dorsal/arxiv
View SchemaNeural integrator - a sandpile model
| Authors | Maxim Nikitchenko, Alexei Koulakov |
|---|---|
| Categories | |
| ArXiv ID | q-bio/0605038 |
| URL | https://arxiv.org/abs/q-bio/0605038 |
Abstract
We investigated a model for the neural integrator based on hysteretic units connected by positive feedback. Hysteresis is assumed to emerge from the intrinsic properties of the cells. We consider the recurrent networks containing either bistable or multistable neurons. We apply our analysis to the oculomotor velocity-to-position neural integrator that calculates the eye positions from the inputs that carry information about eye angular velocity. Using the analysis of the system in the parameter space we show the following. The direction of hysteresis in the neuronal response may be reversed for the system with recurrent connections compared to the case of unconnected neurons. Thus, for the NMDA receptor based bistability the firing rates after ON saccades may be higher than after OFF saccades for the same eye position. We suggest that this is an emergent property due to the presence of global recurrent feedback. The reversal of hysteresis occurs only when the size of hysteresis differs from neuron to neuron. We also relate the macroscopic leak time-constant of the integrator to the rate of microscopic spontaneous noise-driven transitions in the hysteretic units. Finally, we argue that the presence of neurons with small hysteresis may remove the threshold for integration.
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"abstract": "We investigated a model for the neural integrator based on hysteretic units\nconnected by positive feedback. Hysteresis is assumed to emerge from the\nintrinsic properties of the cells. We consider the recurrent networks\ncontaining either bistable or multistable neurons. We apply our analysis to the\noculomotor velocity-to-position neural integrator that calculates the eye\npositions from the inputs that carry information about eye angular velocity.\nUsing the analysis of the system in the parameter space we show the following.\nThe direction of hysteresis in the neuronal response may be reversed for the\nsystem with recurrent connections compared to the case of unconnected neurons.\nThus, for the NMDA receptor based bistability the firing rates after ON\nsaccades may be higher than after OFF saccades for the same eye position. We\nsuggest that this is an emergent property due to the presence of global\nrecurrent feedback. The reversal of hysteresis occurs only when the size of\nhysteresis differs from neuron to neuron. We also relate the macroscopic leak\ntime-constant of the integrator to the rate of microscopic spontaneous\nnoise-driven transitions in the hysteretic units. Finally, we argue that the\npresence of neurons with small hysteresis may remove the threshold for\nintegration.",
"arxiv_id": "q-bio/0605038",
"authors": [
"Maxim Nikitchenko",
"Alexei Koulakov"
],
"categories": [
"q-bio.NC"
],
"title": "Neural integrator - a sandpile model",
"url": "https://arxiv.org/abs/q-bio/0605038"
},
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