Abstract

The ability to learn sequential behaviors is a fundamental property of our brains. Yet a long stream of studies including recent experiments investigating motor sequence learning in adult human subjects have produced a number of puzzling and seemingly contradictory results. In particular, when subjects have to learn multiple action sequences, learning is sometimes impaired by proactive and retroactive interference effects. In other situations, however, learning is accelerated as reflected in facilitation and transfer effects. At present it is unclear what the underlying neural mechanism are that give rise to these diverse findings. Here we show that a recently developed recurrent neural network model readily reproduces this diverse set of findings. The self-organizing recurrent neural network (SORN) model is a network of recurrently connected threshold units that combines a simplified form of spike-timing dependent plasticity (STDP) with homeostatic plasticity mechanisms ensuring network stability, namely intrinsic plasticity (IP) and synaptic normalization (SN). When trained on sequence learning tasks modeled after recent experiments we find that it reproduces the full range of interference, facilitation, and transfer effects. We show how these effects are rooted in the network’s changing internal representation of the different sequences across learning and how they depend on an interaction of training schedule and task similarity. Furthermore, since learning in the model is based on fundamental neuronal plasticity mechanisms, the model reveals how these plasticity mechanisms are ultimately responsible for the network’s sequence learning abilities. In particular, we find that all three plasticity mechanisms are essential for the network to learn effective internal models of the different training sequences. This ability to form effective internal models is also the basis for the observed interference and facilitation effects. This suggests that STDP, IP, and SN may be the driving forces behind our ability to learn complex action sequences.

Highlights

  • Humans can improve their performance in sequential movement tasks through practice, but such motor learning has shown puzzling and seemingly contradictory results

  • How do we learn such sequential behaviors and what neural plasticity mechanisms support this learning? Recent experiments on sequence learning in human adults have produced a range of confusing findings, especially when subjects have to learn multiple sequences at the same time

  • The model is formulated as a recurrent network of simplified spiking neurons and incorporates multiple biologically plausible plasticity mechanisms of neurons and synapses

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Summary

Introduction

Humans can improve their performance in sequential movement tasks through practice, but such motor learning has shown puzzling and seemingly contradictory results. There has been a strong interest in how the learning of sequential patterns may be supported by the temporally asymetric learning window of spike-timing-dependent plasticity (STDP) [5,6,7,8,9] and related learning rules, e.g., [10,11,12,13,14,15,16,17], review in [18] It has been investigated how the relatively short time windows associated with STDP might be extended to behaviorally relevant time scales [19]. Such models have not been related to human performance in actual sequence learning experiments and no mechanistic explanation of the above-mentioned interference and facilitation effects has been given

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