| scholarly article | Q13442814 |
| P50 | author | Joel Stein | Q59158496 |
| P2093 | author name string | Richard Hughes | |
| Neville Hogan | |||
| Hermano Igo Krebs | |||
| Susan E Fasoli | |||
| Stephen Mernoff | |||
| P2860 | cites work | The post-stroke hemiplegic patient. 1. a method for evaluation of physical performance | Q28189300 |
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| Robot-Aided Neurorehabilitation: From Evidence-Based to Science-Based Rehabilitation | Q35549263 | ||
| Systematic review of the effect of robot-aided therapy on recovery of the hemiparetic arm after stroke | Q36539193 | ||
| Effects of robot-assisted therapy on upper limb recovery after stroke: a systematic review | Q36944512 | ||
| Robot-aided neurorehabilitation. | Q37217226 | ||
| Submovements grow larger, fewer, and more blended during stroke recovery. | Q40462482 | ||
| Impairment-oriented training and adaptive motor cortex reorganisation after stroke: a fTMS study | Q46555597 | ||
| Changing motor synergies in chronic stroke. | Q50985681 | ||
| Continuous passive motion improves shoulder joint integrity following stroke. | Q51350558 | ||
| Robotic therapy for chronic motor impairments after stroke: Follow-up results. | Q51650542 | ||
| Comparison of two techniques of robot-aided upper limb exercise training after stroke. | Q51991678 | ||
| Robot-aided sensorimotor arm training improves outcome in patients with chronic stroke. | Q52006810 | ||
| Movement smoothness changes during stroke recovery. | Q52032926 | ||
| A novel approach to stroke rehabilitation: robot-aided sensorimotor stimulation. | Q52078485 | ||
| The effect of robot-assisted therapy and rehabilitative training on motor recovery following stroke. | Q52269587 | ||
| P433 | issue | 1 | |
| P304 | page(s) | 81-87 | |
| P577 | publication date | 2008-01-01 | |
| P1433 | published in | NeuroRehabilitation | Q15753348 |
| P1476 | title | A comparison of functional and impairment-based robotic training in severe to moderate chronic stroke: a pilot study | |
| P478 | volume | 23 |
| Q37425924 | A crossover pilot study evaluating the functional outcomes of two different types of robotic movement training in chronic stroke survivors using the arm exoskeleton BONES. |
| Q36590728 | Ankle Training With a Robotic Device Improves Hemiparetic Gait After a Stroke |
| Q96954247 | Changes in arm kinematics of chronic stroke individuals following "Assist-As-Asked" robot-assisted training in virtual and physical environments: A proof-of-concept study |
| Q43375014 | Combining Upper Limb Robotic Rehabilitation with Other Therapeutic Approaches after Stroke: Current Status, Rationale, and Challenges. |
| Q34143928 | Comparing integrated training of the hand and arm with isolated training of the same effectors in persons with stroke using haptically rendered virtual environments, a randomized clinical trial |
| Q89532124 | Comparisons between end-effector and exoskeleton rehabilitation robots regarding upper extremity function among chronic stroke patients with moderate-to-severe upper limb impairment |
| Q36058002 | Does training with traditionally presented and virtually simulated tasks elicit differing changes in object interaction kinematics in persons with upper extremity hemiparesis? |
| Q21231960 | Effects of intensive arm training with the rehabilitation robot ARMin II in chronic stroke patients: four single-cases |
| Q35203700 | Feasibility of the adaptive and automatic presentation of tasks (ADAPT) system for rehabilitation of upper extremity function post-stroke |
| Q35981391 | Grip type and task goal modify reach-to-grasp performance in post-stroke hemiparesis |
| Q39753709 | Incorporating haptic effects into three-dimensional virtual environments to train the hemiparetic upper extremity |
| Q92487044 | Increasing perceived hand size improves motor performance in individuals with stroke: a home-based training study |
| Q34519287 | Integrated versus isolated training of the hemiparetic upper extremity in haptically rendered virtual environments |
| Q34514753 | Interfacing a haptic robotic system with complex virtual environments to treat impaired upper extremity motor function in children with cerebral palsy |
| Q42369669 | Is two better than one? Muscle vibration plus robotic rehabilitation to improve upper limb spasticity and function: A pilot randomized controlled trial. |
| Q35075979 | Learning in a virtual environment using haptic systems for movement re-education: can this medium be used for remodeling other behaviors and actions? |
| Q36395313 | Learning, not adaptation, characterizes stroke motor recovery: evidence from kinematic changes induced by robot-assisted therapy in trained and untrained task in the same workspace |
| Q30826353 | Long-term Rehabilitation in Patients With Acquired Brain Injury |
| Q34098368 | Management of vaccine inventories as a critical health resource |
| Q47122486 | Movement rehabilitation in virtual reality from then to now: how are we doing? |
| Q33390906 | Novel multi-modal strategies to promote brain and spinal cord injury recovery |
| Q35862771 | Pilot study to test effectiveness of video game on reaching performance in stroke |
| Q27314590 | Rehabilitation of Motor Function after Stroke: A Multiple Systematic Review Focused on Techniques to Stimulate Upper Extremity Recovery |
| Q35241241 | Results of clinicians using a therapeutic robotic system in an inpatient stroke rehabilitation unit |
| Q21231961 | Review of control strategies for robotic movement training after neurologic injury |
| Q35844960 | Risk factors related to falling in stroke patients: a cross-sectional study |
| Q64093594 | Robot-Assisted Therapy in Upper Extremity Hemiparesis: Overview of an Evidence-Based Approach |
| Q38621991 | Robotic Therapy and the Paradox of the Diminishing Number of Degrees of Freedom |
| Q21231959 | Robotic neurorehabilitation: a computational motor learning perspective |
| Q36486470 | Robotics to enable older adults to remain living at home |
| Q30557393 | Single degree-of-freedom exoskeleton mechanism design for finger rehabilitation |
| Q38261674 | Single degree-of-freedom exoskeleton mechanism design for thumb rehabilitation |
| Q30358455 | Spasticity, Motor Recovery, and Neural Plasticity after Stroke. |
| Q37162707 | Teaching Adult Rats Spinalized as Neonates to Walk Using Trunk Robotic Rehabilitation: Elements of Success, Failure, and Dependence |
| Q37432610 | The New Jersey Institute of Technology Robot-Assisted Virtual Rehabilitation (NJIT-RAVR) system for children with cerebral palsy: a feasibility study |
| Q47139272 | The Reticulospinal Pathway Does Not Increase Its Contribution to the Strength of Contralesional Muscles in Stroke Survivors as Compared to Ipsilesional Side or Healthy Controls |
| Q33951911 | The binding of learning to action in motor adaptation |
| Q89421340 | The effects of error-augmentation versus error-reduction paradigms in robotic therapy to enhance upper extremity performance and recovery post-stroke: a systematic review |
| Q33942177 | Training modalities in robot-mediated upper limb rehabilitation in stroke: a framework for classification based on a systematic review. |
| Q24188155 | Virtual reality for stroke rehabilitation |
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