Abstract
Working memory (WM) is the part of the brain's memory system that provides temporary storage and manipulation of information necessary for cognition. Although WM has limited capacity at any given time, it has vast memory content in the sense that it acts on the brain's nearly infinite repertoire of lifetime long-term memories. Using simulations, we show that large memory content and WM functionality emerge spontaneously if we take the spike-timing nature of neuronal processing into account. Here, memories are represented by extensively overlapping groups of neurons that exhibit stereotypical time-locked spatiotemporal spike-timing patterns, called polychronous patterns; and synapses forming such polychronous neuronal groups (PNGs) are subject to associative synaptic plasticity in the form of both long-term and short-term spike-timing dependent plasticity. While long-term potentiation is essential in PNG formation, we show how short-term plasticity can temporarily strengthen the synapses of selected PNGs and lead to an increase in the spontaneous reactivation rate of these PNGs. This increased reactivation rate, consistent with in vivo recordings during WM tasks, results in high interspike interval variability and irregular, yet systematically changing, elevated firing rate profiles within the neurons of the selected PNGs. Additionally, our theory explains the relationship between such slowly changing firing rates and precisely timed spikes, and it reveals a novel relationship between WM and the perception of time on the order of seconds.
Highlights
Various mechanisms have been proposed to model the main aspect of neural activity — elevated firing rates of a cue-specific population of neurons — observed during the delay period of a working memory (WM) task [1,2,3,4]
These include reentrant spiking activity [5], intrinsic membrane currents [6], NMDA currents [7,8,9,10], and short-term synaptic plasticity [7,11,12]. These mechanisms, fail to explain other aspects of neural correlates of Working memory (WM) [13], and they have been demonstrated to work only with a limited memory content where the number of items represented in long-term memory is small, i.e., they hold in WM a few items out of only a conceivable few
The narrow memory content is at odds with experimental findings that neurons participate in many different neural circuits and, are part of many distinct representations that form a vast memory content for WM
Summary
Various mechanisms have been proposed to model the main aspect of neural activity — elevated firing rates of a cue-specific population of neurons — observed during the delay period of a working memory (WM) task [1,2,3,4] These include reentrant spiking activity [5], intrinsic membrane currents [6], NMDA currents [7,8,9,10], and short-term synaptic plasticity [7,11,12]. These limitations may be overcome by a model that accounts for the precise spike-timing nature of neural processing
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