Growing dendrites enhance a neuron's computational power and memory capacity

Growing dendrites enhance a neuron's computational power and memory capacity

Neocortical pyramidal neurons have many dendrites, and such dendrites are capable of, in isolation of one-another, generating a neuronal spike. It is also now understood that there is a large amount of dendritic growth during the first years of a humans life, arguably a period of prodigious learning...

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Bibliographic Details
Main Authors: Baxter, R.A (Author), Levy, W.B (Author)
Format: Article
Language:English
Published: Elsevier Ltd 2023
Subjects:
algorithm
article
brain development
Brain development
Computation theory
Computational memory
dendrite
Dendritic spike
Dendritic spikes
Energy efficiency
Energy efficient
Generative model
human
human cell
learning
memory
Memory capacity
Mixture distributions
nerve cell
Neurons
Pruning
spike
Stochastic algorithms
stochastic model
Stochastic systems
synaptogenesis
Synaptogenesis
Online Access:View Fulltext in Publisher
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Description
Summary:Neocortical pyramidal neurons have many dendrites, and such dendrites are capable of, in isolation of one-another, generating a neuronal spike. It is also now understood that there is a large amount of dendritic growth during the first years of a humans life, arguably a period of prodigious learning. These observations inspire the construction of a local, stochastic algorithm based on an earlier stochastic, homeostatic, Hebbian developmental theory. Here we investigate the neurocomputational advantages and limits on this novel algorithm that combines dendritogenesis with supervised adaptive synaptogenesis. Neurons created with this algorithm have enhanced memory capacity, can avoid catastrophic interference (forgetting), and have the ability to unmix mixture distributions. In particular, individual dendrites develop within each class, in an unsupervised manner, to become feature-clusters that correspond to the mixing elements of class-conditional mixture distribution. Error-free classification is demonstrated with input perturbations up to 40%. Although discriminative problems are used to understand the capabilities of the stochastic algorithm and the neuronal connectivity it produces, the algorithm is in the generative class, it thus seems ideal for decisions that require generalization, i.e., extrapolation beyond previous learning. © 2023 Elsevier Ltd
Physical Description:35
ISBN:08936080 (ISSN)
DOI:10.1016/j.neunet.2023.04.033

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