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1. State-dependent complexity of the local field potential in the primary visual cortex

Author

Jungmann, Rafael M., Feliciano, Thaís, Aguiar, Leandro A. A., Soares-Cunha, Carina, Coimbra, Bárbara, Rodrigues, Ana João, Copelli, Mauro, Matias, Fernanda S., de Vasconcelos, Nivaldo A. P., and Carelli, Pedro V.

Subjects
Quantitative Biology - Neurons and Cognition, Physics - Biological Physics
Abstract

The local field potential (LFP) is as a measure of the combined activity of neurons within a region of brain tissue. While biophysical modeling schemes for LFP in cortical circuits are well established, there is a paramount lack of understanding regarding the LFP properties along the states assumed in cortical circuits over long periods. Here we use a symbolic information approach to determine the statistical complexity based on Jensen disequilibrium measure and Shannon entropy of LFP data recorded from the primary visual cortex (V1) of urethane-anesthetized rats and freely moving mice. Using these information quantifiers, we find consistent relations between LFP recordings and measures of cortical states at the neuronal level. More specifically, we show that LFP's statistical complexity is sensitive to cortical state (characterized by spiking variability), as well as to cortical layer. In addition, we apply these quantifiers to characterize behavioral states of freely moving mice, where we find indirect relations between such states and spiking variability.

Published
2023

2. Feedforward and feedback influences through distinct frequency bands between two spiking-neuron networks

Author

Porta, Leonardo Dalla, Castro, Daniel M., Copelli, Mauro, Carelli, Pedro V., and Matias, Fernanda S.

Subjects
Quantitative Biology - Neurons and Cognition
Abstract

Several studies with brain signals suggested that bottom-up and top-down influences are exerted through distinct frequency bands among visual cortical areas. It has been recently shown that theta and gamma rhythms subserve feedforward, whereas the feedback influence is dominated by the alpha-beta rhythm in primates. A few theoretical models for reproducing these effects have been proposed so far. Here we show that a simple but biophysically plausible two-network motif composed of spiking-neuron models and chemical synapses can exhibit feedforward and feedback influences through distinct frequency bands. Differently from previous studies, this kind of model allows us to study directed influences not only at the population level, by using a proxy for the local field potential, but also at the cellular level, by using the neuronal spiking series.

Published
2021
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3. Statistical complexity is maximized close to criticality in cortical dynamics

Author

Lotfi, Nastaran, Feliciano, Thaís, Aguiar, Leandro A. A., Silva, Thais Priscila Lima, Carvalho, Tawan T. A., Rosso, Osvaldo A., Copelli, Mauro, Matias, Fernanda S., and Carelli, Pedro V.

Subjects
Quantitative Biology - Neurons and Cognition
Abstract

Complex systems are typically characterized as an intermediate situation between a complete regular structure and a random system. Brain signals can be studied as a striking example of such systems: cortical states can range from highly synchronous and ordered neuronal activity (with higher spiking variability) to desynchronized and disordered regimes (with lower spiking variability). It has been recently shown, by testing independent signatures of criticality, that a phase transition occurs in a cortical state of intermediate spiking variability. Here, we use a symbolic information approach to show that, despite the monotonical increase of the Shannon entropy between ordered and disordered regimes, we can determine an intermediate state of maximum complexity based on the Jensen disequilibrium measure. More specifically, we show that statistical complexity is maximized close to criticality for cortical spiking data of urethane-anesthetized rats, as well as for a network model of excitable elements that presents a critical point of a non-equilibrium phase transition., Comment: 8 pages, 6 figures

Published
2020
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4. Anticipated synchronization in human EEG data: unidirectional causality with negative phase-lag

Author

Carlos, Francisco-Leandro P., Ubirakitan, Maciel-Monteiro, Rodrigues, Marcelo Cairrão Araújo, Aguilar-Domingo, Moisés, Herrera-Gutiérrez, Eva, Gómez-Amor, Jesús, Copelli, Mauro, Carelli, Pedro V., and Matias, Fernanda S.

Subjects
Quantitative Biology - Neurons and Cognition, Physics - Biological Physics
Abstract

Understanding the functional connectivity of the brain has become a major goal of neuroscience. In many situatons, the relative phase difference, together with coherence patterns, have been employed to infer the direction of the information flow. However, it has been recently shown in local field potential data from monkeys the existence of a synchronized regime in which unidirectionally coupled areas can present both positive and negative phase differences. During the counterintuitive regime, called anticipated synchronization (AS), the phase difference does not reflect the causality. Here we investigate coherence and causality at the alpha frequency band (10 Hz) between pairs of electroencephalogram (EEG) electrodes in humans during a GO/NO-GO task. We show that human EEG signals can exhibit anticipated synchronization, which is characterized by a unidirectional influence from an electrode A to an electrode B, but the electrode B leads the electrode A in time. To the best of our knowledge, this is the first verification of AS in EEG signals and in the human brain. The usual delayed synchronization (DS) regime is also present between many pairs. DS is characterized by a unidirectional influence from an electrode A to an electrode B and a positive phase difference between A and B which indicates that the electrode A leads the electrode B in time. Moreover, we show that EEG signals exhibit diversity in phase relations: the pairs of electrodes can present in-phase, anti-phase, or out-of-phase synchronization with a similar distribution of positive and negative phase differences.

Published
2020
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5. Subsampled directed-percolation models explain scaling relations experimentally observed in the brain

Author

Carvalho, Tawan T. A., Fontenele, Antonio J., Girardi-Schappo, Mauricio, Feliciano, Thais, Aguiar, Leandro A. A., Silva, Thais P. L., de Vasconcelos, Nivaldo A. P., Carelli, Pedro V., and Copelli, Mauro

Subjects
Quantitative Biology - Neurons and Cognition, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics, Nonlinear Sciences - Adaptation and Self-Organizing Systems, Physics - Biological Physics
Abstract

Recent experimental results on spike avalanches measured in the urethane-anesthetized rat cortex have revealed scaling relations that indicate a phase transition at a specific level of cortical firing rate variability. The scaling relations point to critical exponents whose values differ from those of a branching process, which has been the canonical model employed to understand brain criticality. This suggested that a different model, with a different phase transition, might be required to explain the data. Here we show that this is not necessarily the case. By employing two different models belonging to the same universality class as the branching process (mean-field directed percolation) and treating the simulation data exactly like experimental data, we reproduce most of the experimental results. We find that subsampling the model and adjusting the time bin used to define avalanches (as done with experimental data) are sufficient ingredients to change the apparent exponents of the critical point. Moreover, experimental data is only reproduced within a very narrow range in parameter space around the phase transition., Comment: 15 pages, 9 figures, submitted to Frontiers Neural Circuits

Published
2020
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6. Signatures of brain criticality unveiled by maximum entropy analysis across cortical states

Author

Lotfi, Nastaran, Fontenele, Antonio J., Feliciano, Thaís, Aguiar, Leandro A. A., de Vasconcelos, Nivaldo A. P., Soares-Cunha, Carina, Coimbra, Bárbara, Rodrigues, Ana João, Sousa, Nuno, Copelli, Mauro, and Carelli, Pedro V.

Subjects
Quantitative Biology - Neurons and Cognition, Physics - Biological Physics
Abstract

It has recently been reported that statistical signatures of brain criticality, obtained from distributions of neuronal avalanches, can depend on the cortical state. We revisit these claims with a completely different and independent approach, employing a maximum entropy model to test whether signatures of criticality appear in urethane-anesthetized rats. To account for the spontaneous variation of cortical state, we parse the time series and perform the maximum entropy analysis as a function of the variability of the population spiking activity. To compare data sets with different number of neurons, we define a normalized distance to criticality that takes into account the peak and width of the specific heat curve. We found an universal collapse of the normalized distance to criticality dependence on the cortical state on an animal by animal basis. This indicates a universal dynamics and a critical point at an intermediate value of spiking variability.

Published
2020
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7. Deterministic chaos in an ytterbium-doped mode-locked fiber laser

Author

Mélo, Lucas B. A., Palacios, Guillermo F. R., Carelli, Pedro V., Acioli, Lúcio H., Leite, José R. Rios, and de Miranda, Marcio H. G.

Subjects
Physics - Optics, Nonlinear Sciences - Chaotic Dynamics
Abstract

We experimentally study the nonlinear dynamics of a femtosecond ytterbium doped mode-locked fiber laser. With the laser operating in the pulsed regime a route to chaos is presented, starting from stable mode-locking, period two, period four, chaos and period three regimes. Return maps and bifurcation diagrams were extracted from time series for each regime. The analysis of the time series with the laser operating in the quasi mode-locked regime presents deterministic chaos described by an unidimensional Rossler map. A positive Lyapunov exponent $\lambda = 0.14$ confirms the deterministic chaos of the system. We suggest an explanation about the observed map by relating gain saturation and intra-cavity loss.

Published
2018
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8. Anticipated synchronization in neuronal circuits unveiled by a phase-resetting curve analysis

Author

Matias, Fernanda S., Carelli, Pedro V., Mirasso, Claudio R., and Copelli, Mauro

Subjects
Quantitative Biology - Neurons and Cognition, Physics - Biological Physics
Abstract

Anticipated synchronization (AS) is a counter intuitive behavior that has been observed in several systems. When AS establishes in a sender-receiver configuration, the latter can predict the future dynamics of the former for certain parameter values. In particular, in neuroscience AS was proposed to explain the apparent discrepancy between information flow and time lag in the cortical activity recorded in monkeys. Despite its success, a clear understanding on the mechanisms yielding AS in neuronal circuits is still missing. Here we use the well-known phase-resetting-curve (PRC) approach to study the prototypical sender-receiver-interneuron neuronal motif. Our aim is to better understand how the transitions between delayed to anticipated synchronization and anticipated synchronization to phase-drift regimes occur. We construct a map based on the PRC method to predict the phase-locking regimes and their stability. We find that a PRC function of two variables, accounting simultaneously for the inputs from sender and interneuron into the receiver, is essential to reproduce the numerical results obtained using a Hodgkin-Huxley model for the neurons. On the contrary, the typical approximation that considers a sum of two independent single-variable PRCs fails for intermediate to high values of the inhibitory connectivity between interneuron. In particular, it looses the delayed-synchronization to anticipated-synchronization transition.

Published
2017
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10. Inhibitory loop robustly induces anticipated synchronization in neuronal microcircuits

Author

Matias, Fernanda S., Gollo, Leonardo L., Carelli, Pedro V., Mirasso, Claudio R., and Copelli, Mauro

Subjects
Quantitative Biology - Neurons and Cognition
Abstract

We investigate the synchronization properties between two excitatory coupled neurons in the presence of an inhibitory loop mediated by an interneuron. Dynamical inhibition together with noise independently applied to each neuron provide phase diversity in the dynamics of the neuronal motif. We show that the interplay between the coupling strengths and external noise controls the phase relations between the neurons in a counter-intuitive way. For a master-slave configuration (unidirectional coupling) we find that the slave can anticipate the master, on average, if the slave is subject to the inhibitory feedback. In this non-usual regime, called anticipated synchronization (AS), the phase of the post-synaptic neuron is advanced with respect to that of the pre-synaptic neuron. We also show that the AS regime survives even in the presence of unbalanced bidirectional excitatory coupling. Moreover, for the symmetric mutually coupled situation, the neuron that is subject to the inhibitory loop leads in phase.

Published
2016
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11. Anticipated Synchronization in a Biologically Plausible Model of Neuronal Motifs

Author

Matias, Fernanda S., Carelli, Pedro V., Mirasso, Claudio R., and Copelli, Mauro

Subjects
Quantitative Biology - Neurons and Cognition, Physics - Biological Physics, Physics - Computational Physics
Abstract

Two identical autonomous dynamical systems coupled in a master-slave configuration can exhibit anticipated synchronization (AS) if the slave also receives a delayed negative self-feedback. Recently, AS was shown to occur in systems of simplified neuron models, requiring the coupling of the neuronal membrane potential with its delayed value. However, this coupling has no obvious biological correlate. Here we propose a canonical neuronal microcircuit with standard chemical synapses, where the delayed inhibition is provided by an interneuron. In this biologically plausible scenario, a smooth transition from delayed synchronization (DS) to AS typically occurs when the inhibitory synaptic conductance is increased. The phenomenon is shown to be robust when model parameters are varied within physiological range. Since the DS-AS transition amounts to an inversion in the timing of the pre- and post-synaptic spikes, our results could have a bearing on spike-timing-dependent-plasticity models.

Published
2011
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24. Signatures of brain criticality unveiled by maximum entropy analysis across cortical states

Author

Lotfi, Nastaran, primary, Fontenele, Antonio J., additional, Feliciano, Thaís, additional, Aguiar, Leandro A. A., additional, de Vasconcelos, Nivaldo A. P., additional, Soares-Cunha, Carina, additional, Coimbra, Bárbara, additional, Rodrigues, Ana João, additional, Sousa, Nuno, additional, Copelli, Mauro, additional, and Carelli, Pedro V., additional

Published
2020
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25. Open hardware low-cost system for behavioral experiments simultaneously with electrophysiological recordings

Author

Aguiar, Leandro A. A., de Vasconcelos, Nivaldo A P, Tunes, Gabriela Chiuffa, Fontenele, Antonio J., Reyes, Marcelo Bussotti, de Albuquerque Nogueira, Romildo, and Carelli, Pedro V.

Abstract

A major frontier in neuroscience is to find neural correlates of perception, learning, decision making, and a variety of other types of behavior. In the last decades, modern devices have provided to simultaneously record not only the different responses but also the electrical activity of large neuronal populations. However, the commercially available instruments for behavioral recordings are expensive, and the design of low-cost operate condition chamber has emerged as an appealing alternative to resource-limited laboratories engaged in animal behavior. In this article, we provide a full description of an experimental platform for simultaneously recording behavior and electrical activity of a neural population. The programming of this platform is open source and flexible so that any behavioral task can be implemented. We show examples of behavioral experiments with freely moving rats with simultaneous electrophysiological recordings.

Published
2019
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26. Exploring the Phase-Locking Mechanisms Yielding Delayed and Anticipated Synchronization in Neuronal Circuits

Author

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (Brasil), Agencia Estatal de Investigación (España), Conselho Nacional de Desenvolvimento Científico e Tecnológico (Brasil), Fundação de Amparo à Pesquisa do Estado de São Paulo, Fundação de Amparo à Ciência e Tecnologia do Estado de Pernambuco, Ministerio de Ciencia, Innovación y Universidades (España), Dalla Porta, Leonardo, Matias, Fernanda S., do Santos, Alfredo, J., Alonso, Ana, Carelli, Pedro V., Copelli, Mauro, Mirasso, Claudio R., Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (Brasil), Agencia Estatal de Investigación (España), Conselho Nacional de Desenvolvimento Científico e Tecnológico (Brasil), Fundação de Amparo à Pesquisa do Estado de São Paulo, Fundação de Amparo à Ciência e Tecnologia do Estado de Pernambuco, Ministerio de Ciencia, Innovación y Universidades (España), Dalla Porta, Leonardo, Matias, Fernanda S., do Santos, Alfredo, J., Alonso, Ana, Carelli, Pedro V., Copelli, Mauro, and Mirasso, Claudio R.

Abstract

Synchronization is one of the brain mechanisms allowing the coordination of neuronal activity required in many cognitive tasks. Anticipated Synchronization (AS) is a specific type of out-of-phase synchronization that occurs when two systems are unidirectionally coupled and, consequently, the information is transmitted from the sender to the receiver, but the receiver leads the sender in time. It has been shown that the primate cortex could operate in a regime of AS as part of normal neurocognitive function. However it is still unclear what is the mechanism that gives rise to anticipated synchronization in neuronal motifs. Here, we investigate the synchronization properties of cortical motifs on multiple scales and show that the internal dynamics of the receiver, which is related to its free running frequency in the uncoupled situation, is the main ingredient for AS to occur. For biologically plausible parameters, including excitation/inhibition balance, we found that the phase difference between the sender and the receiver decreases when the free running frequency of the receiver increases. As a consequence, the system switches from the usual delayed synchronization (DS) regime to an AS regime. We show that at three different scales, neuronal microcircuits, spiking neuronal populations and neural mass models, both the inhibitory loop and the external current acting on the receiver mediate the DS-AS transition for the sender-receiver configuration by changing the free running frequency of the receiver. Therefore, we propose that a faster internal dynamics of the receiver system is the main mechanism underlying anticipated synchronization in brain circuits.

Published
2019

29. Criticality between Cortical States

Author

Fontenele, Antonio J., primary, de Vasconcelos, Nivaldo A. P., additional, Feliciano, Thaís, additional, Aguiar, Leandro A. A., additional, Soares-Cunha, Carina, additional, Coimbra, Bárbara, additional, Dalla Porta, Leonardo, additional, Ribeiro, Sidarta, additional, Rodrigues, Ana João, additional, Sousa, Nuno, additional, Carelli, Pedro V., additional, and Copelli, Mauro, additional

Published
2019
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30. Criticality between cortical states

Author

Fontenele, Antonio J., primary, de Vasconcelos, Nivaldo A. P., additional, Feliciano, Thaís, additional, Aguiar, Leandro A. A., additional, Soares-Cunha, Carina, additional, Coimbra, Bárbara, additional, Porta, Leonardo Dalla, additional, Ribeiro, Sidarta, additional, Rodrigues, Ana João, additional, Sousa, Nuno, additional, Carelli, Pedro V., additional, and Copelli, Mauro, additional

Published
2018
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32. Anticipated and zero-lag synchronization in motifs of delay-coupled systems

Author

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (Brasil), Conselho Nacional de Desenvolvimento Científico e Tecnológico (Brasil), Fundação de Amparo à Ciência e Tecnologia do Estado de Pernambuco, Ministerio de Economía y Competitividad (España), Fundação de Amparo à Pesquisa do Estado de São Paulo, Centro de Ciências Matemáticas Aplicadas à Indústria (Brasil), Mirasso, Claudio R., Carelli, Pedro V., Pereira, Tiago, Matias, Fernanda S., Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (Brasil), Conselho Nacional de Desenvolvimento Científico e Tecnológico (Brasil), Fundação de Amparo à Ciência e Tecnologia do Estado de Pernambuco, Ministerio de Economía y Competitividad (España), Fundação de Amparo à Pesquisa do Estado de São Paulo, Centro de Ciências Matemáticas Aplicadas à Indústria (Brasil), Mirasso, Claudio R., Carelli, Pedro V., Pereira, Tiago, and Matias, Fernanda S.

Abstract

Anticipated and zero-lag synchronization have been observed in different scientific fields. In the brain, they might play a fundamental role in information processing, temporal coding and spatial attention. Recent numerical work on anticipated and zero-lag synchronization studied the role of delays. However, an analytical understanding of the conditions for these phenomena remains elusive. In this paper, we study both phenomena in systems with small delays. By performing a phase reduction and studying phase locked solutions, we uncover the functional relation between the delay, excitation and inhibition for the onset of anticipated synchronization in a sender-receiver-interneuron motif. In the case of zero-lag synchronization in a chain motif, we determine the stability conditions. These analytical solutions provide an excellent prediction of the phase-locked regimes of Hodgkin-Huxley models and Roessler oscillators. Anticipated and zero-lag synchronization are phenomena that are believed to play important roles in the brain, with evidence suggesting that they occur despite the conductance delay between cortical areas. Both synchronization regimes were reported in numerical simulations of motifs of three-node neuronal systems coupled with delay. Here, we present an analytical approach to these problems by performing a phase reduction leading to a phase oscillator model. Since neurons have firing rates of the order of tens of Hertz and conduction delays are in the range of tens of milliseconds, the regime of small delays (less than the period of free-running units) is justified and simplifies the calculations. In this framework, three regimes are predicted to occur as inhibition is increased in a sender-receiver-interneuron (SRI) motif: delayed synchronization (DS), anticipated synchronization (AS), and finally phase drift. Varying the delay in a chain motif of three mutually connected units, on the other hand, the locking between the central and the outer nodes is s

Published
2017

35. Inhibitory loop robustly induces anticipated synchronization in neuronal microcircuits

Author

Conselho Nacional de Desenvolvimento Científico e Tecnológico (Brasil), Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (Brasil), Fundação de Amparo à Pesquisa do Estado de São Paulo, Ministerio de Economía y Competitividad (España), Matias, Fernanda S., Gollo, Leonardo L., Carelli, Pedro V., Mirasso, Claudio R., Copelli, Mauro, Conselho Nacional de Desenvolvimento Científico e Tecnológico (Brasil), Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (Brasil), Fundação de Amparo à Pesquisa do Estado de São Paulo, Ministerio de Economía y Competitividad (España), Matias, Fernanda S., Gollo, Leonardo L., Carelli, Pedro V., Mirasso, Claudio R., and Copelli, Mauro

Abstract

We investigate the synchronization properties between two excitatory coupled neurons in the presence of an inhibitory loop mediated by an interneuron. Dynamic inhibition together with noise independently applied to each neuron provide phase diversity in the dynamics of the neuronal motif. We show that the interplay between the coupling strengths and the external noise controls the phase relations between the neurons in a counterintuitive way. For a master-slave configuration (unidirectional coupling) we find that the slave can anticipate the master, on average, if the slave is subject to the inhibitory feedback. In this nonusual regime, called anticipated synchronization (AS), the phase of the postsynaptic neuron is advanced with respect to that of the presynaptic neuron. We also show that the AS regime survives even in the presence of unbalanced bidirectional excitatory coupling. Moreover, for the symmetric mutually coupled situation, the neuron that is subject to the inhibitory loop leads in phase.

Published
2016

38. Self-organized near-zero-lag synchronization induced by spike-timing dependent plasticity in cortical populations

Author

Fundação de Amparo à Pesquisa do Estado de São Paulo, Fundação de Amparo à Ciência e Tecnologia do Estado de Pernambuco, Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (Brasil), Ministerio de Economía y Competitividad (España), European Commission, Conselho Nacional de Desenvolvimento Científico e Tecnológico (Brasil), Matias, Fernanda S., Carelli, Pedro V., Mirasso, Claudio R., Copelli, Mauro, Fundação de Amparo à Pesquisa do Estado de São Paulo, Fundação de Amparo à Ciência e Tecnologia do Estado de Pernambuco, Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (Brasil), Ministerio de Economía y Competitividad (España), European Commission, Conselho Nacional de Desenvolvimento Científico e Tecnológico (Brasil), Matias, Fernanda S., Carelli, Pedro V., Mirasso, Claudio R., and Copelli, Mauro

Abstract

Several cognitive tasks related to learning and memory exhibit synchronization of macroscopic cortical areas together with synaptic plasticity at neuronal level. Therefore, there is a growing effort among computational neuroscientists to understand the underlying mechanisms relating synchrony and plasticity in the brain. Here we numerically study the interplay between spike-timing dependent plasticity (STDP) and anticipated synchronization (AS). AS emerges when a dominant flux of information from one area to another is accompanied by a negative time lag (or phase). This means that the receiver region pulses before the sender does. In this paper we study the interplay between different synchronization regimes and STDP at the level of three-neuron microcircuits as well as cortical populations. We show that STDP can promote auto-organized zero-lag synchronization in unidirectionally coupled neuronal populations. We also find synchronization regimes with negative phase difference (AS) that are stable against plasticity. Finally, we show that the interplay between negative phase difference and STDP provides limited synaptic weight distribution without the need of imposing artificial boundaries. Copyright

Published
2015

41. Modeling positive Granger causality and negative phase lag between cortical areas

Author

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (Brasil), Conselho Nacional de Desenvolvimento Científico e Tecnológico (Brasil), Fundação de Amparo à Ciência e Tecnologia do Estado de Pernambuco, Ministerio de Economía y Competitividad (España), European Commission, Govern de les Illes Balears, Matias, Fernanda S., Gollo, Leonardo L., Carelli, Pedro V., Bressler, Steven L., Copelli, Mauro, Mirasso, Claudio R., Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (Brasil), Conselho Nacional de Desenvolvimento Científico e Tecnológico (Brasil), Fundação de Amparo à Ciência e Tecnologia do Estado de Pernambuco, Ministerio de Economía y Competitividad (España), European Commission, Govern de les Illes Balears, Matias, Fernanda S., Gollo, Leonardo L., Carelli, Pedro V., Bressler, Steven L., Copelli, Mauro, and Mirasso, Claudio R.

Abstract

Different measures of directional influence have been employed to infer effective connectivity in the brain. When the connectivity between two regions is such that one of them (the sender) strongly influences the other (the receiver), a positive phase lag is often expected. The assumption is that the time difference implicit in the relative phase reflects the transmission time of neuronal activity. However, Brovelli et al. (2004) observed that, in monkeys engaged in processing a cognitive task, a dominant directional influence from one area of sensorimotor cortex to another may be accompanied by either a negative or a positive time delay. Here we present a model of two brain regions, coupled with a well-defined directional influence, that displays similar features to those observed in the experimental data. This model is inspired by the theoretical framework of Anticipated Synchronization developed in the field of dynamical systems. Anticipated Synchronization is a form of synchronization that occurs when a unidirectional influence is transmitted from a sender to a receiver, but the receiver leads the sender in time. This counterintuitive synchronization regime can be a stable solution of two dynamical systems coupled in a master-slave (sender-receiver) configuration when the slave receives a negative delayed self-feedback. Despite efforts to understand the dynamics of Anticipated Synchronization, experimental evidence for it in the brain has been lacking. By reproducing experimental delay times and coherence spectra, our results provide a theoretical basis for the underlying mechanisms of the observed dynamics, and suggest that the primate cortex could operate in a regime of Anticipated Synchronization as part of normal neurocognitive function. © 2014 Elsevier Inc.

Published
2014

43. Anticipated synchronization in a biologically plausible model of neuronal motifs

Author

Matías, Manuel A., Carelli, Pedro V., Mirasso, Claudio R., Copelli, Mauro, Matías, Manuel A., Carelli, Pedro V., Mirasso, Claudio R., and Copelli, Mauro

Abstract

Two identical autonomous dynamical systems coupled in a master-slave configuration can exhibit anticipated synchronization (AS) if the slave also receives a delayed negative self-feedback. Recently, AS was shown to occur in systems of simplified neuron models, requiring the coupling of the neuronal membrane potential with its delayed value. However, this coupling has no obvious biological correlate. Here we propose a canonical neuronal microcircuit with standard chemical synapses, where the delayed inhibition is provided by an interneuron. In this biologically plausible scenario, a smooth transition from delayed synchronization (DS) to AS typically occurs when the inhibitory synaptic conductance is increased. The phenomenon is shown to be robust when model parameters are varied within a physiological range. Since the DS-AS transition amounts to an inversion in the timing of the pre- and post-synaptic spikes, our results could have a bearing on spike-timing-dependent plasticity models

Published
2011

48. Single Synapse Information Coding in Intraburst Spike Patterns of Central Pattern Generator Motor Neurons.

Author

Brochini, Ludmila, Carelli, Pedro V., and Pinto, Reynaldo D.

Subjects
*MOTOR neurons, *CENTRAL nervous system stimulants, *SYNAPSES, *NEURAL circuitry, *NEURAL transmission
Abstract

Burst firing is ubiquitous in nervous systems and has been intensively studied in central pattern generators (CPGs). Previous works have described subtle intraburst spike patterns (IBSPs) that, despite being traditionally neglected for their lack of relation to CPG motor function, were shown to be cell-type specific and sensitive to CPG connectivity. Here we address this matter by investigating how a bursting motor neuron expresses information about other neurons in the network. We performed experiments on the crustacean stomatogastric pyloric CPG, both in control conditions and interacting in real-time with computer model neurons. The sensitivity of postsynaptic to presynaptic IBSPs was inferred by computing their average mutual information along each neuron burst. We found that details of input patterns are nonlinearly and inhomogeneously coded through a single synapse into the fine IBSPs structure of the postsynaptic neuron following burst. In this way, motor neurons are able to use different time scales to convey two types of information simultaneously: muscle contraction (related to bursting rhythm) and the behavior of other CPG neurons (at a much shorter timescale by using IBSPs as information carriers). Moreover, the analysis revealed that the coding mechanism described takes part in a previously unsuspected information pathway from a CPG motor neuron to a nerve that projects to sensory brain areas, thus providing evidence of the general physiological role of information coding through IBSPs in the regulation of neuronal firing patterns in remote circuits by the CNS. [ABSTRACT FROM AUTHOR]

Published
2011
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49. Maximum-entropy-based metrics for quantifying critical dynamics in spiking neuron data.

Author

Serafim F, Carvalho TTA, Copelli M, and Carelli PV

Subjects
Animals, Rats, Neurons physiology, Neurons cytology, Entropy, Models, Neurological, Action Potentials
Abstract

An important working hypothesis to investigate brain activity is whether it operates in a critical regime. Recently, maximum-entropy phenomenological models have emerged as an alternative way of identifying critical behavior in neuronal data sets. In the present paper, we investigate the signatures of criticality from a firing rate-based maximum-entropy approach on data sets generated by computational models, and we compare them to experimental results. We found that the maximum entropy approach consistently identifies critical behavior around the phase transition in models and rules out criticality in models without phase transition. The maximum-entropy-model results are compatible with results for cortical data from urethane-anesthetized rats data, providing further support for criticality in the brain.

Published
2024
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50. State-dependent complexity of the local field potential in the primary visual cortex.

Author

Jungmann RM, Feliciano T, Aguiar LAA, Soares-Cunha C, Coimbra B, Rodrigues AJ, Copelli M, Matias FS, de Vasconcelos NAP, and Carelli PV

Subjects
Animals, Mice, Rats, Action Potentials, Neurons physiology, Visual Cortex physiology, Visual Cortex cytology, Models, Neurological, Primary Visual Cortex physiology, Primary Visual Cortex cytology
Abstract

The local field potential (LFP) is as a measure of the combined activity of neurons within a region of brain tissue. While biophysical modeling schemes for LFP in cortical circuits are well established, there is a paramount lack of understanding regarding the LFP properties along the states assumed in cortical circuits over long periods. Here we use a symbolic information approach to determine the statistical complexity based on Jensen disequilibrium measure and Shannon entropy of LFP data recorded from the primary visual cortex (V1) of urethane-anesthetized rats and freely moving mice. Using these information quantifiers, we find consistent relations between LFP recordings and measures of cortical states at the neuronal level. More specifically, we show that LFP's statistical complexity is sensitive to cortical state (characterized by spiking variability), as well as to cortical layer. In addition, we apply these quantifiers to characterize behavioral states of freely moving mice, where we find indirect relations between such states and spiking variability.

Published
2024
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