Abstract
Prediction is the ability of the brain to quickly activate a target concept in response to a related stimulus (prime). Experiments point to the existence of an overlap between the populations of the neurons coding for different stimuli, and other experiments show that prime-target relations arise in the process of long term memory formation. The classical modelling paradigm is that long term memories correspond to stable steady states of a Hopfield network with Hebbian connectivity. Experiments show that short term synaptic depression plays an important role in the processing of memories. This leads naturally to a computational model of priming, called latching dynamics; a stable state (prime) can become unstable and the system may converge to another transiently stable steady state (target). Hopfield network models of latching dynamics have been studied by means of numerical simulation, however the conditions for the existence of this dynamics have not been elucidated. In this work we use a combination of analytic and numerical approaches to confirm that latching dynamics can exist in the context of a symmetric Hebbian learning rule, however lacks robustness and imposes a number of biologically unrealistic restrictions on the model. In particular our work shows that the symmetry of the Hebbian rule is not an obstruction to the existence of latching dynamics, however fine tuning of the parameters of the model is needed.
Highlights
Prediction of changes in the environment is a fundamental adaptive property of the brain [1,2,3,4,5]
The present study provides the first analysis of the sufficient conditions for heteroclinic chains of overlapping patterns in the case of a symmetric Hebbian learning rule
Heteroclinic chains closely approximate latching dynamics, they are good candidates to account for priming processes reported in human and nonhuman primates
Summary
Prediction of changes in the environment is a fundamental adaptive property of the brain [1,2,3,4,5]. To this aim, the neural mechanisms subtending prediction must activate in memory potential future stimuli on the basis of preceding ones. Some neurons strongly respond to the first stimulus and exhibit a retrospective activity at an elevated firing rate after its offset [1, 2, 6]. Retrospective activity is considered as a neural mechanism of short-term maintenance of the first stimulus in working memory [7,8,9,10].
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