ROUTLEDGE HANDBOOK OF MOTOR CONTROL AND MOTOR LEARNING The Routledge Handbook of Motor Control and Motor Learning is the fi rst book to offer a comprehensive survey of neurophysiological, behavioural and biomechanical aspects of motor function. Adopting an integrative approach, it examines the full range of key topics in contemporary human movement studies, explaining motor behaviour in depth from the molecular level to behavioural consequences. The book contains contributions from the world’s leading experts in motor control and motor learning, and is composed of fi ve thematic parts: • Theories and models • Basic aspects of motor control and learning • Motor control and learning in locomotion and posture • Motor control and learning in voluntary actions • Challenges in motor control and learning Mastering and improving motor control may be important in sports, but it becomes even more relevant in rehabilitation and clinical settings, where the prime aim is to regain motor function. Therefore, the book addresses not only basic and theoretical aspects of motor control and learning but also applied areas like robotics, modelling and complex human movements. This book is both a defi nitive subject guide and an important contribution to the contemporary research agenda. It is, therefore, important reading for students, scholars and researchers working in sports and exercise science, kinesiology, physical therapy, medicine and neuroscience. Albert Gollhofer is Professor and Head of the Department of Sport Sciences at the University of Freiburg, Germany. He is former President of the European College of Sport Science and of the German Society of Biomechanics. Wolfgang Taube is Professor and Head of the Movement and Sport Science Department at the University of Fribourg in Switzerland. He is a member of the national research council Switzerland and executive member of the Swiss Society of Sport. Jens Bo Nielsen is Professor of Human Motor Control at the Institute of Exercise and Sport Sciences & Institute of Neuroscience and Pharmacology, University of Copenhagen, Denmark. He is head of the research group Copenhagen Neural Control of Movement. http://avaxhome.ws/blogs/ChrisRedfield ROUTLEDGE HANDBOOK OF MOTOR CONTROL AND MOTOR LEARNING Edited by Albert Gollhofer, Wolfgang Taube and Jens Bo Nielsen First published 2012 by Routledge 2 Park Square, Milton Park, Abingdon, Oxon OX14 4RN Simultaneously published in the USA and Canada by Routledge 711 Third Avenue, New York, NY 10017 Routledge is an imprint of the Taylor & Francis Group, an informa business © 2012 Albert Gollhofer, Wolfgang Taube and Jens Bo Nielsen The right of the editors to be identifi ed as the authors of the editorial material, and of the authors for their individual chapters, has been asserted in accordance with sections 77 and 78 of the Copyright, Designs and Patents Act 1988. All rights reserved. No part of this book may be reprinted or reproduced or utilised in any form or by any electronic, mechanical, or other means, now known or hereafter invented, including photocopying and recording, or in any information storage or retrieval system, without permission in writing from the publishers. Trademark notice : Product or corporate names may be trademarks or registered trademarks, and are used only for identifi cation and explanation without intent to infringe. British Library Cataloguing in Publication Data A catalogue record for this book is available from the British Library Library of Congress Cataloging in Publication Data Library of Congress Cataloging-in-Publication Data Routledge handbook of motor control and motor learning / edited by Albert Gollhofer Wolfgang Taube and Jens Bo Nielsen. p. cm. ISBN 978–0–415–66960–3 (hbk) — ISBN 978–0–203–13274–6 (ebk) 1. Motor learning—Handbooks, manuals, etc. 2. Motor control—Handbooks, manuals, etc. I. Gollhofer, Albert. II. Taube, Wolfgang. III. Nielsen, Jens Bo. BF295.R68 2013 152.3'34—dc23 2012019652 ISBN: 978–0–415–66960–3 (hbk) ISBN: 978–0–203–13274–6 (ebk) Typeset in Bembo by Refi neCatch Limited, Bungay, Suffolk CONTENTS List of fi gures and tables viii Acknowledgements xii Introduction 1 PART I Theories and models 5 1 Theoretical models of motor control and motor learning 7 Adrian M. Haith and John W. Krakauer 2 What can we learn from animal models? 29 Eric M. Rouiller 3 Postural control by disturbance estimation and compensation through long-l oop responses 50 Thomas Mergner 4 Motor learning explored with myoelectric and neural interfaces 71 Andrew Jackson and Kianoush Nazarpour 5 Biomechanical and neuromechanical concepts for legged locomotion: Computer models and robot validation 90 Andre Seyfarth, Sten Grimmer, Daniel Häufl e, Horst-Moritz Maus, Frank Peuker and Karl-Theodor Kalveram v Contents PART II Basic aspects of motor control and learning 111 6 Visual activation of short latency reinforcement mechanisms in the basal ganglia 113 Nicolas Vautrelle, Mariana Leriche and Peter Redgrave 7 The role of augmented feedback in human motor learning 135 Christian Leukel and Jesper Lundbye-Jensen 8 Neuroscientifi c aspects of implicit motor learning in sport 155 Frank Zhu, Jamie Poolton and Rich Masters 9 Mirror neurons and imitation 175 Stefano Rozzi, Giovanni Buccino and Pier F. Ferrari PART III Motor control and learning in locomotion and posture 195 10 Neural control of walking 197 Michael J. Grey, Laurent Bouyer and Jens Bo Nielsen 11 Adaptive plasticity of gait 213 Laurent Bouyer, Michael J. Grey and Jens Bo Nielsen 12 Motor control and motor learning in stretch-s hortening cycle movements 231 Wolfgang Taube, Christian Leukel and Albert Gollhofer 13 Postural control and balance training 252 Wolfgang Taube and Albert Gollhofer PART IV Motor control and learning in voluntary actions 281 14 Body schema, illusions of movement and body perception 283 Mark Schram Christensen 15 Voluntary movement: Limitations and consequences of the anatomy and physiology of motor pathways 304 John C. Rothwell and Jens Bo Nielsen 16 Acute and long-t erm neural adaptations to training 319 Jacques Duchateau, Tibor Hortobágyi and Roger M. Enoka vi Contents PART V Challenges in motor control and learning 351 17 Motor control and motor learning under fatigue conditions 353 Janet L. Taylor 18 Movement disorders: Implications for the understanding of motor control 384 Michèle Hubli and Volker Dietz Index 409 vii LIST OF FIGURES AND TABLES Figures 1.1 Comparison of effort and endpoint variability costs for open- loop arm and eye movements. 13 1.2 Maximum Likelihood Estimation of hand position from visual and proprioceptive estimates. 19 1.3 Adaptation as Bayesian estimation. 23 2.1 Schematic representation of the major motor cortical areas in non-h uman primates, as seen on a lateral view of the left hemisphere and the right hemisphere. 31 2.2 (a) Mean reaction times obtained from a macaque monkey performing detection of acoustic stimuli, or of visual stimuli or to simultaneous presentation of the two sensory modalities. (b) Cartoon illustrating the scenario of a possible fast transmission of information from sensory cortices to premotor cortex, via the thalamus. 39 3.1 Schematic representation of center of mass, and center of pressure. 52 3.2 Vestibular–neck interaction and re-i nterpretation in terms of coordinate transformation. 54 3.3 Servo control model. 61 3.4 Servo control model extended by long latency refl ex loops for disturbance estimation and compensation (‘DEC’) model. 62 3.5 More detailed version of DEC model. 63 3.6 Emergence of movement synergy and postural adjustment from hierarchical DEC control (extended to include the hip joints in addition to the ankle joints). 64 3.7 Picture of postural control robot Posturob II (2 DOF, hip and ankle joints). 65 3.8 Comparison of postural responses between human and robot experiments. 66 4.1 Exploring abstract sensorimotor learning with a myoelectric interface. 73 viii List of fi gures and tables 4.2 When holding an object steady, the net force on the object is more important than the absolute force exerted by either fi nger or thumb muscles. 78 4.3 Exploring fl exible control of synergies using a myoelectric interface. 80 4.4 Spike- triggered averaging reveals monosynaptic facilitation of muscles via the corticospinal pathway. 82 4.5 Divergence and convergence in the corticospinal system allows fl exible control of muscle synergies. 83 4.6 S chematic of hierarchal redundancy within the motor system. 84 4.7 Schematic of a Brain–Machine Interface experiment. 86 5.1 (a) Experimental evidence for spring- like leg behavior in human walking and running provided by mean leg force vs. leg length traces of 21 subjects. (b) The bipedal SLIP model predicts walking and running patterns based on the assumption of spring- like leg behavior. (c) Stable gait patterns can be characterized by three parameters. 91 5.2 (a) Ground reaction forces of a 14-month- old child walking several steps on an instrumented treadmill. (b) Ground reaction forces of a person with long-t erm unilateral leg amputation using three different kinds of knee joints. 94 5.3 Asymmetric walking described in the bipedal SLIP model. 95 5.4 Stability in spring-m ass hopping with variable leg parameters k (t) and L (t) during contact. 97 0 5.5 The VPP concept. 98 5.6 (a) Extension of the SLIP model to 3D running. (b) Predicted region of 3D stable running. 99 5.7 Model evolution: the path from a reductive model to more elaborated representative models for human hopping. 102 5.8 (a) Schematic approach to legged locomotion based on three functional levels. (b) Extension of this approach to quadrupedal locomotion. 104 5.9 Conceptual robots to investigate the interplay of body mechanics and muscle function in hopping. 105 6.1 Principal components of the mammalian basal ganglia. 114 6.2 Cortico-b asal ganglia- cortical loops in animals and humans. 115 6.3 Selective disinhibition within the re-e ntrant parallel looped architecture of the basal ganglia represents a mechanism for selection. 117 6.4 A neural network confi gured to determine agency and the discovery of novel actions. 125 6.5 Separate mechanisms of reinforcement could bias section within the re- entrant parallel looped architecture of the basal ganglia. 127 7.1 Types of feedback. 136 7.2 Augmented feedback. 137 7.3 Dimensions of augmented feedback. 141 8.1 The location of the brain regions of interest for studies using EEG methodology to investigate cortical activity during motor performance. 158 8.2 (a) A visual representation of waveform patterns from two exemplar trials that participants tracked during practice trials. (b) Laparoscopic ix List of fi gures and tables skills training set-u p. (c) Electroencephalographic alpha T3–Fz and T4–Fz coherence in the retention test. 163 8.3 (a) Electroencephalographic alpha2 T3–Fz and T4–Fz coherence across the four second period prior to ball strike in the retention test. (b) Golf putting set- up. 164 8.4 Electroencephalographic alpha2 T3–Fz coherence across the four second period prior to ball strike in the retention test and psychological stress transfer test. 166 8.5 Electroencephalographic alpha2 T3–Fz and T4–Fz coherence during putting performance for participants with low and high conscious motor processing scores. 167 9.1 Lateral and mesial views of the monkey brain showing the parcellation of the agranular frontal and posterior parietal cortices. 176 9.2 Goal coding in F5 motor neurons. 177 9.3 Examples of F5 mirror neurons. 179 9.4 (a) Paradigm used for the motor task. (b) Paradigm used for the visual task. (c) Discharge of the neuron during execution (left) and observation (right) of the two actions. 181 9.5 Cortical areas active during observation for imitation. 189 10.1 Human walking. 199 10.2 Schematic view of the neural control of walking. 200 10.3 State dependent refl ex modulation. 201 10.4 Soleus EMG responses evoked by sudden perturbations during walking in human participants. 203 10.5 Gait pattern evoked in the cat by MLR stimulation. 205 10.6 Comparison of TA stretch responses during the walking cycle and during tonic dorsifl exion in a sitting participant. 207 11.1 Foot in the hole protocol. 215 11.2 LGS denervation in the spinal cat. 217 11.3 Elastic force fi eld adaptation protocol. 219 11.4 Phase-specifi c carry-over of force fi eld adaptation aftereffects. 221 11.5 Example of force fi eld adaptation with pseudorandomly inserted catch trials. 222 11.6 Effects of elastic force fi eld adaptation duration and force fi eld intensity on aftereffects duration. 224 11.7 Force fi eld adaptation with catch trials in a non-naïve subject. 224 12.1 Evidence of spinal stretch refl ex activity during hopping on a moveable platform. 235 12.2 Changes in EMG pattern due to modulation of drop height. 238 12.3 Interaction of feedforward and feedback control during stretch-s hortening cycle movement. 241 12.4 The parameterization of the internal model is dependent on the setting of the task. 243 12.5 Drop height specifi c training adaptations of the neuromuscular activity. 247 13.1 Subjects stood quietly with or without body support. 263 13.2 Interrelation of cortical plasticity and stance stability. 268 13.3 Balance training induced adaptations assessed during postural tasks. 269 13.4 Motor tasks in which subjects were measured before and after balance training. 271 x