Your search keyword '"Mejias, Jorge F."' showing total 3 results

1. Learning Contrast-Invariant Cancellation of Redundant Signals in Neural Systems.

Author

Mejias, Jorge F., Marsat, Gary, Bol, Kieran, Maler, Leonard, and Longtin, André

Subjects

*NEURAL circuitry, *NERVOUS system, *REFLEXES, *NEURAL transmission, *SYNAPSES, *SENSE organs, *PHYSIOLOGY

Abstract

Cancellation of redundant information is a highly desirable feature of sensory systems, since it would potentially lead to a more efficient detection of novel information. However, biologically plausible mechanisms responsible for such selective cancellation, and especially those robust to realistic variations in the intensity of the redundant signals, are mostly unknown. In this work, we study, via in vivo experimental recordings and computational models, the behavior of a cerebellar-like circuit in the weakly electric fish which is known to perform cancellation of redundant stimuli. We experimentally observe contrast invariance in the cancellation of spatially and temporally redundant stimuli in such a system. Our model, which incorporates heterogeneously-delayed feedback, bursting dynamics and burst-induced STDP, is in agreement with our in vivo observations. In addition, the model gives insight on the activity of granule cells and parallel fibers involved in the feedback pathway, and provides a strong prediction on the parallel fiber potentiation time scale. Finally, our model predicts the existence of an optimal learning contrast around 15% contrast levels, which are commonly experienced by interacting fish. [ABSTRACT FROM AUTHOR]

Published

2013

2. Emergence of Resonances in Neural Systems: The Interplay between Adaptive Threshold and Short-Term Synaptic Plasticity.

Author

Mejias, Jorge F. and Torres, Joaquin J.

Subjects

*NEUROPLASTICITY, *RESONANCE, *NEURAL circuitry, *SYNAPSES, *STOCHASTIC resonance, *PHENOMENOLOGY, *NEURAL transmission

Abstract

In this work we study the detection of weak stimuli by spiking (integrate-and-fire) neurons in the presence of certain level of noisy background neural activity. Our study has focused in the realistic assumption that the synapses in the network present activity-dependent processes, such as short-term synaptic depression and facilitation. Employing mean-field techniques as well as numerical simulations, we found that there are two possible noise levels which optimize signal transmission. This new finding is in contrast with the classical theory of stochastic resonance which is able to predict only one optimal level of noise. We found that the complex interplay between adaptive neuron threshold and activity-dependent synaptic mechanisms is responsible for this new phenomenology. Our main results are confirmed by employing a more realistic FitzHugh-Nagumo neuron model, which displays threshold variability, as well as by considering more realistic stochastic synaptic models and realistic signals such as poissonian spike trains. [ABSTRACT FROM AUTHOR]

Published

2011

3. Irregular Dynamics in Up and Down Cortical States.

Author

Mejias, Jorge F., Kappen, Hilbert J., and Torres, Joaquin J.

Subjects

*BIOLOGICAL neural networks, *NOISE, *NEURAL transmission, *STOCHASTIC models, *MATHEMATICAL models, *SYNAPSES, *NEURAL circuitry, *SOMATOSENSORY evoked potentials, *COMPUTER simulation

Abstract

Complex coherent dynamics is present in a wide variety of neural systems. A typical example is the voltage transitions between up and down states observed in cortical areas in the brain. In this work, we study this phenomenon via a biologically motivated stochastic model of up and down transitions. The model is constituted by a simple bistable rate dynamics, where the synaptic current is modulated by short-term synaptic processes which introduce stochasticity and temporal correlations. A complete analysis of our model, both with mean-field approaches and numerical simulations, shows the appearance of complex transitions between high (up) and low (down) neural activity states, driven by the synaptic noise, with permanence times in the up state distributed according to a power-law. We show that the experimentally observed large fluctuation in up and down permanence times can be explained as the result of sufficiently noisy dynamical synapses with sufficiently large recovery times. Static synapses cannot account for this behavior, nor can dynamical synapses in the absence of noise. [ABSTRACT FROM AUTHOR]

Published

2010