Marco Canepari,
Dejan Zecevic
Springer New York
2011e druk, 2010
9781441965578
Membrane Potential Imaging in the Nervous System
Methods and Applications
Specificaties
Gebonden, 170 blz.
|
Engels
Springer New York |
2011e druk, 2010
ISBN13: 9781441965578
Rubricering
Levertijd ongeveer 8 werkdagen
Samenvatting
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.
Specificaties
ISBN13:9781441965578
Taal:Engels
Bindwijze:gebonden
Aantal pagina's:170
Uitgever:Springer New York
Druk:2011
Inhoudsopgave
Chapter 1: Historical overview and general methods of membrane potential imaging
Lawrence B Cohen
Chapter 2: Design and use of organic voltage sensitive dyes
Leslie M Loew
Chapter 3: Imaging submillisecond membrane potential changes from individual regions of single axons, dendrites and spines
Marco Canepari, Marko Popovic, Kaspar Vogt, Knut Holthoff, Arthur Konnerth, Brian M Salzberg, Amiram Grinvald, Srdjan D Antic and Dejan Zecevic
Chapter 4: Combined voltage and calcium imaging and signal calibration
Marco Canepari, Peter Saggau and Dejan Zecevic
Chapter 5: Use of fast-responding voltage-sensitive dyes for large-scale recording of neuronal spiking activity with single-cell resolution
William N Frost, Jean Wang, Christopher J Brandon, Caroline Moore-Kochlacs, Terrence J Sejnowski and Evan S Hill
Chapter 6: Monitoring integrated activity of individual neurons using FRET-based voltage-sensitive dyes
Kevin L Briggman, William B Kristan, Jesús E González, David Kleinfeld and Roger Y Tsien
Chapter 7: Monitoring population membrane potential signals from neocortex
Xiaoying Huang, Weifeng Xu, Kentaroh Takagaki and Jian-young Wu
Chapter 8: Monitoring population membrane potential signals during functional development of neuronal circuits in vertebrate embryos
Yoko Momose-Sato, Katsushige Sato and Kohtaro Kamino
Chapter 9: Imaging the dynamics of mammalian neocortical population activity in-vivo
Amiram Grinvald, David Omer, Shmuel Naaman and Dahlia Sharon
Chapter 10: Imaging the dynamics of neocortical population activity in behaving and freely moving mammals
Amiram Grinvald and Carl CH Petersen
Chapter 11: Monitoring membrane voltage using two-photon excitation of fluorescent voltage-sensitive dyes
Jonathan AN Fisher and Brian M Salzberg
Chapter 12: Random-access multiphoton microscopy for fast three-dimensional Imaging
Gaddum Duemani Reddy and Peter Saggau
Chapter 13: Second harmonic imaging of membrane potential
Leslie M. Loew and Aaron Lewis
Chapter 14: Genetically encoded protein sensors of membrane potential
Lei Jin, Hiroki Mutoh, Thomas Knopfel, Lawrence B Cohen, Thom Hughes, Vincent A Pieribone, Ehud Y Isacoff, Brian M Salzberg, and Bradley J Baker
Lawrence B Cohen
Chapter 2: Design and use of organic voltage sensitive dyes
Leslie M Loew
Chapter 3: Imaging submillisecond membrane potential changes from individual regions of single axons, dendrites and spines
Marco Canepari, Marko Popovic, Kaspar Vogt, Knut Holthoff, Arthur Konnerth, Brian M Salzberg, Amiram Grinvald, Srdjan D Antic and Dejan Zecevic
Chapter 4: Combined voltage and calcium imaging and signal calibration
Marco Canepari, Peter Saggau and Dejan Zecevic
Chapter 5: Use of fast-responding voltage-sensitive dyes for large-scale recording of neuronal spiking activity with single-cell resolution
William N Frost, Jean Wang, Christopher J Brandon, Caroline Moore-Kochlacs, Terrence J Sejnowski and Evan S Hill
Chapter 6: Monitoring integrated activity of individual neurons using FRET-based voltage-sensitive dyes
Kevin L Briggman, William B Kristan, Jesús E González, David Kleinfeld and Roger Y Tsien
Chapter 7: Monitoring population membrane potential signals from neocortex
Xiaoying Huang, Weifeng Xu, Kentaroh Takagaki and Jian-young Wu
Chapter 8: Monitoring population membrane potential signals during functional development of neuronal circuits in vertebrate embryos
Yoko Momose-Sato, Katsushige Sato and Kohtaro Kamino
Chapter 9: Imaging the dynamics of mammalian neocortical population activity in-vivo
Amiram Grinvald, David Omer, Shmuel Naaman and Dahlia Sharon
Chapter 10: Imaging the dynamics of neocortical population activity in behaving and freely moving mammals
Amiram Grinvald and Carl CH Petersen
Chapter 11: Monitoring membrane voltage using two-photon excitation of fluorescent voltage-sensitive dyes
Jonathan AN Fisher and Brian M Salzberg
Chapter 12: Random-access multiphoton microscopy for fast three-dimensional Imaging
Gaddum Duemani Reddy and Peter Saggau
Chapter 13: Second harmonic imaging of membrane potential
Leslie M. Loew and Aaron Lewis
Chapter 14: Genetically encoded protein sensors of membrane potential
Lei Jin, Hiroki Mutoh, Thomas Knopfel, Lawrence B Cohen, Thom Hughes, Vincent A Pieribone, Ehud Y Isacoff, Brian M Salzberg, and Bradley J Baker