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v | |
| Preface |
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xi | |
| Acknowledgments |
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xiii | |
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Innate versus learned movements--a false dischotomy? |
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3 | (10) |
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Why and how are posture and movement coordinated? |
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13 | (16) |
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Motor coordination can be fully understood only by studying complex movements |
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29 | (10) |
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The emotional brain: neural correlates of cat sexual behavior and human male ejaculation |
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39 | (10) |
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Section II. Spinal cord and brainstem: developmental and comparative issues |
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Developmental changes in rhythmic spinal neuronal activity in the rat fetus |
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49 | (8) |
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The maturation of locomotor networks |
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57 | (10) |
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Reflections on respiratory rhythm generation |
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67 | (10) |
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Section III. Spinal cord and brainstem: motoneurons, pattern generation and sensory feedback |
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Key mechanisms for setting the input--output gain across the motoneuron pool |
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77 | (20) |
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Rhythm generation for food-ingestive movements |
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97 | (8) |
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Do respiratory neurons control female receptive behavior: a suggested role for a medullary central pattern generator? |
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105 | (10) |
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The central pattern generator for forelimb locomotion in the cat |
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115 | (8) |
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Generating the walking gait: role of sensory feedback |
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123 | (10) |
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Section IV. Spinal cord and brainstem: adaptive mechanisms |
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Cellular transplants: steps toward restoration of function in spinal injured animals |
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133 | (14) |
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Neurotrophic effects on dorsal root regeneration into the spinal cord |
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147 | (8) |
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Effects of an embryonic repair graft on recovery from spinal cord injury |
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155 | (8) |
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Determinants of locomotor recover after spinal injury in the cat |
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163 | (12) |
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Section V. Biomechanical and imaging approaches in movement neuroscience |
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Trunk movements and EMG activity in the cat: level versus upslope walking |
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175 | (8) |
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Biomechanical constraints in hindlimb joints during the quadrupedal versus bipedal locomotion of M. fuscata |
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183 | (8) |
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Reactive and anticipatory control of posture and bipedal locomotion in a nonhuman primate |
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191 | (8) |
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Neural control mechanisms for normal versus Parkinsonian gait |
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199 | (8) |
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Multijoint movement control: the importance of interactive torques |
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207 | (14) |
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Section VI. Descending command issues |
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How the mesencephalic locomotor region recruits hindbrain neurons |
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221 | (10) |
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Role of basal ganglia-brainstem systems in the control of postural muscle tone and locomotion |
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231 | (8) |
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Locomotor role of the corticoreticular-reticulospinal-spinal interneuronal system |
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239 | (12) |
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Cortical and brainstem control of locomotion |
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251 | (12) |
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Direct and indirect pathways for corticospinal control of upper limb motoneurons in the primate |
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263 | (20) |
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Section VII. Supraspinal sensorimotor interactions |
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Arousal mechanisms related to posture and locomotion:
1. Descending modulation |
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283 | (8) |
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Arousal mechanisms related to posture and locomotion:
2. Ascending modulation |
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291 | (8) |
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Switching between cortical and subcortical sensorimotor pathways |
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299 | (10) |
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Section VIII. Cerebellar interactions and control mechanisms |
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Cerebellar activation of cortical motor regions: comparisons across mammals |
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309 | (10) |
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Task-dependent role of the cerebellum in motor learning |
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319 | (12) |
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Role of the cerebellum in eyeblink conditioning |
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331 | (10) |
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Integration of multiple motor segments for the elaboration of locomotion: role of the fastigial nucleus of the cerebellum |
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341 | (12) |
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Role of the cerebellum in the control and adaptation of gait in health and disease |
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353 | (16) |
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Section IX. Eye--head--neck coordination |
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Current approaches and future directions to understanding control of head movement |
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369 | (14) |
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The neural control of orienting: role of multiple-branching reticulospinal neurons |
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383 | (8) |
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Role of the frontal eye fields in smooth-gaze tracking |
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391 | (12) |
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Role of cross-striolar and commissural inhibition in the vestibulocollic reflex |
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403 | (8) |
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Functional synergies among neck muscles revealted by branching patterns of single long descending motor-tract axons |
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411 | (12) |
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Control of orienting movements: role of multiple tectal projections to the lower brainstem |
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423 | (16) |
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Pedunculo-pontine control of visually guided saccades |
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439 | (10) |
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Section X. Higher control mechanisms: basal ganglia, sensorimotor cortex and frontal lobe |
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Macro-architecture of basal ganglia loops with the cerebral cortex: use of rabies virus to reveal multisynaptic circuits |
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449 | (12) |
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A new dynamic model of the cortico-basal ganglia loop |
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461 | (6) |
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Functional recovery after lesions of the primary motor cortex |
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467 | (10) |
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Adaptive behavior of cortical neurons during a perturbed arm-reaching movement in a nonhuman primate |
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477 | (14) |
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The quest to understand bimanual coordination |
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491 | (16) |
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Functional specialization in dorsal and ventral premotor areas |
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507 | (6) |
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Spatially directed movement and neuronal activity in freely moving monkey |
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513 | (8) |
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| Subject Index |
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521 | |
