In the 25 years since "From Neuron to Brain" was first published, the author's aim has remained constant: to describe how nerve cells go about their business of transmitting signals, how the signals are put together, and how, out of this integration, higher functions emerge. The fourth edition, while maintaining this focus, has been completely reformatted and updated. Intended for use in upper-level undergraduate, graduate, psychology and medical school neuroscience courses, "From Neuron to Brain" should be of interest to anyone, with or without a specialized background in biological sciences, who is curious about the workings of the nervous system. It presents a readable and coherent account of how cellular and molecular approaches can provide insights into the workings of the brain.
Auflage
Sprache
Verlagsort
Zielgruppe
Für höhere Schule und Studium
Für Beruf und Forschung
Editions-Typ
Illustrationen
Maße
Höhe: 280 mm
Breite: 210 mm
ISBN-13
978-0-87893-581-9 (9780878935819)
Copyright in bibliographic data and cover images is held by Nielsen Book Services Limited or by the publishers or by their respective licensors: all rights reserved.
Schweitzer Klassifikation
Autor*in
Johns Hopkins University School of Medicine
University of Colorado School of Medicine, USA
University of Colorado School of Medicine, USA
Überarbeitet von
Part 1 - introduction: principles of signalling and organization. Part II Signalling in the nervous system: ion channels and signalling; structure of ion channels; transport across cell membranes; ionic basis of the resting potential; ionic basis of the action potential; neurons as conductors of electricity; properties and functions of neuroglial cells; principles of direct synaptic transmission; indirect mechanisms of synaptic transmission; transmitter release; synaptic plasticity; cellular and molecular biochemistry of synaptic transmission; neurotransmitters in the central nervous system. Part III Integrative mechanisms: cellular mechanisms of integration and behaviour in leeches, ants, and bees; autonomic nervous system; transduction of mechanical and chemical stimuli; processing of somatosensory and auditory; transduction and signalling the retina; analysis of form in primary visual cortex; functional architecture of the visual cortex; cellular mechanisms of motor control. Part IV Development of the nervous system: development of the nervous system; denervation and regeneration of synaptic connections; critical periods in visual and auditory systems. Part V Conclusions: open questions.
