Abstract
Recent experiments have demonstrated that visual cortex engages in spatio-temporal sequence learning and prediction. The cellular basis of this learning remains unclear, however. Here we present a spiking neural network model that explains a recent study on sequence learning in the primary visual cortex of rats. The model posits that the sequence learning and prediction abilities of cortical circuits result from the interaction of spike-timing dependent plasticity (STDP) and homeostatic plasticity mechanisms. It also reproduces changes in stimulus-evoked multi-unit activity during learning. Furthermore, it makes precise predictions regarding how training shapes network connectivity to establish its prediction ability. Finally, it predicts that the adapted connectivity gives rise to systematic changes in spontaneous network activity. Taken together, our model establishes a new conceptual bridge between the structure and function of cortical circuits in the context of sequence learning and prediction.
Highlights
To conclude, the mean PSP amplitudes in our network simulation lie within the range of experimentally observed values [11,12,28] and the EPSP amplitude distribution was shaped to the experimentally observed one [12]
Using connectivity data from a network that was simulated for 500 s, we transformed the weight distributions of the different connection types to the corresponding PSP amplitude distribution using weight-to-PSP transformation functions obtained via the above explained process
S1 Appendix Fig 1 shows the results for the PSP amplitude estimates in excitatory neurons
Summary
The mean PSP amplitudes in our network simulation lie within the range of experimentally observed values [11,12,28] and the EPSP amplitude distribution was shaped to the experimentally observed one [12]. To estimate the PSP amplitudes occurring in our network, we took the following, different approach. We simulated the neuron’s response to one presynaptic spike and determined the amplitude of the PSP.
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