Progress in Motor Control
Crossroads between Neurophysiology and Applications
- 1st Edition - June 1, 2026
- Latest edition
- Editors: Mark L. Latash, Mariusz Furmanek, Mindy F. Levin, Monica Perez, Eugene Tunik
- Language: English
Progress in Motor Control: Crossroads between Neurophysiology and Applications provides an in-depth exploration of the evolving field of motor control, synthesizing the latest… Read more
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Progress in Motor Control: Crossroads between Neurophysiology and Applications provides an in-depth exploration of the evolving field of motor control, synthesizing the latest innovative research. This volume emphasizes the complex relationships within the central nervous system and their critical roles in the neural control of movement, featuring contributions from leading experts who employ a range of approaches, from basic physical principles to advanced control theory. It addresses applied aspects of motor control, focusing on recovery strategies for functional movements in patients with conditions such as spinal cord injuries, subcortical disorders, and strokes. Divided into five comprehensive parts, the book covers theoretical advances, neurophysiological mechanisms, motor learning, neural plasticity, and motor disorders, including essential topics like neural population dynamics and the dual role of vestibulospinal reflexes. The final sections highlight practical strategies for improving recovery outcomes following neurological events. This essential resource effectively bridges the gap between foundational research and clinical application, making it invaluable for researchers, clinicians, and students dedicated to advancing knowledge in motor control and rehabilitation.
- Integrates cutting-edge theories from multiple disciplines to offer a holistic view of motor control mechanisms
- Highlights clinical case studies that demonstrate real-world applications of motor control research in rehabilitation settings
- Discusses the impact of emerging technologies, such as non-invasive brain stimulation, on the understanding and treatment of motor disorders
- Examines the role of environmental factors and contextual influences on motor performance and learning
- Provides practical insights for clinicians on tailoring interventions based on the latest findings in neurophysiology and motor learning
Instructors, researchers, clinicians and other professionals in all the fields related to biological movement including movement disorders and sensorimotor rehabilitation; students in Kinesiology (Movement Science), Psychology, Physiology, Neuroscience, and Physical Therapy
Part I: Theoretical Advances in Motor Control
1. Neural population dynamics, synergies, and the uncontrolled manifold: A conceptual analysis.
2. Origins of processes within the uncontrolled manifold
3. Preparedness in thought and action
4. Movement vigor as a reflection of subjective value
5. Exploration for learning new coordinative structures
Part II: Advances in Understanding Neurophysiological Mechanisms
6. Relative contributions of corticospinal and reticulospinal tracts to control of the primate upper limb
7. Investigation of human reach to grasp using non-invasive brain stimulation
8. Descending and spinal control of the electrical properties of motoneurons to match the functions of their muscles
9. The dual role of vestibulospinal reflexes: Excitatory and inhibitory influences on limb muscle activity
10. Locomotor coordination and dynamic visual acuity
Part III: Motor Learning and Neural Plasticity
11. Non-invasive neurobehavioral training to improve motor behaviors and functions of the targeted pathway in CNS disorders
12. Targeting sensorimotor networks with noninvasive brain stimulation
13. Body mapping in infancy: Implications for goal-directed movements
14. New perspectives on cortical and subcortical mechanisms for visuomotor adaptation and their clinical implications
Part IV: Motor Disorders
15. The role of astrocytes in regulating neuroenergetics and synaptic plasticity as therapeutic targets in treating Parkinson's disease
16. Discoveries of motor control as the foundation for unexpected walking recovery after pediatric spinal cord injury
17. Impact of exercise on cognitive circuitry in Parkinson's disease
18. Stability of walking in healthy and neurological conditions
19. Motor output variability in movement disorders
Part V: Recovery of the Motor Function
20. Translation of motor control principles to functional movement improvement after stroke
21. Strategies to maximize functional restoration following spinal cord injury
22. Motor control as a pathway to recovery in neurorehabilitation
1. Neural population dynamics, synergies, and the uncontrolled manifold: A conceptual analysis.
2. Origins of processes within the uncontrolled manifold
3. Preparedness in thought and action
4. Movement vigor as a reflection of subjective value
5. Exploration for learning new coordinative structures
Part II: Advances in Understanding Neurophysiological Mechanisms
6. Relative contributions of corticospinal and reticulospinal tracts to control of the primate upper limb
7. Investigation of human reach to grasp using non-invasive brain stimulation
8. Descending and spinal control of the electrical properties of motoneurons to match the functions of their muscles
9. The dual role of vestibulospinal reflexes: Excitatory and inhibitory influences on limb muscle activity
10. Locomotor coordination and dynamic visual acuity
Part III: Motor Learning and Neural Plasticity
11. Non-invasive neurobehavioral training to improve motor behaviors and functions of the targeted pathway in CNS disorders
12. Targeting sensorimotor networks with noninvasive brain stimulation
13. Body mapping in infancy: Implications for goal-directed movements
14. New perspectives on cortical and subcortical mechanisms for visuomotor adaptation and their clinical implications
Part IV: Motor Disorders
15. The role of astrocytes in regulating neuroenergetics and synaptic plasticity as therapeutic targets in treating Parkinson's disease
16. Discoveries of motor control as the foundation for unexpected walking recovery after pediatric spinal cord injury
17. Impact of exercise on cognitive circuitry in Parkinson's disease
18. Stability of walking in healthy and neurological conditions
19. Motor output variability in movement disorders
Part V: Recovery of the Motor Function
20. Translation of motor control principles to functional movement improvement after stroke
21. Strategies to maximize functional restoration following spinal cord injury
22. Motor control as a pathway to recovery in neurorehabilitation
- Edition: 1
- Latest edition
- Published: June 1, 2026
- Language: English
ML
Mark L. Latash
Mark Latash is a Distinguished Professor of Kinesiology and Director of the Motor Control Laboratory at the Pennsylvania State University. He received equivalents of B.S. in Physics and M.S. in Physics of Living Systems from the Moscow Institute of Physics and Technology, and a Ph.D. in Physiology from Rush University in Chicago. His research interests are focused on the control and coordination of human voluntary movements, movement disorders in neurological disorders, and effects of rehabilitation. He is the author of “Control of Human Movement” (1993) “The Neurophysiological Basis of Movement” (1998, 2008), “Synergy” (2008), and “Fundamentals of Motor Control” (2012). In addition, he edited eight books and published about 350 papers in refereed journals. Mark Latash served as the Founding Editor of the journal “Motor Control” (1996-2007) and as President of the International Society of Motor Control (2001-2005). He has served as Director of the annual Motor Control Summer School series since 2004. He is a recipient of the Bernstein Prize in motor control.
Affiliations and expertise
Department of Kinesiology, The Pennsylvania State University, University Park, PA, USAMF
Mariusz Furmanek
Mariusz P. Furmanek, PhD, PT, DPT is a new Assistant Professor in the Physical Therapy Department at the University of Rhode Island. He graduated from the Academy of Physical Education in Katowice, Poland, in Physical Therapy, Physical Education, and Kinesiology. Dr. Furmanek completed Postdoctoral Fellowship in the Movement Neuroscience Laboratory, Department of Physical Therapy Movement and Rehabilitation Sciences at Northeastern University in Boston, where he received his DPT. He has clinical experience in outpatient orthopedics and neurorehabilitation. Dr. Furmanek’s research and academic focus are on Motor Control and Neuroscience in rehabilitation, athletic training, and virtual engagement.
Affiliations and expertise
University of Rhode Island, USAML
Mindy F. Levin
Dr. Levin, physiotherapist (McGill University), obtained a M.Sc. in Clinical Sciences (University of Montreal 1985) and a Ph.D. in Physiology (McGill 1990). Dr. Levin was a researcher and professor in the School of Rehabilitation at U Montreal and since 2004, she has been at the School of Physical and Occupational Therapy (SPOT) at McGill University. She was Research Director of the Rehabilitation Institute of Montreal (1997-2001) and Physical Therapy Program Director at SPOT (2004-2008). She was Research Scholar of the Quebec Health Research Fund (1992-2004) and held a Tier 1 Canada Research Chair in Motor Recovery and Rehabilitation (2005-2019). She is currently a Distinguished James McGill Professor and a member of the Canadian Academy of Health Sciences. Dr. Levin is the President of the International Society of Motor Control and is a Past-President of the International Society for Virtual Rehabilitation (2015-2017). She is also a Board member of the International Neurological Physiotherapy Association of the World Physiotherapy Association and editor of the journal "Motor Control". She has over 180 peer-reviewed publications. Her research focuses on elucidating mechanisms underlying sensorimotor deficits and their recovery in patients with CNS lesions. Amongst her research methodologies are new technologies such as virtual reality and robotics.
Affiliations and expertise
Professor, School of Physical and Occupational Therapy Faculty of Medicine and Health Sciences McGill University Montreal, Quebec, CanadaMP
Monica Perez
Monica A. Perez, PT, PhD, is an internationally recognized leader in spinal cord injury (SCI) research. At Shirley Ryan AbilityLab, she leads a translational research team to orchestrate the application of the most modern methods for measuring upper-extremity function.
Affiliations and expertise
Shirley Ryan Ability Lab, USAET
Eugene Tunik
Gene Tunik has a BS in Physical Therapy (Northeastern University) and PhD in Neuroscience (Rutgers University). He is a tenured Professor in the Department of Physical Therapy, Movement, and Rehabilitation Sciences and Associate Dean of Research and Innovation at the Bouvé College of Health Sciences. He directs the Laboratory for Movement Neuroscience, where research focuses on studying cognitive-motor interactions in health and disease, as well as improving human-robot interactions. Approaches in the lab include virtual reality, non-invasive brain stimulation, physiological recording, and measurement of movement.
Affiliations and expertise
Northeastern University, USA