Textbook of Ion Channels Volume I
Fundamental Mechanisms and Methodologies
Herausgeber: Zheng, Jie; Trudeau, Matthew C.
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Textbook of Ion Channels Volume I
Fundamental Mechanisms and Methodologies
Herausgeber: Zheng, Jie; Trudeau, Matthew C.
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This three-volume textbook provides a wide-ranging reference source on ion channels for students, instructors, and researchers. Volume I covers fundamental topics and basic principles, and offers a practical guide of cardinal methods for researching ion channels.
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This three-volume textbook provides a wide-ranging reference source on ion channels for students, instructors, and researchers. Volume I covers fundamental topics and basic principles, and offers a practical guide of cardinal methods for researching ion channels.
Produktdetails
- Produktdetails
- Verlag: Taylor & Francis Ltd
- Seitenzahl: 318
- Erscheinungstermin: 9. Juni 2023
- Englisch
- Abmessung: 180mm x 262mm x 23mm
- Gewicht: 858g
- ISBN-13: 9780367538156
- ISBN-10: 0367538156
- Artikelnr.: 67259532
- Verlag: Taylor & Francis Ltd
- Seitenzahl: 318
- Erscheinungstermin: 9. Juni 2023
- Englisch
- Abmessung: 180mm x 262mm x 23mm
- Gewicht: 858g
- ISBN-13: 9780367538156
- ISBN-10: 0367538156
- Artikelnr.: 67259532
Jie Zheng, PhD, is a professor at the University of California Davis School of Medicine, where he has served as a faculty member in the Department of Physiology and Membrane Biology since 2004. Dr. Zheng earned a bachelor's degree in physiology and biophysics (1988) and a master's degree in biophysics (1991) at Peking University. He earned a PhD in physiology (1998) at Yale University, where he studied with Dr. Fredrick J. Sigworth on patch-clamp recording, single-channel analysis, and voltage-dependent activation mechanisms. He received his postdoctoral training at the Howard Hughes Medical Institute (HHMI) and the University of Washington during 1999-2003, working with Dr. William N. Zagotta on the cyclic nucleotide-gated channels activation mechanism and novel fluorescence techniques for ion channel research. Currently, Dr. Zheng's research focuses on temperature-sensitive TRP channels. Matthew C. Trudeau, PhD, is a professor in the Department of Physiology at the University of Maryland School of Medicine in Baltimore, Maryland. He earned a bachelor's degree in biochemistry and molecular biology in 1992 and a PhD in physiology in 1998 while working with Gail Robertson, PhD, at the University of Wisconsin-Madison. His thesis work was on the properties of voltage-gated potassium channels in the human ether-aì-go-go related gene (hERG) family and the role of these channels in heart disease. Dr. Trudeau was a postdoctoral fellow with William Zagotta, PhD, at the University of Washington and the Howard Hughes Medical Institute (HHMI) in Seattle from 1998 to 2004, where he focused on the molecular physiology of cyclic nucleotide-gated ion channels, the mechanism of their modulation by calcium-calmodulin, and their role in an inherited form of vision loss. Currently, Dr. Trudeau's work focuses on hERG potassium channels, their biophysical mechanisms, and their role in cardiac physiology and cardiac arrhythmias.
Part I: Fundamental Mechanisms 1. Ion Selectivity and Conductance 2.
Voltage-Dependent Gating of Ion Channels 3. Ligand-Dependent Gating
Mechanism 4. Mechanosensitive Channels and Their Emerging Gating Mechanisms
5. Inactivation and Desensitization 6. Ion Channel Inhibitors Part II:
Methodologies 7. Expression of Channels in Heterologous Systems and Voltage
Clamp Recordings of Macroscopic Currents 8. Patch Clamping and
Single-Channel Analysis 9. Patch Clamp Recordings from Native Cells and
Isolation of Membrane Currents 10. Models of Ion Channel Gating 11.
Investigating Ion Channel Structure and Dynamics Using Fluorescence
Spectroscopy 12. Ion Channel Structural Biology in the Era of Single
Particle Cryo-EM 13. Protein Crystallography 14. Rosetta Structural
Modeling 15. Molecular Dynamics 16. Genetic Models and Transgenics 17. EPR
and DEER Spectroscopy
Voltage-Dependent Gating of Ion Channels 3. Ligand-Dependent Gating
Mechanism 4. Mechanosensitive Channels and Their Emerging Gating Mechanisms
5. Inactivation and Desensitization 6. Ion Channel Inhibitors Part II:
Methodologies 7. Expression of Channels in Heterologous Systems and Voltage
Clamp Recordings of Macroscopic Currents 8. Patch Clamping and
Single-Channel Analysis 9. Patch Clamp Recordings from Native Cells and
Isolation of Membrane Currents 10. Models of Ion Channel Gating 11.
Investigating Ion Channel Structure and Dynamics Using Fluorescence
Spectroscopy 12. Ion Channel Structural Biology in the Era of Single
Particle Cryo-EM 13. Protein Crystallography 14. Rosetta Structural
Modeling 15. Molecular Dynamics 16. Genetic Models and Transgenics 17. EPR
and DEER Spectroscopy
Part I: Fundamental Mechanisms 1. Ion Selectivity and Conductance 2.
Voltage-Dependent Gating of Ion Channels 3. Ligand-Dependent Gating
Mechanism 4. Mechanosensitive Channels and Their Emerging Gating Mechanisms
5. Inactivation and Desensitization 6. Ion Channel Inhibitors Part II:
Methodologies 7. Expression of Channels in Heterologous Systems and Voltage
Clamp Recordings of Macroscopic Currents 8. Patch Clamping and
Single-Channel Analysis 9. Patch Clamp Recordings from Native Cells and
Isolation of Membrane Currents 10. Models of Ion Channel Gating 11.
Investigating Ion Channel Structure and Dynamics Using Fluorescence
Spectroscopy 12. Ion Channel Structural Biology in the Era of Single
Particle Cryo-EM 13. Protein Crystallography 14. Rosetta Structural
Modeling 15. Molecular Dynamics 16. Genetic Models and Transgenics 17. EPR
and DEER Spectroscopy
Voltage-Dependent Gating of Ion Channels 3. Ligand-Dependent Gating
Mechanism 4. Mechanosensitive Channels and Their Emerging Gating Mechanisms
5. Inactivation and Desensitization 6. Ion Channel Inhibitors Part II:
Methodologies 7. Expression of Channels in Heterologous Systems and Voltage
Clamp Recordings of Macroscopic Currents 8. Patch Clamping and
Single-Channel Analysis 9. Patch Clamp Recordings from Native Cells and
Isolation of Membrane Currents 10. Models of Ion Channel Gating 11.
Investigating Ion Channel Structure and Dynamics Using Fluorescence
Spectroscopy 12. Ion Channel Structural Biology in the Era of Single
Particle Cryo-EM 13. Protein Crystallography 14. Rosetta Structural
Modeling 15. Molecular Dynamics 16. Genetic Models and Transgenics 17. EPR
and DEER Spectroscopy