Principal component analysis learning algorithms: a neurobiological analysis

The biological relevance of principal component analysis (PCA) learning algorithms is addressed by: (i) describing a plausible biological mechanism which accounts for the changes in synaptic efficacy implicit in Oja’s ‘Subspace’ algorithm (Int. J. neural Syst. 1, 61 (1989)); and (ii) establishing a potential role for PCA-like mechanisms in the development of functional segregation, PCA learning algorithms comprise an associative Hebbian term and a decay term which interact to find the principal patterns of correlations in the inputs shared by a group of units. We propose that the presynaptic component of this decay could be regulated by retrograde signals that are translocated from the terminal arbors of presynaptic neurons to their cell bodies. This proposal is based on reported studies of structural plasticity in the nervous system. By using simulations we demonstrate that PCA-like mechanisms can eliminate afferent connections whose signals are unrelated to the prevalent pattern of afferent activity. This elimination may be instrumental in refining extrinsic cortico-cortical connections that underlie functional segregation.

[1]  S. Mcconnell,et al.  The determination of neuronal fate in the cerebral cortex , 1989, Trends in Neurosciences.

[2]  R. Palmer,et al.  Introduction to the theory of neural computation , 1994, The advanced book program.

[3]  S. Rotshenker,et al.  Multiple modes and sites for the induction of axonal growth , 1988, Trends in Neurosciences.

[4]  W B Levy,et al.  Associative synaptic potentiation and depression: Quantification of dissociable modifications in the hippocampal dentate gyrus favors a particular class of synaptic modification equations , 1990, Synapse.

[5]  G. Edelman,et al.  Spatial signaling in the development and function of neural connections. , 1991, Cerebral cortex.

[6]  G. Edelman,et al.  The NO hypothesis: possible effects of a short-lived, rapidly diffusible signal in the development and function of the nervous system. , 1990, Proceedings of the National Academy of Sciences of the United States of America.

[7]  Erkki Oja,et al.  Neural Networks, Principal Components, and Subspaces , 1989, Int. J. Neural Syst..

[8]  H. Wigström,et al.  Physiological mechanisms underlying long-term potentiation , 1988, Trends in Neurosciences.

[9]  R. Burke Synaptic efficacy and the control of neuronal input-output relations , 1987, Trends in Neurosciences.

[10]  W B Levy,et al.  Morphological correlates of long‐term potentiation imply the modification of existing synapses, not synaptogenesis, in the hippocampal dentate gyrus , 1990, Synapse.

[11]  S. Zeki Vision: The motion pathways of the visual cortex , 1991 .

[12]  P. Foldiak,et al.  Adaptive network for optimal linear feature extraction , 1989, International 1989 Joint Conference on Neural Networks.

[13]  C. Bendotti,et al.  Distribution of GAP-43 mRNA in the brain stem of adult rats as evidenced by in situ hybridization: localization within monoaminergic neurons , 1991, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[14]  Ralph Linsker,et al.  Self-organization in a perceptual network , 1988, Computer.

[15]  Kurt Hornik,et al.  Convergence analysis of local feature extraction algorithms , 1992, Neural Networks.

[16]  H. D. Miller,et al.  The Theory Of Stochastic Processes , 1977, The Mathematical Gazette.

[17]  M. Mattson Neurotransmitters in the regulation of neuronal cytoarchitecture , 1988, Brain Research Reviews.

[18]  C. Malsburg,et al.  How to label nerve cells so that they can interconnect in an ordered fashion. , 1977, Proceedings of the National Academy of Sciences of the United States of America.

[19]  A. Routtenberg,et al.  A membrane phosphoprotein associated with neural development, axonal regeneration, phospholipid metabolism, and synaptic plasticity , 1987, Trends in Neurosciences.

[20]  M. Fishman,et al.  GAP-43 gene expression during development: persistence in a distinctive set of neurons in the mature central nervous system. , 1989, Brain research. Developmental brain research.

[21]  Karl J. Friston,et al.  Entropy and cortical activity: information theory and PET findings. , 1992, Cerebral cortex.

[22]  M. Sur,et al.  Cross-modal plasticity in cortical development: differentiation and specification of sensory neocortex , 1990, Trends in Neurosciences.

[23]  K D Miller,et al.  Models of activity-dependent neural development. , 1992, Progress in brain research.