Astrocytes are a highly expressed and highly enigmatic cell-type in the mammalian brain. Traditionally viewed as a mediator of basic physiological sustenance, it is increasingly recognized that astrocytes may play a more direct role in neural computation. A conceptual challenge to this idea is the fact that astrocytic activity takes a very different form than that of neurons, and in particular, occurs at orders-of-magnitude slower time-scales. In the current paper, we engage how such time-scale separation may endow astrocytes with the capability to enable learning in context-dependent settings, where fluctuations in task parameters may occur much more slowly than within-task requirements. This idea is based on the recent supposition that astrocytes, owing to their sensitivity to a host of physiological covariates, may be particularly well poised to modulate the dynamics of neural circuits in functionally salient ways. We pose a general model of neural-synaptic-astrocyte interaction and use formal analysis to characterize how astrocytic modulation may constitute a form of meta-plasticity, altering the ways in which synapses and neurons adapt as a function of time. We then embed this model in a bandit-based reinforcement learning task environment, and show how the presence of time-scale separated astrocytic modulation enables learning over multiple fluctuating contexts. Indeed, these networks learn far more reliably versus dynamically homogenous networks and conventional non-network-based bandit algorithms. Our results indicate how the presence of neural-astrocyte interaction in the brain may benefit learning over different time-scale and the conveyance of task relevant contextual information onto circuit dynamics.
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