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The Self-Organizing Brain: From Growth Cones to Functional Networks
 
 

The Self-Organizing Brain: From Growth Cones to Functional Networks, 1st Edition

 
The Self-Organizing Brain: From Growth Cones to Functional Networks, 1st Edition,M.A. Corner,F.H. Lopes da Silva,H.B.M. Uylings,J. van Pelt,ISBN9780080862279
 
 
 

Corner   &   Lopes da Silva   &   Uylings   &   van Pelt   

Elsevier Science

9780080862279

443

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This book concentrates on the organizational level of neurons and neuronal networks under the unifying theme "The Self-Organizing Brain - From Growth Cones to Functional Networks". Such a theme is attractive because it incorporates all phases in the emergence of complexity and (adaptive) organization, as well as involving processes that remain operative in the mature state.

The order of the sections follows successive levels of organization from neuronal growth cones, neurite formation, neuronal morphology and signal processing to network development, network dynamics and, finally, to the formation of functional circuits.

M.A. Corner

F.H. Lopes da Silva

Affiliations and Expertise

Department of Experimental Zoology, University of Amsterdam, The Netherlands

H.B.M. Uylings

J. van Pelt

Affiliations and Expertise

Netherlands Institute for Brain Research, Amsterdam, The Netherlands

The Self-Organizing Brain: From Growth Cones to Functional Networks, 1st Edition

List of contributors. Preface. Acknowledgements. Section I - Introduction. 1. Reciprocity of structure-function relations in developing neural networks: the Odyssey of a self-organizing brain through research fads, fallacies and prospects. Section II - From Growth Cone to Neuron. A. Growth Cone Dynamics and Neuritic Outgrowth. 2. Growth cone motility: substratum-bound molecules, cytoplasmic (Ca2+) and Ca2+-regulated proteins. 3. Filopodia as detectors of environmental cues: signal integration through changes in growth cone calcium levels. 4. Microtubule transport and assembly cooperate to generate the microtubule assay of growing axons. 5. Initial tract formation in the vertebrate brain. 6. Dynamic mechanisms of neuronal outgrowth. 7. Geometrical and topological characteristics in the dendritic development of cortical pyramidal and non-pyramidal neurons. B. Morphology, Excitability and Signal Processing. 8. Electrotonic properties of passive dendritic trees - effect of dendritic topology. 9. Exploring the computational capabilities of single neurons by continuous cable modelling. 10. Development of voltage-dependent and ligand-gated channels in excitable membranes. 11. Theoretical models for describing neural signal transduction. 12. Intrinsic neuronal physiology and the functions, dysfunctions and development of neurocortex. Section III - From Neuron to Network. A. Functional Activity and Other Formative Factors. 13. Development of projection neurons of the mammalian cerebral cortex. 14. Naturally occurring and axotomy-induced motoneuron death, and its prevention by neurotrophic agents: a comparison between chick and mouse. 15. Synaptic development of the cerebral cortex: implications for learning, memory and mental illness. 16. Activity-dependent neurite outgrowth and neural network development. 17. &ggr;-Aminobutyric acid (GABA): a fast excitatory transmitter which may regulate the development of hippocampal neurons in early postnatal life. B. Sensory Stimulation and Cortical Maturation. 18. Regulation of N-methyl-D-aspartate (NMDA) receptor function during the rearrangement of developing neuronal connections. 19. Role of the visual environment in the formation of receptive fields according to the BCM theory. 20. Models of activity-dependent neural development. 21. Role of chaotic dynamics in neural plasticity. 22. Neural networks in the brain involved in memory and recall. 23. Categories of cortical structure. Section IV - Neural Network Dynamics. 24. Dynamics of local neuronal networks: control parameters and state bifurcations in epileptogenesis. 25. Non-linear dynamics in neural networks. 26. Are there unifying principles underlying the generation of epileptic afterdischarges in vitro? 27. Synchronization in neuronal transmission and its importance for information processing. 28. Oscillatory and non-oscillatory synchronizations in the visual cortex and their possible roles in association of visual features. 29. Modelling the cerebellar Purkinje cell: experiments 'in computo'. Subject index
 
 
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