Hackensack, NJ, : World Scientific Pub., c2005

1-281-89920-8

9786611899202

981-270-323-3

1 online resource (418 p.)

CoombesStephen

BressloffPaul C

612.8/1

Neural transmission

Sensory neurons

Inglese

Description based upon print version of record.

Includes bibliographical references and index.

PREFACE; CONTENTS; PART I: BURSTING AT THE SINGLE CELL LEVEL; CHAPTER 1 THE DEVELOPMENT OF THE HINDMARSH-ROSE MODEL FOR BURSTING; CHAPTER 2 NEGATIVE CALCIUM FEEDBACK: THE ROAD FROM CHAY-KEIZER; CHAPTER 3 AUTOREGULATION OF BURSTING OF AVP NEURONS OF THE RAT HYPOTHALAMUS; CHAPTER 4 BIFURCATIONS IN THE FAST DYNAMICS OF NEURONS: IMPLICATIONS FOR BURSTING; CHAPTER 5 BURSTING IN 2-COMPARTMENT NEURONS: A CASE STUDY OF THE PINSKY-RINZEL MODEL; CHAPTER 6 GHOSTBURSTING: THE ROLE OF ACTIVE DENDRITES IN ELECTROSENSORY PROCESSING; PART 11: BURSTING AT THE NETWORK LEVEL

CHAPTER 7 ANALYSIS OF CIRCUITS CONTAINING BURSTING NEURONS USING PHASE RESETTING CURVESCHAPTER 8 BURSTING IN COUPLED CELL SYSTEMS; CHAPTER 9 MODULATORY EFFECTS OF COUPLING ON BURSTING MAPS; CHAPTER 10 BEYOND SYNCHRONIZATION: MODULATORY AND BURSTING EMERGENT EFFECTS OF COUPLING IN SQUARE-WAVE; CHAPTER 11 BURSTING IN EXCITATORY NEURAL NETWORKS; CHAPTER 12 OSCILLATORY BURSTING MECHANISMS IN RESPIRATORY PACEMAKER NEURONS AND NETWORKS; CHAPTER 13 GEOMETRIC ANALYSIS OF BURSTING NETWORKS; CHAPTER 14 ELLIPTIC

BURSTERS, DEPOLARIZATION BLOCK, AND WAVES; INDEX

Neurons in the brain communicate with each other by transmitting sequences of electrical spikes or action potentials. One of the major challenges in neuroscience is to understand the basic physiological mechanisms underlying the complex spatiotemporal patterns of spiking activity observed during normal brain functioning, and to determine the origins of pathological dynamical states such as epileptic seizures and Parkinsonian tremors. A second major challenge is to understand how the patterns of spiking activity provide a substrate for the encoding and transmission of information, that is, how