Introduction: Overview of the book
Part I: Basic framework: Movement recovery and neuroplasticity
Learning in the damaged brain/spinal cord: Neuroplasticity
Movement neuroscience foundations of neurorehabilitation
Recovery of sensorimotor functions after stroke and SCI: Neurophysiological basis of rehabilitation technology
Part II: From movement physiology to technology application
The upper limb after SCI: Use of technology in the assessment and rehabilitation
Implementation of impairment based neuro-rehabilitation devices and technologies following brain injury
The hand after stroke and SCI: Restoration of function with technology
Neural coupling in movement coordination: Implications for rehabilitation technology
Robotic gait training in specific neurological conditions: Rationale and application
Part III: Principles for interactive rehabilitation technology
Designing technology solutions for rehabilitation challenge that optimize motor performance
Psychophysiological integration of humans and machines for rehabilitation
Sensory-motor interactions and the manipulation of movement error
Role of haptic interactions with machines for promoting motor learning
Implementation of robots into rehabilitation programs: Meeting the requirements and expectations of professional and end users
Application of rehabilitation technologies in children undergoing neurorehabilitation
Part IV: Assessment technology and predictive modeling
Robotic technologies and digital health metrics for assessing sensorimotor disability
Computational neurorehabilitation
Precision rehabilitation: Can neurorehabilitation technology help make it a realistic target?- Part V: General technological approaches in neurorehabilitation
Spinal cord stimulation to enable leg motor control And walking in people with spinal cord injury
Functional electrical stimulation therapy: Recovery of function following spinal cord injury and stroke
Basis and clinical evidence of virtual reality-based rehabilitation of sensorimotor impairments after stroke
Wearable sensors for stroke rehabilitation
BCI-based neuroprostheses and physiotherapies for stroke motor rehabilitation
Passive devices for upper limb training
Mobile technologies for cognitive rehabilitation
Telerehabilitation technology
Part VI: Robotic technologies for neurorehabilitation: Upper extremity
Forging Mens et Manus: The MIT experience in upper extremity robotic therapy
Three-dimensional multi-degree-of-freedom arm therapy robot (armin)
Upper extremity movement training with mechanically assistive devices
Part VII: Robotic technologies for neurorehabilitation: Gait and balance
Technology of the robotic gait orthosis lokomat
Using robotic exoskeletons for over-ground locomotor training
Beyond human or robot administered treadmill training
Toward flexible assistance for locomotor training: Design and clinical testing of a cable-driven robot for stroke, spinal cord injury, and cerebral palsy
Body weight support devices for overground gait and balance training
Epilogue: The ongoing debate over robots in neurorehabilitation.