Abstract
Memory-related activity in the Dentate Gyrus (DG) is characterized by sparsity. Memory representations are seen as activated neuronal populations of granule cells, the main encoding cells in DG, which are estimated to engage 2–4% of the total population. This sparsity is assumed to enhance the ability of DG to perform pattern separation, one of the most valuable contributions of DG during memory formation. In this work, we investigate how features of the DG such as its excitatory and inhibitory connectivity diagram can be used to develop theoretical algorithms performing Sparse Approximation, a widely used strategy in the Signal Processing field. Sparse approximation stands for the algorithmic identification of few components from a dictionary that approximate a certain signal. The ability of DG to achieve pattern separation by sparsifing its representations is exploited here to improve the performance of the state of the art sparse approximation algorithm “Iterative Soft Thresholding” (IST) by adding new algorithmic features inspired by the DG circuitry. Lateral inhibition of granule cells, either direct or indirect, via mossy cells, is shown to enhance the performance of the IST. Apart from revealing the potential of DG-inspired theoretical algorithms, this work presents new insights regarding the function of particular cell types in the pattern separation task of the DG.
Highlights
The hippocampal formation is one of the most important information processing units in the brain, critically implicated in spatial [1], associational and episodic memory storage and retrieval [2]
The organization of Granule Cells (GC) is adopted from the work of Myers and Scharfman [5], where it is supposed to be structured in non-overlapping clusters
This work uses features of the Dentate Gyrus (DG) circuitry to extend and improve the state of the art Iterative Soft Thresholding (IST) algorithm which is extensively used for sparse approximation tasks
Summary
The hippocampal formation is one of the most important information processing units in the brain, critically implicated in spatial [1], associational and episodic memory storage and retrieval [2]. The hippocampus is a cascade of different subregions dedicated to perform distinct and specific functional processes. Information enters from the Entorhinal Cortex (EC, the upstream area of hippocampus) and passes through the Dentate Gyrus, the CA3, CA2 and CA1 regions, where it is processed to form neuronal representations of memories that will be stored and/or retrieved. Suitably manipulated information from the hippocampus is projected back to the cortex for further processing.
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