MARC record from Internet Archive

LEADER: 06283fam a2200481 a 4500
001 4056099
005 20221027025343.0
008 970110t19971997maua b 001 0 eng
010 $a 97001551
020 $a0262193906 (alk. paper)
035 $a(OCoLC)36219348
035 $a(OCoLC)ocm36219348
035 $9AMV7195HS
035 $a(NNC)4056099
035 $a4056099
040 $aDLC$cDLC$dDLC$dNNC-M$dOrLoB-B
050 00 $aQP383.15$b.N48 1997
082 00 $a612.8/252$221
245 00 $aNeurons, networks, and motor behavior /$cedited by Paul S.G. Stein [and others].
260 $aCambridge, Mass. :$bMIT Press,$c[1997], ©1997.
300 $axiii, 305 pages :$billustrations ;$c29 cm.
336 $atext$btxt$2rdacontent
337 $aunmediated$bn$2rdamedia
490 1 $aComputational neuroscience
500 $a"A Bradford book."
504 $aIncludes bibliographical references and indexes.
505 00 $gI.$tSelection and Initiation of Motor Patterns.$g1.$tSelection and Initiation of Motor Behavior /$rSten Grillner, Apostolos P. Georgopoulos and Larry M. Jordan.$g2.$tThe Role of Population Coding in the Control of Movement /$rDavid L. Sparks, William B. Kristan, Jr. and Brian K. Shaw.$g3.$tNeural Substrates for Initiation of Startle Responses /$rRoy E. Ritzmann and Robert C. Eaton --$gII.$tGeneration and Formation of Motor Patterns: Cellular and Systems Properties.$g4.$tBasic Building Blocks of Vertebrate Spinal Central Pattern Generators /$rOle Kiehn, Jorn Hounsgaard and Keith T. Sillar.$g5.$tNeural and Biomechanical Control Strategies for Different Forms of Vertebrate Hindlimb Motor Tasks /$rPaul S. G. Stein and Judith L. Smith.$g6.$tSpinal Networks and Sensory Feedback in the Control of Undulatory Swimming in Lamprey /$rPeter Wallen.$g7.$tSpinal Networks Controlling Swimming in Hatchling Xenopus Tadpoles /$rAlan Roberts, Steve R. Soffe and Ray Perrins.
505 80 $g8.$tRole of Ionic Currents in the Operation of Motor Circuits in the Xenopus Embryo /$rNicholas Dale.$g9.$tIntegration of Cellular and Network Mechanisms in Mammalian Oscillatory Motor Circuits: Insights from the Respiratory Oscillator /$rJeffrey C. Smith.$g10.$tShared Features of Invertebrate Central Pattern Generators /$rAllen I. Selverston, Yuri V. Panchin and Yuri I. Arshavsky [et al.].$g11.$tIntrinsic Membrane Properties and Synaptic Mechanisms in Motor Rhythm Generators /$rRonald L. Calabrese and Jack L. Feldman.$g12.$tOrganization of Neural Networks for the Control of Posture and Locomotion in an Insect /$rMalcolm Burrows --$gIII.$tGeneration and Formation of Motor Patterns: Computational Approaches.$g13.$tHow Computation Aids in Understanding Biological Networks /$rEve Marder, Nancy Kopell and Karen Sigvardt.$g14.$tDynamical Systems Analyses of Real Neuronal Networks /$rJohn Guckenheimer and Peter Rowat.
505 80 $g15.$tRealistic Modeling of Burst Generation and Swimming in Lamprey /$rAnders Lansner, Orjan Ekeberg and Stern Grillner.$g16.$tIntegrate-and-Fire Simulations of Two Molluscan Neural Circuits /$rWilliam N. Frost, James R. Lieb, Jr. and Mark J. Tunstall [et al.] --$gIV.$tModulation and Reconfiguration.$g17.$tChemical Modulation of Vertebrate Motor Circuits /$rKeith T. Sillar, Ole Kiehn and Norio Kudo.$g18.$tModulation of Neural Circuits by Steroid Hormones in Rodent and Insect Model Systems /$rJanis C. Weeks and Bruce S. McEwen.$g19.$tChemical Modulation of Crustacean Stomatogastric Pattern Generator Networks /$rRonald M. Harris-Warrick, Deborah J. Baro and Lisa M. Coniglio [et al.].$g20.$tReconfiguration of the Peripheral Plant during Various Forms of Feeding Behaviors in the Mollusc Aplysia /$rIrving Kupfermann, Vladimir Brezina and Elizabeth C. Cropper [et al.] --$gV.$tShort-Term Modulation of Pattern-Generating Circuits.
505 80 $g21.$tSensory Modulation of Pattern-Generating Circuits /$rKeir G. Pearson and Jan-Marino Ramirez.$g22.$tPresynaptic Mechanisms during Rhythmic Activity in Vertebrates and Invertebrates /$rMichael P. Nusbaum, Abdeljabbar El Manira and Jean-Pierre Gossard [et al.] --$gVI.$tSensory Modification of Motor Output to Control Whole-Body Orientation.$g23.$tControl of Body Orientation and Equilibrium in Vertebrates /$rJane M. Macpherson, Tatiana G. Deliagina and Grigori N. Orlovsky.$g24.$tCentrally Patterned Behavior Generates Sensory Input for Adaptive Control /$rMark A. Willis and Edmund A. Arbas.$g25.$tOculomotor Control in Insects: From Muscles to Elementary Motion Detectors /$rNicholas J. Strausfeld.
520 $aRecent advances in motor behavior research rely on detailed knowledge of the characteristics of the neurons and networks that generate motor behavior. At the cellular level, Neurons, Networks, and Motor Behavior describes the computational characteristics of individual neurons and how these characteristics are modified by neuromodulators. At the network and behavioral levels, the volume discusses how network structure is dynamically modulated to produce adaptive behavior.
520 8 $aComparisons of model systems throughout the animal kingdom provide insights into general principles of motor control. Contributors describe how networks generate such motor behaviors as walking, swimming, flying, scratching, reaching, breathing, feeding, and chewing. An emerging principle of organization is that nervous systems are remarkably efficient in constructing neural networks that control multiple tasks and dynamically adapt to change.
650 0 $aSensorimotor cortex.$0http://id.loc.gov/authorities/subjects/sh87006733
650 0 $aLocomotion.$0http://id.loc.gov/authorities/subjects/sh85077989
650 0 $aNeural networks (Neurobiology)$0http://id.loc.gov/authorities/subjects/sh93002348
650 0 $aNeuromuscular transmission.$0http://id.loc.gov/authorities/subjects/sh85091151
650 0 $aMuscles$xInnervation.
650 2 $aLocomotion.$0https://id.nlm.nih.gov/mesh/D008124
650 2 $aNerve Net.$0https://id.nlm.nih.gov/mesh/D009415
650 2 $aMuscles$xinnervation.$0https://id.nlm.nih.gov/mesh/D009132Q000294
700 1 $aStein, Paul S. G.$0http://id.loc.gov/authorities/names/n97003122
830 0 $aComputational neuroscience.$0http://id.loc.gov/authorities/names/n86711840
852 00 $boff,hsl$hQP383.15$i.N48 1997 Q