The book is structured in five sections, each containing several chapters written by experts and major contributors to particular topics. The volume starts with a historical perspective and fundamental principles of membrane potential imaging and continues to cover the measurement of membrane potential signals from dendrites and axons of individual neurons, measurements of the activity of many neurons with single cell resolution, monitoring of population signals from the nervous system, and concludes with the overview of new approaches to voltage-imaging. The book is targeted at all scientists…mehr
The book is structured in five sections, each containing several chapters written by experts and major contributors to particular topics. The volume starts with a historical perspective and fundamental principles of membrane potential imaging and continues to cover the measurement of membrane potential signals from dendrites and axons of individual neurons, measurements of the activity of many neurons with single cell resolution, monitoring of population signals from the nervous system, and concludes with the overview of new approaches to voltage-imaging. The book is targeted at all scientists interested in this mature but also rapidly expanding imaging approach.
Artikelnr. des Verlages: 12560493, 978-1-4419-6557-8
2011
Seitenzahl: 180
Erscheinungstermin: 1. November 2010
Englisch
Abmessung: 285mm x 215mm x 15mm
Gewicht: 614g
ISBN-13: 9781441965578
ISBN-10: 1441965572
Artikelnr.: 29151583
Autorenporträt
Dejan Zecevic (b. Belgrade 1948) is a Research Scientist at the Department of Cellular and Molecular Physiology, Yale University School of Medicine. He received the PhD in Biophysics from The University of Belgrade, Serbia and was trained in the laboratory of Dr Lawrence Cohen who initiated the field of voltage-sensitive dye recording. Dejan is the pioneer of intracellular voltage-sensitive dye imaging technique, a unique and a cutting edge technology for monitoring the membrane potential fluctuation in dendritic spines and fine branches. Marco (b. Milan 1970) is first class INSERM researcher (CR1) working at the Grenoble Institute of Neuroscience. He graduated in physics at the University of Genoa and received his PhD in biophysics from the International School for Advanced Studies in Trieste. He worked at the National Institute for Medical Research in London, at Yale University and at the University of Basel. Marco is expert on several optical techniques applied to neurophysiology. Marco and Dejan collaborated for a number of years using voltage-imaging and calcium imaging approaches to study mechanisms underlying synaptic plasticity.
Inhaltsangabe
Historical overview and general methods of membrane potential imaging.- Design and use of organic voltage sensitive dyes.- Imaging submillisecond membrane potential changes from individual regions of single axons, dendrites and spines.- Combined voltage and calcium imaging and signal calibration.- Use of fast-responding voltage-sensitive dyes for large-scale recording of neuronal spiking activity with single-cell resolution.- Monitoring integrated activity of individual neurons using FRET-based voltage-sensitive dyes.- Monitoring population membrane potential signals from neocortex.- Monitoring population membrane potential signals during functional development of neuronal circuits in vertebrate embryos.- Imaging the dynamics of mammalian neocortical population activity in-vivo.- Imaging the dynamics of neocortical population activity in behaving and freely moving mammals.- Monitoring membrane voltage using two-photon excitation of fluorescent voltage-sensitive dyes.- Random-access multiphoton microscopy for fast three-dimensional Imaging.- Second harmonic imaging of membrane potential.- Genetically encoded protein sensors of membrane potential
Historical overview and general methods of membrane potential imaging.- Design and use of organic voltage sensitive dyes.- Imaging submillisecond membrane potential changes from individual regions of single axons, dendrites and spines.- Combined voltage and calcium imaging and signal calibration.- Use of fast-responding voltage-sensitive dyes for large-scale recording of neuronal spiking activity with single-cell resolution.- Monitoring integrated activity of individual neurons using FRET-based voltage-sensitive dyes.- Monitoring population membrane potential signals from neocortex.- Monitoring population membrane potential signals during functional development of neuronal circuits in vertebrate embryos.- Imaging the dynamics of mammalian neocortical population activity in-vivo.- Imaging the dynamics of neocortical population activity in behaving and freely moving mammals.- Monitoring membrane voltage using two-photon excitation of fluorescent voltage-sensitive dyes.- Random-access multiphoton microscopy for fast three-dimensional Imaging.- Second harmonic imaging of membrane potential.- Genetically encoded protein sensors of membrane potential
Historical overview and general methods of membrane potential imaging.- Design and use of organic voltage sensitive dyes.- Imaging submillisecond membrane potential changes from individual regions of single axons, dendrites and spines.- Combined voltage and calcium imaging and signal calibration.- Use of fast-responding voltage-sensitive dyes for large-scale recording of neuronal spiking activity with single-cell resolution.- Monitoring integrated activity of individual neurons using FRET-based voltage-sensitive dyes.- Monitoring population membrane potential signals from neocortex.- Monitoring population membrane potential signals during functional development of neuronal circuits in vertebrate embryos.- Imaging the dynamics of mammalian neocortical population activity in-vivo.- Imaging the dynamics of neocortical population activity in behaving and freely moving mammals.- Monitoring membrane voltage using two-photon excitation of fluorescent voltage-sensitive dyes.- Random-access multiphoton microscopy for fast three-dimensional Imaging.- Second harmonic imaging of membrane potential.- Genetically encoded protein sensors of membrane potential
Historical overview and general methods of membrane potential imaging.- Design and use of organic voltage sensitive dyes.- Imaging submillisecond membrane potential changes from individual regions of single axons, dendrites and spines.- Combined voltage and calcium imaging and signal calibration.- Use of fast-responding voltage-sensitive dyes for large-scale recording of neuronal spiking activity with single-cell resolution.- Monitoring integrated activity of individual neurons using FRET-based voltage-sensitive dyes.- Monitoring population membrane potential signals from neocortex.- Monitoring population membrane potential signals during functional development of neuronal circuits in vertebrate embryos.- Imaging the dynamics of mammalian neocortical population activity in-vivo.- Imaging the dynamics of neocortical population activity in behaving and freely moving mammals.- Monitoring membrane voltage using two-photon excitation of fluorescent voltage-sensitive dyes.- Random-access multiphoton microscopy for fast three-dimensional Imaging.- Second harmonic imaging of membrane potential.- Genetically encoded protein sensors of membrane potential
Rezensionen
"This is an excellent 'how to' and methods approach to single, multiple, and populational photon imaging using various dyes optically in what is now recognized as a cutting edge technique. ... This is a very technical book for intermediate to advanced neuroscientists and would be useful for both the office and laboratory. ... I highly recommend this book for all interested audiences." (Joseph J. Grenier, Amazon.com, April, 2015)
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