142 related articles for article (PubMed ID: 30065785)
1. Dynamic Balance Gait for Walking Assistance Exoskeleton.
Chen Q; Cheng H; Yue C; Huang R; Guo H
Appl Bionics Biomech; 2018; 2018():7847014. PubMed ID: 30065785
[TBL] [Abstract][Full Text] [Related]
2. Lower Limb Exoskeleton Gait Planning Based on Crutch and Human-Machine Foot Combined Center of Pressure.
Yang W; Zhang J; Zhang S; Yang C
Sensors (Basel); 2020 Dec; 20(24):. PubMed ID: 33339443
[TBL] [Abstract][Full Text] [Related]
3. Novel swing-assist un-motorized exoskeletons for gait training.
Mankala KK; Banala SK; Agrawal SK
J Neuroeng Rehabil; 2009 Jul; 6():24. PubMed ID: 19575808
[TBL] [Abstract][Full Text] [Related]
4. Volition-adaptive control for gait training using wearable exoskeleton: preliminary tests with incomplete spinal cord injury individuals.
Rajasekaran V; López-Larraz E; Trincado-Alonso F; Aranda J; Montesano L; Del-Ama AJ; Pons JL
J Neuroeng Rehabil; 2018 Jan; 15(1):4. PubMed ID: 29298691
[TBL] [Abstract][Full Text] [Related]
5. A Novel Balance Control Strategy Based on Enhanced Stability Pyramid Index and Dynamic Movement Primitives for a Lower Limb Human-Exoskeleton System.
Xu F; Qiu J; Yuan W; Cheng H
Front Neurorobot; 2021; 15():751642. PubMed ID: 34899229
[TBL] [Abstract][Full Text] [Related]
6. An Adaptable Human-Like Gait Pattern Generator Derived From a Lower Limb Exoskeleton.
Mendoza-Crespo R; Torricelli D; Huegel JC; Gordillo JL; Pons JL; Soto R
Front Robot AI; 2019; 6():36. PubMed ID: 33501052
[TBL] [Abstract][Full Text] [Related]
7. Assistive powered exoskeleton for complete spinal cord injury: correlations between walking ability and exoskeleton control.
Guanziroli E; Cazzaniga M; Colombo L; Basilico S; Legnani G; Molteni F
Eur J Phys Rehabil Med; 2019 Apr; 55(2):209-216. PubMed ID: 30156088
[TBL] [Abstract][Full Text] [Related]
8. An Adaptive Neuromuscular Controller for Assistive Lower-Limb Exoskeletons: A Preliminary Study on Subjects with Spinal Cord Injury.
Wu AR; Dzeladini F; Brug TJH; Tamburella F; Tagliamonte NL; van Asseldonk EHF; van der Kooij H; Ijspeert AJ
Front Neurorobot; 2017; 11():30. PubMed ID: 28676752
[TBL] [Abstract][Full Text] [Related]
9. Simulation on the Effect of Gait Variability, Delays, and Inertia with Respect to Wearer Energy Savings with Exoskeleton Assistance.
Fang S; Kinney AL; Reissman ME; Reissman T
IEEE Int Conf Rehabil Robot; 2019 Jun; 2019():506-511. PubMed ID: 31374680
[TBL] [Abstract][Full Text] [Related]
10. Hybrid FES-robot cooperative control of ambulatory gait rehabilitation exoskeleton.
del-Ama AJ; Gil-Agudo A; Pons JL; Moreno JC
J Neuroeng Rehabil; 2014 Mar; 11():27. PubMed ID: 24594302
[TBL] [Abstract][Full Text] [Related]
11. Gait speed using powered robotic exoskeletons after spinal cord injury: a systematic review and correlational study.
Louie DR; Eng JJ; Lam T;
J Neuroeng Rehabil; 2015 Oct; 12():82. PubMed ID: 26463355
[TBL] [Abstract][Full Text] [Related]
12. An assistance approach for a powered knee exoskeleton during level walking and the effects on metabolic cost.
Jang J; Lim B; Shim Y
Annu Int Conf IEEE Eng Med Biol Soc; 2019 Jul; 2019():6216-6219. PubMed ID: 31947263
[TBL] [Abstract][Full Text] [Related]
13. Restoration of gait for spinal cord injury patients using HAL with intention estimator for preferable swing speed.
Tsukahara A; Hasegawa Y; Eguchi K; Sankai Y
IEEE Trans Neural Syst Rehabil Eng; 2015 Mar; 23(2):308-18. PubMed ID: 25350933
[TBL] [Abstract][Full Text] [Related]
14. Gait training with Achilles ankle exoskeleton in chronic incomplete spinal cord injury subjects.
Tamburella F; Tagliamonte NL; Masciullo M; Pisotta I; Arquilla M; van Asseldonk EHF; van der Kooij H; Wu AR; Dzeladini F; Ijspeert AJ; Molinari M
J Biol Regul Homeost Agents; 2020; 34(5 Suppl. 3):147-164. Technology in Medicine. PubMed ID: 33386045
[TBL] [Abstract][Full Text] [Related]
15. Design and control of the MINDWALKER exoskeleton.
Wang S; Wang L; Meijneke C; van Asseldonk E; Hoellinger T; Cheron G; Ivanenko Y; La Scaleia V; Sylos-Labini F; Molinari M; Tamburella F; Pisotta I; Thorsteinsson F; Ilzkovitz M; Gancet J; Nevatia Y; Hauffe R; Zanow F; van der Kooij H
IEEE Trans Neural Syst Rehabil Eng; 2015 Mar; 23(2):277-86. PubMed ID: 25373109
[TBL] [Abstract][Full Text] [Related]
16. Assessment of In-Hospital Walking Velocity and Level of Assistance in a Powered Exoskeleton in Persons with Spinal Cord Injury.
Yang A; Asselin P; Knezevic S; Kornfeld S; Spungen AM
Top Spinal Cord Inj Rehabil; 2015; 21(2):100-9. PubMed ID: 26364279
[TBL] [Abstract][Full Text] [Related]
17. A novel gait-based synthesis procedure for the design of 4-bar exoskeleton with natural trajectories.
Singh R; Chaudhary H; Singh AK
J Orthop Translat; 2018 Jan; 12():6-15. PubMed ID: 29662774
[TBL] [Abstract][Full Text] [Related]
18. Development of VariLeg, an exoskeleton with variable stiffness actuation: first results and user evaluation from the CYBATHLON 2016.
Schrade SO; Dätwyler K; Stücheli M; Studer K; Türk DA; Meboldt M; Gassert R; Lambercy O
J Neuroeng Rehabil; 2018 Mar; 15(1):18. PubMed ID: 29534730
[TBL] [Abstract][Full Text] [Related]
19. Gait Trajectory and Event Prediction from State Estimation for Exoskeletons During Gait.
Tanghe K; De Groote F; Lefeber D; De Schutter J; Aertbelien E
IEEE Trans Neural Syst Rehabil Eng; 2020 Jan; 28(1):211-220. PubMed ID: 31675336
[TBL] [Abstract][Full Text] [Related]
20. Reducing the metabolic cost of walking with an ankle exoskeleton: interaction between actuation timing and power.
Galle S; Malcolm P; Collins SH; De Clercq D
J Neuroeng Rehabil; 2017 Apr; 14(1):35. PubMed ID: 28449684
[TBL] [Abstract][Full Text] [Related]
[Next] [New Search]
