Series Foreword | p. ix |
Preface | p. xi |
Selection and Initiation of Motor Patterns | p. 1 |
Selection and Initiation of Motor Behavior | p. 3 |
The Role of Population Coding in the Control of Movement | p. 21 |
Neural Substrates for Initiation of Startle Responses | p. 33 |
Generation and Formation of Motor Patterns: Cellular and Systems Properties | p. 45 |
Basic Building Blocks of Vertebrate Spinal Central Pattern Generators | p. 47 |
Neural and Biomechanical Control Strategies for Different Forms of Vertebrate Hindlimb Motor Tasks | p. 61 |
Spinal Networks and Sensory Feedback in the Control of Undulatory Swimming in Lamprey | p. 75 |
Spinal networks Controlling Swimming in Hatchling Xenopus Tadpoles | p. 83 |
Role of Ionic Currents in the Operation of Motor Circuits in the Xenopus Embryo | p. 91 |
Integration of Cellular and Network Mechanisms in Mammalian Oscillatory Motor Circuits: Insights from the Respiratory Oscillator | p. 97 |
Shared Features of Invertebrate Central Pattern Generators | p. 105 |
Intrinsic Membrane Properties and Synaptic Mechanisms in Motor Rhythm Generators | p. 119 |
Organization of Neural Networks for the Control of Posture and Locomotion in an Insect | p. 131 |
Generation and Formation of Motor Patterns: Computational Approaches | p. 137 |
How Computation Aids in Understanding Biological Networks | p. 139 |
Dynamical Systems Analyses of Real Neuronal Networks | p. 151 |
Realistic Modeling of Burst Generation and Swimming in Lamprey | p. 165 |
Integrate-and-Fire Simulations of Two Molluscan Neural Circuits | p. 173 |
Modulation and Reconfiguration | p. 181 |
Chemical Modulation of Vertebrate Motor Circuits | p. 183 |
Modulation of Neural Circuits by Steroid Hormones in Rodent and Insect Model Systems | p. 195 |
Chemical Modulation of Crustacean Stomatogastric Pattern Generator Networks | p. 209 |
Reconfiguration of the Peripheral Plant during Various Forms of Feeding Behaviors in the Mollusc Aplysia | p. 217 |
Short-Term Modulation of Pattern-Generating Circuits | p. 223 |
Sensory Modulation of Pattern-Generating Circuits | p. 225 |
Presynaptic Mechanisms during Rhythmic Activity in Vertebrates and Invertebrates | p. 237 |
Sensory Modification of Motor Output to Control Whole-Body Orientation | p. 255 |
Control of Body Orientation and Equilibrium in Vertebrates | p. 257 |
Centrally Patterned Behavior Generates Sensory Input for Adaptive Control | p. 269 |
Oculomotor Control in Insects: From Muscles to Elementary Motion Detectors | p. 277 |
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