Membrane potential resonance in non-oscillatory neurons interacts with synaptic connectivity to produce network oscillations

Abstract: Several neuron types have been shown to exhibit (subthreshold) membrane potential resonance (MPR), defined as the occurrence of a peak in their voltage amplitude response to oscillatory input currents at a preferred (resonant) frequency. MPR has been investigated both experimentally and theoretically. However, whether MPR is simply an epiphenomenon or it plays a functional role for the generation of neuronal network oscillations and how the latent time scales present in individual, non-oscillatory cells affect… Show more

“…To study the effects of f res on f ntw we follow [4,12] and change the model parameters in such a way that f res changes but Z max remains constant. In particular, we consider a fixed value of g L,1 , and various balanced combinations of values of g 1 and τ 1 so as to increase f res and maintain Z max constant.…”

“…In addition to the single-cell mechanisms of generation of oscillations described above, oscillations can be generated at the network level in mutually connected cells that do not exhibit sustained oscillations when disconnected, but they are rather damped oscillators or resonators [4,48,88,93]. The graded synaptic connectivity used in these studies has been assumed to be instantaneously fast and to have no dynamics.…”

“…In [4] we have identified a minimal (3D) network model consisting of a two-dimensional resonator and a one-dimensional passive cell mutually connected through graded inhibition. Oscillations are also obtained in self-excited resonators (2D), mutually excited resonators (4D) and mutually inhibited resonators (4D), also using graded synaptic connectivity.…”

“…In self-excited networks, self-excitation provides the amplifying process necessary for the generation of oscillations. In fact, self-excited resonators have the same mathematical structure as single neurons having both resonant and amplifying ionic processes whose dynamics are also 2D [4]. Mutually excited resonators exhibit synchronized in-phase patterns and therefore their dynamics are captured by those of self-excited resonators.…”

“…Subsequently, we show how the resonant frequency of the individual 2D resonator affects the network oscillation frequency. Finally, we review some results obtained in [4] for smooth connectivity functions, discuss the existence of relaxation oscillations and the associated canard phenomenon, and compare the oscillatory properties of networks having smooth and PWL connectivity functions. We conclude in Section 4 by discussing our results, their implications for network dynamics and future work.…”

Inhibition-based relaxation oscillations emerge in resonator networks

“…To study the effects of f res on f ntw we follow [4,12] and change the model parameters in such a way that f res changes but Z max remains constant. In particular, we consider a fixed value of g L,1 , and various balanced combinations of values of g 1 and τ 1 so as to increase f res and maintain Z max constant.…”

“…In addition to the single-cell mechanisms of generation of oscillations described above, oscillations can be generated at the network level in mutually connected cells that do not exhibit sustained oscillations when disconnected, but they are rather damped oscillators or resonators [4,48,88,93]. The graded synaptic connectivity used in these studies has been assumed to be instantaneously fast and to have no dynamics.…”

“…In [4] we have identified a minimal (3D) network model consisting of a two-dimensional resonator and a one-dimensional passive cell mutually connected through graded inhibition. Oscillations are also obtained in self-excited resonators (2D), mutually excited resonators (4D) and mutually inhibited resonators (4D), also using graded synaptic connectivity.…”

“…In self-excited networks, self-excitation provides the amplifying process necessary for the generation of oscillations. In fact, self-excited resonators have the same mathematical structure as single neurons having both resonant and amplifying ionic processes whose dynamics are also 2D [4]. Mutually excited resonators exhibit synchronized in-phase patterns and therefore their dynamics are captured by those of self-excited resonators.…”

“…Subsequently, we show how the resonant frequency of the individual 2D resonator affects the network oscillation frequency. Finally, we review some results obtained in [4] for smooth connectivity functions, discuss the existence of relaxation oscillations and the associated canard phenomenon, and compare the oscillatory properties of networks having smooth and PWL connectivity functions. We conclude in Section 4 by discussing our results, their implications for network dynamics and future work.…”

Inhibition-based relaxation oscillations emerge in resonator networks

Resonance-Based Mechanisms of Generation of Relaxation Oscillations in Networks of Non-oscillatory Neurons

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