Your search keyword '"Paik, Se-Bum"' showing total 2 results

1. Synaptic Plasticity Controls Sensory Responses through Frequency-Dependent Gamma Oscillation Resonance.

Author

Paik, Se-Bum and Glaser, Donald A.

Subjects

*BIOLOGICAL neural networks, *PHENOTYPIC plasticity, *NEUROPLASTICITY, *VISUAL cortex, *NEURAL circuitry, *COGNITIVE neuroscience

Abstract

Synchronized gamma frequency oscillations in neural networks are thought to be important to sensory information processing, and their effects have been intensively studied. Here we describe a mechanism by which the nervous system can readily control gamma oscillation effects, depending selectively on visual stimuli. Using a model neural network simulation, we found that sensory response in the primary visual cortex is significantly modulated by the resonance between "spontaneous" and "stimulus-driven" oscillations. This gamma resonance can be precisely controlled by the synaptic plasticity of thalamocortical connections, and cortical response is regulated differentially according to the resonance condition. The mechanism produces a selective synchronization between the afferent and downstream neural population. Our simulation results explain experimental observations such as stimulus-dependent synchronization between the thalamus and the cortex at different oscillation frequencies. The model generally shows how sensory information can be selectively routed depending on its frequency components. [ABSTRACT FROM AUTHOR]

Published

2010

2. Spontaneous Local Gamma Oscillation Selectively Enhances Neural Network Responsiveness.

Author

Paik, Se-Bum, Kumar, Tribhawan, and Glaser, Donald A.

Subjects

*BIOLOGICAL neural networks, *VISUAL cortex, *CELL communication, *CELLULAR control mechanisms, *NEURONS

Abstract

Synchronized oscillation is very commonly observed in many neuronal systems and might play an important role in the response properties of the system. We have studied how the spontaneous oscillatory activity affects the responsiveness of a neuronal network, using a neural network model of the visual cortex built from Hodgkin-Huxley type excitatory (E-) and inhibitory (I-) neurons. When the isotropic local E-I and I-E synaptic connections were sufficiently strong, the network commonly generated gamma frequency oscillatory firing patterns in response to random feed-forward (FF) input spikes. This spontaneous oscillatory network activity injects a periodic local current that could amplify a weak synaptic input and enhance the network's responsiveness. When E-E connections were added, we found that the strength of oscillation can be modulated by varying the FF input strength without any changes in single neuron properties or interneuron connectivity. The response modulation is proportional to the oscillation strength, which leads to self-regulation such that the cortical network selectively amplifies various FF inputs according to its strength, without requiring any adaptation mechanism. We show that this selective cortical amplification is controlled by E-E cell interactions. We also found that this response amplification is spatially localized, which suggests that the responsiveness modulation may also be spatially selective. This suggests a generalized mechanism by which neural oscillatory activity can enhance the selectivity of a neural network to FF inputs. [ABSTRACT FROM AUTHOR]

Published

2009