Abstract
Spike-timing dependent plasticity (STDP) has traditionally been of great interest to theoreticians, as it seems to provide an answer to the question of how the brain can develop functional structure in response to repeated stimuli. However, despite this high level of interest, convincing demonstrations of this capacity in large, initially random networks have not been forthcoming. Such demonstrations as there are typically rely on constraining the problem artificially. Techniques include employing additional pruning mechanisms or STDP rules that enhance symmetry breaking, simulating networks with low connectivity that magnify competition between synapses, or combinations of the above. In this paper, we first review modeling choices that carry particularly high risks of producing non-generalizable results in the context of STDP in recurrent networks. We then develop a theory for the development of feed-forward structure in random networks and conclude that an unstable fixed point in the dynamics prevents the stable propagation of structure in recurrent networks with weight-dependent STDP. We demonstrate that the key predictions of the theory hold in large-scale simulations. The theory provides insight into the reasons why such development does not take place in unconstrained systems and enables us to identify biologically motivated candidate adaptations to the balanced random network model that might enable it.
Highlights
For several decades it has been commonly assumed that functional structures in the brain develop by strengthening synapses between neurons that fire in a correlated fashion (Hebb, 1949)
3.1 Fixed point analysis of weight dynamics To investigate the dynamics of spike-timing dependent plasticity (STDP) in a recurrent network undergoing synchronous stimulation, we select the update rule proposed by van Rossum et al (2000), which is additive for potentiation (F+(w) = l) and multiplicative for depression (F−(w) = alw)
4 Discussion We have developed a simple model using a mean field approach and a linear neuron model to investigate the propagation of feedforward structure in plastic recurrent networks
Summary
For several decades it has been commonly assumed that functional structures in the brain develop by strengthening synapses between neurons that fire in a correlated fashion (Hebb, 1949). Feed-forward structures in which neural activity is propagated as a wave from one pool to the (Abeles, 1991) would seem to be favored by a synaptic plasticity dynamics which strengthens causally correlated connections and weakens acausally correlated connections This key property of spike-timing dependent plasticity (STDP) was postulated theoretically (Gerstner et al, 1993) before it was observed experimentally on the timescale of 10 ms (Markram and Sakmann, 1995; Markram et al, 1997; Bi and Poo, 1998), strengthening of causal correlations on the timescale of 100 ms had already been found (Gustafsson et al, 1987). Apart from being a natural candidate for the representation of serial activities, such as the sequential activation of muscles to generate a movement, Bienenstock (1995)
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