

1. Transfer Entropy reconstruction and labeling of neuronal connections from simulated calcium imaging

Author

Orlandi, Javier G., Stetter, Olav, Soriano, Jordi, Geisel, Theo, and Battaglia, Demian

Subjects
Quantitative Biology - Neurons and Cognition, Condensed Matter - Disordered Systems and Neural Networks
Abstract

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., Comment: 24 pages, 4 figures

Published
2013
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2. Model-free reconstruction of neuronal network connectivity from calcium imaging signals

Author

Stetter, Olav, Battaglia, Demian, Soriano, Jordi, and Geisel, Theo

Subjects
Quantitative Biology - Neurons and Cognition, Condensed Matter - Disordered Systems and Neural Networks
Abstract

A systematic assessment of global neural network connectivity through direct electrophysiological assays has remained technically unfeasible even in dissociated neuronal cultures. We introduce an improved algorithmic approach based on Transfer Entropy to reconstruct approximations to network structural connectivities from network activity monitored through calcium fluorescence imaging. Based on information theory, our method requires no prior assumptions on the statistics of neuronal firing and neuronal connections. The performance of our algorithm is benchmarked on surrogate time-series of calcium fluorescence generated by the simulated dynamics of a network with known ground-truth topology. We find that the effective network topology revealed by Transfer Entropy depends qualitatively on the time-dependent dynamic state of the network (e.g., bursting or non-bursting). We thus demonstrate how conditioning with respect to the global mean activity improves the performance of our method. [...] Compared to other reconstruction strategies such as cross-correlation or Granger Causality methods, our method based on improved Transfer Entropy is remarkably more accurate. In particular, it provides a good reconstruction of the network clustering coefficient, allowing to discriminate between weakly or strongly clustered topologies, whereas on the other hand an approach based on cross-correlations would invariantly detect artificially high levels of clustering. Finally, we present the applicability of our method to real recordings of in vitro cortical cultures. We demonstrate that these networks are characterized by an elevated level of clustering compared to a random graph (although not extreme) and by a markedly non-local connectivity., Comment: 54 pages, 8 figures (+9 supplementary figures), 1 table; submitted for publication

Published
2012
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3. Leaders of neuronal cultures in a quorum percolation model

Author

Eckmann, J. -P., Moses, Elisha, Stetter, Olav, Tlusty, Tsvi, and Zbinden, Cyrille

Subjects
Quantitative Biology - Neurons and Cognition, Condensed Matter - Disordered Systems and Neural Networks, Physics - Biological Physics
Abstract

We present a theoretical framework using quorum-percolation for describing the initiation of activity in a neural culture. The cultures are modeled as random graphs, whose nodes are excitatory neurons with kin inputs and kout outputs, and whose input degrees kin = k obey given distribution functions pk. We examine the firing activity of the population of neurons according to their input degree (k) classes and calculate for each class its firing probability \Phi_k(t) as a function of t. The probability of a node to fire is found to be determined by its in-degree k, and the first-to-fire neurons are those that have a high k. A small minority of high-k classes may be called "Leaders", as they form an inter-connected subnetwork that consistently fires much before the rest of the culture. Once initiated, the activity spreads from the Leaders to the less connected majority of the culture. We then use the distribution of in-degree of the Leaders to study the growth rate of the number of neurons active in a burst, which was experimentally measured to be initially exponential. We find that this kind of growth rate is best described by a population that has an in-degree distribution that is a Gaussian centered around k = 75 with width {\sigma} = 31 for the majority of the neurons, but also has a power law tail with exponent -2 for ten percent of the population. Neurons in the tail may have as many as k = 4, 700 inputs. We explore and discuss the correspondence between the degree distribution and a dynamic neuronal threshold, showing that from the functional point of view, structure and elementary dynamics are interchangeable. We discuss possible geometric origins of this distribution, and comment on the importance of size, or of having a large number of neurons, in the culture., Comment: Keywords: Neuronal cultures, Graph theory, Activation dynamics, Percolation, Statistical mechanics of networks, Leaders of activity, Quorum. http://www.weizmann.ac.il/complex/tlusty/papers/FrontCompNeuro2010.pdf

Published
2010
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4. First Connectomics Challenge: From Imaging to Connectivity

Author

Orlandi, Javier, Ray, Bisakha, Battaglia, Demian, Guyon, Isabelle, Lemaire, Vincent, Saeed, Mehreen, Statnikov, Alexander, Stetter, Olav, Soriano, Jordi, Escalante, Hugo Jair, Series editor, Guyon, Isabelle, Series editor, Escalera, Sergio, Series editor, Battaglia, Demian, editor, Lemaire, Vincent, editor, Orlandi, Javier, editor, Ray, Bisakha, editor, and Soriano, Jordi, editor

Published
2017
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5. First Connectomics Challenge: From Imaging to Connectivity

Author

Orlandi, Javier, primary, Ray, Bisakha, additional, Battaglia, Demian, additional, Guyon, Isabelle, additional, Lemaire, Vincent, additional, Saeed, Mehreen, additional, Statnikov, Alexander, additional, Stetter, Olav, additional, and Soriano, Jordi, additional

Published
2017
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7. Transfer entropy reconstruction and labeling of neuronal connections from simulated calcium imaging

Author

Orlandi, Javier G., Stetter, Olav, Soriano, Jordi, Geisel, Theo, Battaglia, Demian, Garcia-Ojalvo, Jordi, and Universitat de Barcelona

Subjects
Circuit Models, Entropy, lcsh:Medicine, Calcium, Imaging [Neuronal Connections], Nervous System, Topology, Neuroquímica, Animal Cells, Xarxes neuronals (Neurobiologia), Simulació per ordinador, Image Processing, Computer-Assisted, Neural networks (Neurobiology), lcsh:Science, Neurons, Physics, Optical Imaging, Neurochemistry, Condensed Matter - Disordered Systems and Neural Networks, Computer simulation, Computer algorithms, Calcium Imaging, Physical Sciences, Interdisciplinary Physics, Neurons and Cognition (q-bio.NC), Anatomy, Cellular Types, Research Article, Computer Modeling, Computer and Information Sciences, Neural Networks, Bioinformatics, FOS: Physical sciences, Neuroimaging, Models, Biological, Topologia, Developmental Neuroscience, Bioinformàtica, Algorismes computacionals, Computational Neuroscience, lcsh:R, Biology and Life Sciences, Computational Biology, Disordered Systems and Neural Networks (cond-mat.dis-nn), Cell Biology, Connectomics, Neuroanatomy, Sinapsi, FOS: Biological sciences, Quantitative Biology - Neurons and Cognition, Synapses, lcsh:Q, Neural Circuit Formation, Nerve Net, Neuroscience
Abstract

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., 24 pages, 4 figures

Published
2014

8. Model-Free Reconstruction of Excitatory Neuronal Connectivity from Calcium Imaging Signals

Author

Stetter, Olav, Battaglia, Demian, Soriano, Jordi, Geisel, Theo, Beggs, John, and Universitat de Barcelona

Subjects
Circuit Models, Neural Networks, QH301-705.5, Bioinformatics, Neurophysiology, Neuroimaging, Models, Biological, Fluorescence, neural network connectivity, Transfer Entropy, algorithmic approach, Rats, Sprague-Dawley, Developmental Neuroscience, Bioinformàtica, Neurofisiologia, Xarxes neuronals (Neurobiologia), Animals, Cluster Analysis, Algorismes computacionals, Biology (General), Neural networks (Neurobiology), Electrofisiologia, Biology, Computerized Simulations, Cells, Cultured, Computational Neuroscience, Neurons, Quantitative Biology::Neurons and Cognition, Connectomics, Computer algorithms, Calcium Imaging, Rats, Electrophysiology, Neuroanatomy, Sinapsi, Computer Science, Synapses, Calcium, Neural Circuit Formation, Research Article, Neuroscience
Abstract

A systematic assessment of global neural network connectivity through direct electrophysiological assays has remained technically infeasible, even in simpler systems like dissociated neuronal cultures. We introduce an improved algorithmic approach based on Transfer Entropy to reconstruct structural connectivity from network activity monitored through calcium imaging. We focus in this study on the inference of excitatory synaptic links. Based on information theory, our method requires no prior assumptions on the statistics of neuronal firing and neuronal connections. The performance of our algorithm is benchmarked on surrogate time series of calcium fluorescence generated by the simulated dynamics of a network with known ground-truth topology. We find that the functional network topology revealed by Transfer Entropy depends qualitatively on the time-dependent dynamic state of the network (bursting or non-bursting). Thus by conditioning with respect to the global mean activity, we improve the performance of our method. This allows us to focus the analysis to specific dynamical regimes of the network in which the inferred functional connectivity is shaped by monosynaptic excitatory connections, rather than by collective synchrony. Our method can discriminate between actual causal influences between neurons and spurious non-causal correlations due to light scattering artifacts, which inherently affect the quality of fluorescence imaging. Compared to other reconstruction strategies such as cross-correlation or Granger Causality methods, our method based on improved Transfer Entropy is remarkably more accurate. In particular, it provides a good estimation of the excitatory network clustering coefficient, allowing for discrimination between weakly and strongly clustered topologies. Finally, we demonstrate the applicability of our method to analyses of real recordings of in vitro disinhibited cortical cultures where we suggest that excitatory connections are characterized by an elevated level of clustering compared to a random graph (although not extreme) and can be markedly non-local., Author Summary Unraveling the general organizing principles of connectivity in neural circuits is a crucial step towards understanding brain function. However, even the simpler task of assessing the global excitatory connectivity of a culture in vitro, where neurons form self-organized networks in absence of external stimuli, remains challenging. Neuronal cultures undergo spontaneous switching between episodes of synchronous bursting and quieter inter-burst periods. We introduce here a novel algorithm which aims at inferring the connectivity of neuronal cultures from calcium fluorescence recordings of their network dynamics. To achieve this goal, we develop a suitable generalization of Transfer Entropy, an information-theoretic measure of causal influences between time series. Unlike previous algorithmic approaches to reconstruction, Transfer Entropy is data-driven and does not rely on specific assumptions about neuronal firing statistics or network topology. We generate simulated calcium signals from networks with controlled ground-truth topology and purely excitatory interactions and show that, by restricting the analysis to inter-bursts periods, Transfer Entropy robustly achieves a good reconstruction performance for disparate network connectivities. Finally, we apply our method to real data and find evidence of non-random features in cultured networks, such as the existence of highly connected hub excitatory neurons and of an elevated (but not extreme) level of clustering.

Published
2012

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