Abstract
Top-down synapses are ubiquitous throughout neocortex and play a central role in cognition, yet little is known about their development and specificity. During sensory experience, lower neocortical areas are activated before higher ones, causing top-down synapses to experience a preponderance of post-synaptic activity preceding pre-synaptic activity. This timing pattern is the opposite of that experienced by bottom-up synapses, which suggests that different versions of spike-timing dependent synaptic plasticity (STDP) rules may be required at top-down synapses. We consider a two-layer neural network model and investigate which STDP rules can lead to a distribution of top-down synaptic weights that is stable, diverse and avoids strong loops. We introduce a temporally reversed rule (rSTDP) where top-down synapses are potentiated if post-synaptic activity precedes pre-synaptic activity. Combining analytical work and integrate-and-fire simulations, we show that only depression-biased rSTDP (and not classical STDP) produces stable and diverse top-down weights. The conclusions did not change upon addition of homeostatic mechanisms, multiplicative STDP rules or weak external input to the top neurons. Our prediction for rSTDP at top-down synapses, which are distally located, is supported by recent neurophysiological evidence showing the existence of temporally reversed STDP in synapses that are distal to the post-synaptic cell body.
Highlights
Connectivity patterns between different areas in neocortex are often discussed in terms of bottom-up and top-down connections [1,2,3]
We use mathematical analysis and computational simulations to show that this reverse time learning rule, and not previous learning rules, leads to a biologically plausible connectivity pattern with stable synaptic strengths
We study the characteristics of synaptic plasticity learning rules at top-down synapses and evaluate whether the resulting distribution of synaptic strengths fulfill the three properties outlined above: stability, diversity and weakness
Summary
Connectivity patterns between different areas in neocortex are often discussed in terms of bottom-up and top-down connections [1,2,3]. Feedforward or ‘‘bottom-up’’ connections are those which run from lower neocortical areas (such as visual area V1) to higher areas (such as V2); they typically but not always originate in layers 2/3 and synapse onto neurons in layer 4 [1,4,5,6]. Feedback or ‘‘top-down’’ connections, which run from higher neocortical areas to lower ones, typically originate in layer 6 and frequently synapse onto distal dendrites in layer 1. According to STDP, when a pre-synaptic spike occurs within tens of milliseconds before a post-synaptic spike, the synaptic strength is enhanced. When a pre-synaptic spike occurs shortly after a post-synaptic spike, the synaptic strength is decreased. STDP has been observed in a wide variety of systems and conditions [11] and has been examined in many computational studies as well (e.g. [12,13,14]; for reviews, see [15,16,17])
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