Synaptic Transmission

Authors:

Language: English
Cover of the book Synaptic Transmission

Subjects for Synaptic Transmission

Keywords

Acetylcholinesterase; Action potential; Action potential propagation; Active membrane properties; Active zone; Alzheimer’s disease; Animal model system; Arachidonic acid pathway; Astrocytes; CGRP; CORE complex; Calcium; Calcium buffering; Calcium microdomains; Calcium waves; Carbon monoxide; Catecholamines; Choline acetyltransferase; Clathrin-mediated endocytosis; Connexons; Corelease; Cotransmission; Cyclic AMP pathway; Dendritic filtering; Dendritic spines; Direct pathway; Dopamine; Effector proteins; Electrical synapse plasticity; Endocytosis; Endplate potential; Epinephrine; G-proteins; GABA; Gap junction; Glial cells; Glutamate; Glycine; Habituation; Histamine; Hydrogen sulfide; Hypothesis; Ion channel; Ion channel structure; Ion channel subunits; Ion channels; Ionic currents; Ionotropic receptors; Ions; L-DOPA; Large dense-core vesicles; Ligand-gated ion channels; Long-term synaptic plasticity; Membrane potential; Metabotropic receptors; Miniature endplate potential; NMDA receptors; Neuromodulator; Neuromuscular junction; Neuron Doctrine; Neuropeptide Y; Neurotransmitter; Neurotransmitter phenotype; Neurotransmitter release; Neurotransmitter switching; Nicotinic acetylcholine receptors; Nitric oxide; Nitric oxide synthetase; Norepinephrine; Passive membrane properties; Phosphoinositol pathway; Prepropeptide; Quantal analysis; Quantal theory; Receptor gating; Regulation of neurotransmitter synthesis; Reticular theory; Retrograde messenger; Reuptake; Reversal potential; Second messenger; Sensitization; Serotonin; Short-term synaptic plasticity; Spike timing-dependent plasticity; Synapse formation; Synapse structure; Synaptic vesicle; Synaptotagmin; Synchronization; Synthetic pathways; Termination of action; Vesicle fusion; Vesicle pools; Vesicle trafficking; Vesicular acetylcholine transporter; Voltage clamp; Voltage-gated calcium channels

146.54 €

In Print (Delivery period: 14 days).

Add to cartAdd to cart
Publication date:
528 p. · 19x23.3 cm · Paperback

Synaptic Transmission is a comprehensive guide to the topic of neurotransmission that provides an in-depth discussion on many aspects of synapse structure and function?a fundamental part of the neuroscience discipline. Chapters include boxes that describe renowned/award-winning researchers and their contributions to the field of synaptic transmission, diseases relevant to the material presented, details of experimental approaches used to study synaptic transmission, and interesting asides that expand on topics covered. This book will inspire students to appreciate how the basic cellular and molecular biology of the synapse can lead to a better understanding of nervous system function and neurological disorders.

1. Introduction

Part 1: Synaptic Biophysics and Nerve Terminal Structure2. The formation and Structure of Synapses3. Basics of Cellular Neurophysiology4. Ion Channels and Their Role in Generating Action Potentials5. Electrical Synapses

Part 2: Regulation of Chemical Transmitter Release6. Function of Chemical Synapses and the Quantal Theory of Transmitter Release7. Calcium Homeostasis, Calcium Channels, and Transmitter Release8. Cellular and Molecular Mechanisms of Exocytosis9. Cellular and Molecular Mechanisms of Endocytosis and Synaptic Vesicle Trafficking

Part 3: Receptors and Signaling10. Introduction to Receptors11. Ionotropic Receptors12. Metabotropic G-protein-coupled Receptors and Their Cytoplasmic Signaling Pathways13. Synaptic Integration Within Postsynaptic Neurons14. Synaptic Plasticity

Part 4: Chemical Transmitters15. Introduction to Chemical Transmitter Systems16. Acetylcholine17. Monoamine Transmitters18. Amino Acid Neurotransmitters19. Neuropeptide Transmitters20. Gaseous Neurotransmitters21. The Use of Multiple Neurotransmitters at Synapses22. Complex Signaling Within Tripartite Synapses

Students and researchers in the neurobiological, biological, and biomedical sciences; neuroscientists; neurobiologists; post-doctoral fellows and researchers in neuroscience
Dr. Meriney is Professor of Neuroscience and Psychiatry at the University of Pittsburgh. He completed his Ph.D. in Physiology / Neuroscience with Dr. Guillermo Pilar at the University of Connecticut studying the development of parasympathetic synapses that innervate the intrinsic eye muscles. He then moved on to postdoctoral training in synaptic physiology at UCLA under the direction of Dr. Alan Grinnell where he used the neuromuscular junction as a model system to study presynaptic mechanisms of transmitter release. At the University of Pittsburgh, he has developed a research program focused on neurotransmitter release, plasticity, and diseases of the synapse, including the development of a new class of calcium channel gating modifiers with therapeutic potential to treat various neuromuscular disorders that result in weakness. Dr. Meriney has received grant support for this research from the National Institutes of Health, the National Science Foundation, the American Heart Association, and the Muscular Dystrophy Association. Dr. Meriney has developed and taught several undergraduate courses at the University of Pittsburgh including Developmental Neuroscience and Synaptic Transmission, that both serve a relatively large class of undergraduates majoring in Neuroscience. He is also currently the co-director for the graduate program within the Center for Neuroscience at the University of Pittsburgh, a multi-departmental cross campus PhD training program.
Dr. Fanselow completed her Ph.D. in neurobiology with Dr. Miguel Nicolelis at Duke University, where she studied the function of the thalamocortical loop in the rodent somatosensory system. Additionally, she pioneered methods for using trigeminal nerve stimulation as a treatment for epilepsy. She then did a postdoctoral fellowship with Dr. Barry Connors at Brown University, where her research focused on neurophysiological aspects of synaptic connectivity and the roles inhibitory neurons play neuronal networks. Her
  • Provides a comprehensive reference on synaptic structure, physiology, function and neurotransmission
  • Discusses many landmark experiments in the field of synaptic transmission to emphasize core principles
  • Includes references to primary scientific literature, relevant review articles and books, many of which could be assigned as discussion material for courses focused on this topic