291 related articles for article (PubMed ID: 23336754)
21. Biomechanical mechanisms underlying exosuit-induced improvements in walking economy after stroke.
Bae J; Awad LN; Long A; O'Donnell K; Hendron K; Holt KG; Ellis TD; Walsh CJ
J Exp Biol; 2018 Mar; 221(Pt 5):. PubMed ID: 29361587
[TBL] [Abstract][Full Text] [Related]
22. Use of Pelvic Corrective Force With Visual Feedback Improves Paretic Leg Muscle Activities and Gait Performance After Stroke.
Hsu CJ; Kim J; Roth EJ; Rymer WZ; Wu M
IEEE Trans Neural Syst Rehabil Eng; 2019 Dec; 27(12):2353-2360. PubMed ID: 31675335
[TBL] [Abstract][Full Text] [Related]
23. Real-time closed-loop control of cognitive load in neurological patients during robot-assisted gait training.
Koenig A; Novak D; Omlin X; Pulfer M; Perreault E; Zimmerli L; Mihelj M; Riener R
IEEE Trans Neural Syst Rehabil Eng; 2011 Aug; 19(4):453-64. PubMed ID: 21827971
[TBL] [Abstract][Full Text] [Related]
24. Powered robotic exoskeletons in post-stroke rehabilitation of gait: a scoping review.
Louie DR; Eng JJ
J Neuroeng Rehabil; 2016 Jun; 13(1):53. PubMed ID: 27278136
[TBL] [Abstract][Full Text] [Related]
25. A wearable resistive robot facilitates locomotor adaptations during gait.
Washabaugh EP; Krishnan C
Restor Neurol Neurosci; 2018; 36(2):215-223. PubMed ID: 29526856
[TBL] [Abstract][Full Text] [Related]
26. Speed-dependent reference joint trajectory generation for robotic gait support.
Koopman B; van Asseldonk EH; van der Kooij H
J Biomech; 2014 Apr; 47(6):1447-58. PubMed ID: 24529911
[TBL] [Abstract][Full Text] [Related]
27. A neuromechanics-based powered ankle exoskeleton to assist walking post-stroke: a feasibility study.
Takahashi KZ; Lewek MD; Sawicki GS
J Neuroeng Rehabil; 2015 Feb; 12():23. PubMed ID: 25889283
[TBL] [Abstract][Full Text] [Related]
28. Learning to walk with an adaptive gain proportional myoelectric controller for a robotic ankle exoskeleton.
Koller JR; Jacobs DA; Ferris DP; Remy CD
J Neuroeng Rehabil; 2015 Nov; 12():97. PubMed ID: 26536868
[TBL] [Abstract][Full Text] [Related]
29. Biofeedback for robotic gait rehabilitation.
Lünenburger L; Colombo G; Riener R
J Neuroeng Rehabil; 2007 Jan; 4():1. PubMed ID: 17244363
[TBL] [Abstract][Full Text] [Related]
30. Influence of the amount of body weight support on lower limb joints' kinematics during treadmill walking at different gait speeds: Reference data on healthy adults to define trajectories for robot assistance.
Ferrarin M; Rabuffetti M; Geda E; Sirolli S; Marzegan A; Bruno V; Sacco K
Proc Inst Mech Eng H; 2018 Jun; 232(6):619-627. PubMed ID: 29890931
[TBL] [Abstract][Full Text] [Related]
31. Gait training with a robotic leg brace after stroke: a randomized controlled pilot study.
Stein J; Bishop L; Stein DJ; Wong CK
Am J Phys Med Rehabil; 2014 Nov; 93(11):987-94. PubMed ID: 24901757
[TBL] [Abstract][Full Text] [Related]
32. The Kickstart Walk Assist System for improving balance and walking function in stroke survivors: a feasibility study.
Yao J; Sado T; Wang W; Gao J; Zhao Y; Qi Q; Mukherjee M
J Neuroeng Rehabil; 2021 Feb; 18(1):42. PubMed ID: 33627142
[TBL] [Abstract][Full Text] [Related]
33. Effect of assist-as-needed robotic gait training on the gait pattern post stroke: a randomized controlled trial.
Alingh JF; Fleerkotte BM; Groen BE; Rietman JS; Weerdesteyn V; van Asseldonk EHF; Geurts ACH; Buurke JH
J Neuroeng Rehabil; 2021 Feb; 18(1):26. PubMed ID: 33546733
[TBL] [Abstract][Full Text] [Related]
34. Training for Walking Efficiency With a Wearable Hip-Assist Robot in Patients With Stroke: A Pilot Randomized Controlled Trial.
Lee HJ; Lee SH; Seo K; Lee M; Chang WH; Choi BO; Ryu GH; Kim YH
Stroke; 2019 Dec; 50(12):3545-3552. PubMed ID: 31623545
[TBL] [Abstract][Full Text] [Related]
35. Interactive cueing with Walk-Mate for hemiparetic stroke rehabilitation.
Muto T; Herzberger B; Hermsdoerfer J; Miyake Y; Poeppel E
J Neuroeng Rehabil; 2012 Aug; 9():58. PubMed ID: 22909032
[TBL] [Abstract][Full Text] [Related]
36. Reducing robotic guidance during robot-assisted gait training improves gait function: a case report on a stroke survivor.
Krishnan C; Kotsapouikis D; Dhaher YY; Rymer WZ
Arch Phys Med Rehabil; 2013 Jun; 94(6):1202-6. PubMed ID: 23168401
[TBL] [Abstract][Full Text] [Related]
37. Lateral balance control for robotic gait training.
Koopman B; Meuleman JH; van Asseldonk EH; van der Kooij H
IEEE Int Conf Rehabil Robot; 2013 Jun; 2013():6650363. PubMed ID: 24187182
[TBL] [Abstract][Full Text] [Related]
38. Neural Decoding of Robot-Assisted Gait During Rehabilitation After Stroke.
Contreras-Vidal JL; Bortole M; Zhu F; Nathan K; Venkatakrishnan A; Francisco GE; Soto R; Pons JL
Am J Phys Med Rehabil; 2018 Aug; 97(8):541-550. PubMed ID: 29481376
[TBL] [Abstract][Full Text] [Related]
39. Effect of robotic performance-based error-augmentation versus error-reduction training on the gait of healthy individuals.
Kao PC; Srivastava S; Agrawal SK; Scholz JP
Gait Posture; 2013 Jan; 37(1):113-20. PubMed ID: 22832470
[TBL] [Abstract][Full Text] [Related]
40. Gait rehabilitation machines based on programmable footplates.
Schmidt H; Werner C; Bernhardt R; Hesse S; Krüger J
J Neuroeng Rehabil; 2007 Feb; 4():2. PubMed ID: 17291335
[TBL] [Abstract][Full Text] [Related]
[Previous] [Next] [New Search]
