| Título : |
Neurorehabilitation technology |
| Tipo de documento: |
texto impreso |
| Autores: |
Reinkensmeyer, David J, Autor ; Dietz, Volker, Autor |
| Mención de edición: |
2a ed. |
| Editorial: |
New York : Springer |
| Fecha de publicación: |
2016 |
| Número de páginas: |
647 p |
| Il.: |
il. col. |
| Dimensiones: |
Pasta dura |
| ISBN/ISSN/DL: |
978-3-319-28601-3 |
| Idioma : |
Inglés (eng) |
| Palabras clave: |
NEUROREHABILITACIÓN, ENFERMEDADES DEL SISTEMA NERVIOSO, TRASTORNOS MENTALES, INGENIERIA NEURAL, NEUROMODULACIÓN, NEUROREHABILITATION, NEURAL ENGINEERING, NEUROMODULATION |
| Resumen: |
This revised, updated second edition provides an accessible, practical overview of major areas of technical development and clinical application in the field of neurorehabilitation movement therapy. The initial section provides a rationale for technology application in movement therapy by summarizing recent findings in neuroplasticity and motor learning. The following section then explains the state of the art in human-machine interaction requirements for clinical rehabilitation practice |
| Nota de contenido: |
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. // 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 Locomotor Neurorehabilitation. // Clinical Application of Robotics and Technology in the Restoration of Walking. // Standards and Safety Aspects for Medical Devices in the Field of Neurorehabilitation. // Clinical Application of Rehabilitation Technologies in Children Undergoing Neurorehabilitation. // 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 Neurorehabilitation Devices and Technologies Following Brain Injury. // 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 Over-Ground 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 Wireless Sensors for Rehabilitation. // BCI-Based Neuroprostheses and Physiotherapies for Stroke Motor Rehabilitation |
Neurorehabilitation technology [texto impreso] / Reinkensmeyer, David J, Autor ; Dietz, Volker, Autor . - 2a ed. . - New York : Springer, 2016 . - 647 p : il. col. ; Pasta dura. ISBN : 978-3-319-28601-3 Idioma : Inglés ( eng)
| Palabras clave: |
NEUROREHABILITACIÓN, ENFERMEDADES DEL SISTEMA NERVIOSO, TRASTORNOS MENTALES, INGENIERIA NEURAL, NEUROMODULACIÓN, NEUROREHABILITATION, NEURAL ENGINEERING, NEUROMODULATION |
| Resumen: |
This revised, updated second edition provides an accessible, practical overview of major areas of technical development and clinical application in the field of neurorehabilitation movement therapy. The initial section provides a rationale for technology application in movement therapy by summarizing recent findings in neuroplasticity and motor learning. The following section then explains the state of the art in human-machine interaction requirements for clinical rehabilitation practice |
| Nota de contenido: |
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. // 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 Locomotor Neurorehabilitation. // Clinical Application of Robotics and Technology in the Restoration of Walking. // Standards and Safety Aspects for Medical Devices in the Field of Neurorehabilitation. // Clinical Application of Rehabilitation Technologies in Children Undergoing Neurorehabilitation. // 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 Neurorehabilitation Devices and Technologies Following Brain Injury. // 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 Over-Ground 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 Wireless Sensors for Rehabilitation. // BCI-Based Neuroprostheses and Physiotherapies for Stroke Motor Rehabilitation |
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