Informazioni
Non ci sono recensioni
Learning in the Damaged Brain/Spinal Cord: Neuroplasticity
Pages 3-17
Punto di Riferimento
per Medici e Operatori Sanitari
per Medici e Operatori Sanitari
LIBRERIA STUDIUM
Neurorehabilitation Technology
Reinkensmeyer, Dietz
Editore
Springer
Anno
2016
Pagine
647
ISBN
9783319286013
170,00 €
DA SCONTARE
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. Subsequent sections describe the ongoing revolution in robotic therapy for upper extremity movement and for walking, and then describe other emerging technologies including electrical stimulation, virtual reality, wearable sensors, and brain-computer interfaces. The promises and limitations of these technologies in neurorehabilitation are discussed. Throughout the book the chapters provide detailed practical information on state-of-the-art clinical applications of these devices following stroke, spinal cord injury, and other neurologic disorders. The text is illustrated throughout with photographs and schematic diagrams which serve to clarify the information for the reader.
Neurorehabilitation Technology, Second Edition is a valuable resource for neurologists, biomedical engineers, roboticists, rehabilitation specialists, physiotherapists, occupational therapists and those training in these fields.
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Movement Neuroscience Foundations of Neurorehabilitation
Pages 19-38
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Designing Robots That Challenge to Optimize Motor Learning
Pages 39-58
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Multisystem Neurorehabilitation in Rodents with Spinal Cord Injury
Pages 59-77
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Sensory-Motor Interactions and Error Augmentation
Pages 79-95
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Normal and Impaired Cooperative Hand Movements: Role of Neural Coupling
Pages 97-105
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Clinical Assessment and Rehabilitation of the Upper Limb Following Cervical Spinal Cord Injury
Pages 107-138
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Application Issues for Robotics
Pages 141-160
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The Human in the Loop
Pages 161-181
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Robotic and Wearable Sensor Technologies for Measurements/Clinical Assessments
Pages 183-207
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Clinical Aspects for the Application of Robotics in Locomotor Neurorehabilitation
Pages 209-222
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Clinical Application of Robotics and Technology in the Restoration of Walking
Pages 223-248
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Standards and Safety Aspects for Medical Devices in the Field of Neurorehabilitation
Pages 249-281
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Clinical Application of Rehabilitation Technologies in Children Undergoing Neurorehabilitation
Pages 283-308
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Restoration of Hand Function in Stroke and Spinal Cord Injury
Pages 311-331
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Forging Mens et Manus: The MIT Experience in Upper Extremity Robotic Therapy
Pages 333-350
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Three-Dimensional Multi-degree-of-Freedom Arm Therapy Robot (ARMin)
Pages 351-374
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Implementation of Impairment-Based Neurorehabilitation Devices and Technologies Following Brain Injury
Pages 375-392
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Technology of the Robotic Gait Orthosis Lokomat
Pages 395-407
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Beyond Human or Robot Administered Treadmill Training
Pages 409-433
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Toward Flexible Assistance for Locomotor Training: Design and Clinical Testing of a Cable-Driven Robot for Stroke, Spinal Cord Injury, and Cerebral Palsy
Pages 435-459
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Robot-Aided Gait Training with LOPES
Pages 461-481
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Robotic Devices for Overground Gait and Balance Training
Pages 483-492
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Using Robotic Exoskeletons for Over-Ground Locomotor Training
Pages 493-511
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Functional Electrical Stimulation Therapy: Recovery of Function Following Spinal Cord Injury and Stroke
Pages 513-532
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Passive Devices for Upper Limb Training
Pages 533-551
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Upper-Extremity Therapy with Spring Orthoses
Pages 553-571
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Virtual Reality for Sensorimotor Rehabilitation Post Stroke: Design Principles and Evidence
Pages 573-603
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Wearable Wireless Sensors for Rehabilitation
Pages 605-615
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BCI-Based Neuroprostheses and Physiotherapies for Stroke Motor Rehabilitation
Pages 617-627
