108 results on '"Dietz, Volker'
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2. Recovery of Sensorimotor Functions After Stroke and SCI: Neurophysiological Basis of Rehabilitation Technology
Catalog
Books, media, physical & digital resources
3. Learning in the Damaged Brain/Spinal Cord: Neuroplasticity
4. Spasticity Versus Spastic Movement Disorder
5. Clinical Aspects for the Application of Robotics in Locomotor Neurorehabilitation
6. Learning in the Damaged Brain/Spinal Cord: Neuroplasticity
7. Normal and Impaired Cooperative Hand Movements: Role of Neural Coupling
8. Rehabilitation Technologies for Spinal Injury
9. Rehabilitation-Dependent Neural Plasticity After Spinal Cord Injury
10. Clinical Aspects for the Application of Robotics in Neurorehabilitation
11. Learning in the Damaged Brain/Spinal Cord: Neuroplasticity
12. Grundlagen
13. Anwendung von Robotern in der Neurorehabilitation
14. Performance of Functional Arm and Leg Movements Depends on Neural Coupling
15. Do We Need Allowing Arm Movements for Rehabilitation of Gait?
16. Spinal Networks Involved in Interlimb Co-ordination and Reflex Regulation of Locomotion
17. Technologie-Entwicklung im Bereich Home Banking
18. Contribution of spinal stretch reflexes to the activity of leg muscles in running
19. Short and Long Latency Proprioceptive Reflexes during the Standing and Stepping of Normal and Hemiparetic Human Subjects
20. General Summary
21. Epilogue: Robots for Neurorehabilitation—The Debate
22. Beyond Human or Robot Administered Treadmill Training
23. Upper-Extremity Movement Training with Mechanically Assistive Devices
24. Wearable Sensors for Stroke Rehabilitation
25. Using Robotic Exoskeletons for Overground Locomotor Training
26. A Flexible Cable-Driven Robotic System: Design and Its Clinical Application for Improving Walking Function in Adults with Stroke, SCI, and Children with CP
27. Designing User-Centered Technologies for Rehabilitation Challenge that Optimize Walking and Balance Performance
28. Body Weight Support Devices for Overground Gait and Balance Training
29. Robotic Gait Training in Specific Neurological Conditions: Rationale and Application
30. The Role of Haptic Interactions with Robots for Promoting Motor Learning
31. Forging Mens et Manus: The MIT Experience in Upper Extremity Robotic Therapy
32. Technology of the Robotic Gait Orthosis Lokomat
33. Three-Dimensional Multi-Degree-of-Freedom Arm Therapy Robot (ARMin)
34. Telerehabilitation Technology
35. Passive Devices for Upper Limb Training
36. BCI-Based Neuroprostheses and Physiotherapies for Stroke Motor Rehabilitation
37. Mobile Technology for Cognitive Rehabilitation
38. Basis and Clinical Evidence of Virtual Reality-Based Rehabilitation of Sensorimotor Impairments After Stroke
39. Computational Neurorehabilitation
40. Functional Electrical Stimulation Therapy: Mechanisms for Recovery of Function Following Spinal Cord Injury and Stroke
41. Spinal Cord Stimulation to Enable Leg Motor Control and Walking in People with Spinal Cord Injury
42. Precision Rehabilitation: Can Neurorehabilitation Technology Help Make It a Realistic Target?
43. Robotic Technologies and Digital Health Metrics for Assessing Sensorimotor Disability
44. Sensory-Motor Interactions and the Manipulation of Movement Error
45. Clinical Application of Rehabilitation Therapy Technologies to Children with CNS Damage
46. Implementation of Robots into Rehabilitation Programs: Meeting the Requirements and Expectations of Professional and End Users
47. Psychophysiological Integration of Humans and Machines for Rehabilitation
48. The Hand After Stroke and SCI: Restoration of Function with Technology
49. Implementation of Impairment-Based Neurorehabilitation Devices and Technologies Following Brain Injury
50. Use of Technology in the Assessment and Rehabilitation of the Upper Limb After Cervical Spinal Cord Injury
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