Abstract
In a recent experiment [9], a cell in the human medial temporal lobe (MTL) encoding one sensory stimulus starts to also respond to a second stimulus following a combined experience associating the two. We develop a theoretical model predicting that an assembly of cells with exceptionally high synaptic intraconnectivity can emerge, in response to a particular sensory experience, to
encode and abstract that experience. We also show that two such assemblies are modified to increase their intersection after a sensory event that associates the two corresponding stimuli. The main technical tools employed are random graph theory, and Bernoulli approximations. Assembly creation must overcome a computational challenge akin to the Densest K-Subgraph problem, namely selecting, from a large population of randomly and sparsely interconnected cells, a subset with exceptionally high density of interconnections. We identify three mechanisms that help achieve this feat in our model: (1) a simple two-stage randomized algorithm, and (2) the “triangle completion bias” in synaptic connectivity [14] and a “birthday paradox”, while (3) the strength of these connections is enhanced through Hebbian plasticity.
encode and abstract that experience. We also show that two such assemblies are modified to increase their intersection after a sensory event that associates the two corresponding stimuli. The main technical tools employed are random graph theory, and Bernoulli approximations. Assembly creation must overcome a computational challenge akin to the Densest K-Subgraph problem, namely selecting, from a large population of randomly and sparsely interconnected cells, a subset with exceptionally high density of interconnections. We identify three mechanisms that help achieve this feat in our model: (1) a simple two-stage randomized algorithm, and (2) the “triangle completion bias” in synaptic connectivity [14] and a “birthday paradox”, while (3) the strength of these connections is enhanced through Hebbian plasticity.
Original language | English |
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Title of host publication | 9th Innovations in Theoretical Computer Science Conference (ITCS 2018) |
Publisher | Schloss Dagstuhl - Leibniz-Zentrum für Informatik |
Pages | 57:1–57:15 |
Volume | 94 |
DOIs | |
Publication status | Published - 2018 |
Publication series
Name | LIPIcs-Leibniz International Proceedings in Informatics |
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Publisher | Schloss Dagstuhl--Leibniz-Zentrum fuer Informatik |
Keywords
- Brain computation
- long term memory
- assemblies
- association