Abstract
Spike timing dependent plasticity (STDP) is a phenomenon in which the precise timing of spikes affects the sign and magnitude of changes in synaptic strength. STDP is often interpreted as the comprehensive learning rule for a synapse – the “first law” of synaptic plasticity. This interpretation is made explicit in theoretical models in which the total plasticity produced by complex spike patterns results from a superposition of the effects of all spike pairs. Although such models are appealing for their simplicity, they can fail dramatically. For example, the measured single-spike learning rule between hippocampal CA3 and CA1 pyramidal neurons does not predict the existence of long-term potentiation one of the best-known forms of synaptic plasticity. Layers of complexity have been added to the basic STDP model to repair predictive failures, but they have been outstripped by experimental data. We propose an alternate first law: neural activity triggers changes in key biochemical intermediates, which act as a more direct trigger of plasticity mechanisms. One particularly successful model uses intracellular calcium as the intermediate and can account for many observed properties of bidirectional plasticity. In this formulation, STDP is not itself the basis for explaining other forms of plasticity, but is instead a consequence of changes in the biochemical intermediate, calcium. Eventually a mechanism-based framework for learning rules should include other messengers, discrete change at individual synapses, spread of plasticity among neighboring synapses, and priming of hidden processes that change a synapse's susceptibility to future change. Mechanism-based models provide a rich framework for the computational representation of synaptic plasticity.
Highlights
It is amateurs who have one big bright beautiful idea that they can never abandon
At connections between mammalian pyramidal neurons (Markram et al, 1997; Bi and Poo, 1998; Feldman, 2000; Nishiyama et al, 2000; Sjöström et al, 2001; Wittenberg and Wang, 2006) a presynaptic spike preceding a postsynaptic spike within a narrow time window leads to long-term potentiation (LTP); if the order is reversed, long-term depression (LTD) results
This pairing is repeated at low frequency and the resulting change in synaptic response size is measured. Repeating this experiment for many values of ∆t gives the timing-dependence of plasticity. Such an Spike timing dependent plasticity (STDP) curve is assumed to be useful for predicting the plasticity that results when ∆t is variable, e.g., for arbitrary trains of presynaptic and postsynaptic spikes that occur under less controlled conditions
Summary
Spike timing dependent plasticity: a consequence of more fundamental learning rules. Reviewed by: Wulfram Gerstner, Ecole Polytechnique Fédérale de Lausanne, Switzerland Nicolas Brunel, Centre National de la Recherche Scientifique, France. The minimal nature of STDP protocols carried with it two hopes: that the activity patterns used were more realistic, and that the various properties of synaptic plasticity could eventually be accounted for by knowing the timing of all the spikes This is realized in theoretical models by assuming that cumulative plasticity is predicted by a simple superposition of spike pairs that repeatedly sample the STDP curve (“linear STDP”) (Gerstner et al, 1996; Kempter et al, 1999; Abbott and Nelson, 2000; Song et al, 2000; van Rossum et al, 2000; Gütig et al, 2003; Izhikevich and Desai, 2003).
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