Neurorehabilitation Technology
-15%
portes grátis
Neurorehabilitation Technology
Dietz, Volker; Reinkensmeyer, David J.
Springer International Publishing AG
06/2018
647
Mole
Inglês
9783319803869
15 a 20 dias
Descrição não disponível.
Introduction: Rationale for Machine Use.- Part I Basic Framework: Motor Recovery, Learning, and Neural Impairment.- Learning in the Damaged Brain/Spinal Cord: Neuroplasticity.- Movement Neuroscience Foundations of Neurorehabilitation.- Designing Robots That Challenge to Optimize Motor Learning.- Multisystem Neurorehabilitation in Rodents with Spinal Cord Injury.- Sensory-Motor Interactions and Error Augmentation.- Normal and Impaired Cooperative Hand Movements: Role of Neural Coupling.- Clinical Assessment and Rehabilitation of the Upper Limb Following Cervical Spinal Cord Injury.- Part II Human-Machine Interaction in Rehabilitation Practice.- Application Issues for Robotics.- The Human in the Loop.- Robotic and wearable sensor technologies for measurements/clinical assessments.- Clinical Aspects for the Application of Robotics in Neurorehabilitation.- Clinical Application of Robotics and Technology in Restoration of Walking.- Standards and Safety Aspects for Medical Devices in the Field of Neurorehabilitation.- Clinical Application of Rehabilitation Technologies in Children and Youths Undergoing Neurorehabilitation.- Part III Robots for Upper Extremity Recovery.- Restoration of Hand Function in Stroke and Spinal Cord Injury.- Forging Mens et Manus: the MIT Experience in Upper Extremity Robotic Therapy.- Three-Dimensional Multi-Degree-of-Freedom Arm Therapy Robot (ARMin).- Implementation of Impairment Based Neuro-Rehabilitation Devices and Technologies following Brain Injury.- Part IV Robotics for Locomotion Recovery.- Technology of the Robotic Gait Orthosis Lokomat.- 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.- Robot-Aided Gait Training with LOPES.- Robotic Devices for Overground Gait and Balance Training.- Using Robotic Exoskeletons for Overground Locomotor Training.- Functional Electrical Stimulation Therapy: Recovery of Function Following Spinal Cord Injury and Stroke.- Passive Devices for Upper Limb Training.- Upper-Extremity Therapy with Spring Orthoses.- Virtual Reality for Sensorimotor Rehabilitation Post-Stroke: Design Principles and Evidence.- Wearable Sensors for Rehabilitation.- BCI-based Neuroprostheses and Physiotherapies for Stroke Motor Rehabilitation.- Epilogue: What Lies Ahead?
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Neurorehabilitation technology;Posture;Robotics;Spinal Cord;locomotion;Neurorehabilitation;wearable sensor;functional electrical stimulation;virtual reality;rehabilitation psychology
Introduction: Rationale for Machine Use.- Part I Basic Framework: Motor Recovery, Learning, and Neural Impairment.- Learning in the Damaged Brain/Spinal Cord: Neuroplasticity.- Movement Neuroscience Foundations of Neurorehabilitation.- Designing Robots That Challenge to Optimize Motor Learning.- Multisystem Neurorehabilitation in Rodents with Spinal Cord Injury.- Sensory-Motor Interactions and Error Augmentation.- Normal and Impaired Cooperative Hand Movements: Role of Neural Coupling.- Clinical Assessment and Rehabilitation of the Upper Limb Following Cervical Spinal Cord Injury.- Part II Human-Machine Interaction in Rehabilitation Practice.- Application Issues for Robotics.- The Human in the Loop.- Robotic and wearable sensor technologies for measurements/clinical assessments.- Clinical Aspects for the Application of Robotics in Neurorehabilitation.- Clinical Application of Robotics and Technology in Restoration of Walking.- Standards and Safety Aspects for Medical Devices in the Field of Neurorehabilitation.- Clinical Application of Rehabilitation Technologies in Children and Youths Undergoing Neurorehabilitation.- Part III Robots for Upper Extremity Recovery.- Restoration of Hand Function in Stroke and Spinal Cord Injury.- Forging Mens et Manus: the MIT Experience in Upper Extremity Robotic Therapy.- Three-Dimensional Multi-Degree-of-Freedom Arm Therapy Robot (ARMin).- Implementation of Impairment Based Neuro-Rehabilitation Devices and Technologies following Brain Injury.- Part IV Robotics for Locomotion Recovery.- Technology of the Robotic Gait Orthosis Lokomat.- 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.- Robot-Aided Gait Training with LOPES.- Robotic Devices for Overground Gait and Balance Training.- Using Robotic Exoskeletons for Overground Locomotor Training.- Functional Electrical Stimulation Therapy: Recovery of Function Following Spinal Cord Injury and Stroke.- Passive Devices for Upper Limb Training.- Upper-Extremity Therapy with Spring Orthoses.- Virtual Reality for Sensorimotor Rehabilitation Post-Stroke: Design Principles and Evidence.- Wearable Sensors for Rehabilitation.- BCI-based Neuroprostheses and Physiotherapies for Stroke Motor Rehabilitation.- Epilogue: What Lies Ahead?
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