Abstract
Brain networks store new memories using functional and structural synaptic plasticity. Memory formation is generally attributed to Hebbian plasticity, while homeostatic plasticity is thought to have an ancillary role in stabilizing network dynamics. Here we report that homeostatic plasticity alone can also lead to the formation of stable memories. We analyze this phenomenon using a new theory of network remodeling, combined with numerical simulations of recurrent spiking neural networks that exhibit structural plasticity based on firing rate homeostasis. These networks are able to store repeatedly presented patterns and recall them upon the presentation of incomplete cues. Storage is fast, governed by the homeostatic drift. In contrast, forgetting is slow, driven by a diffusion process. Joint stimulation of neurons induces the growth of associative connections between them, leading to the formation of memory engrams. These memories are stored in a distributed fashion throughout connectivity matrix, and individual synaptic connections have only a small influence. Although memory-specific connections are increased in number, the total number of inputs and outputs of neurons undergo only small changes during stimulation. We find that homeostatic structural plasticity induces a specific type of “silent memories”, different from conventional attractor states.
Highlights
Memories are thought to be stored in the brain using cell assemblies that emerge through coordinated synaptic plasticity [1]
Memories are thought to be stored in groups of strongly connected neurons, or engrams
Hebbian plasticity occurs when synaptic weights are strengthened between pairs of neurons with correlated activity
Summary
Memories are thought to be stored in the brain using cell assemblies that emerge through coordinated synaptic plasticity [1]. Cell assemblies with strong enough recurrent connections lead to bistable firing rates, which allows a network to encode memories as dynamic attractor states [2, 3]. If strong excitatory recurrent connections are counteracted by inhibitory plasticity, “silent” memories are formed [4,5,6]. It has been shown that attractor networks can emerge through the creation of such neuronal clusters [7]. The creation of clusters through changes in connectivity between cells would require synaptic rewiring, or structural plasticity. Poses a severe challenge to the idea of memories being stored in synaptic connections [11]. Recent theoretical work has shown that stable assemblies can be maintained despite ongoing synaptic rewiring [12, 13]
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