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Pubmed for Handhelds

PUBMED FOR HANDHELDS

Journal Abstract Search

292 related items for PubMed ID: 25246110

  • 1. Within-socket myoelectric prediction of continuous ankle kinematics for control of a powered transtibial prosthesis.
    Farmer S, Silver-Thorn S, Voglewede P, Beardsley SA.
    J Neural Eng; 2014 Oct; 11(5):056027. PubMed ID: 25246110
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  • 2. Continuous Myoelectric Prediction of Future Ankle Angle and Moment Across Ambulation Conditions and Their Transitions.
    Zabre-Gonzalez EV, Riem L, Voglewede PA, Silver-Thorn B, Koehler-McNicholas SR, Beardsley SA.
    Front Neurosci; 2021 Oct; 15():709422. PubMed ID: 34483828
    [Abstract] [Full Text] [Related]

  • 3. Locomotor Adaptation by Transtibial Amputees Walking With an Experimental Powered Prosthesis Under Continuous Myoelectric Control.
    Huang S, Wensman JP, Ferris DP.
    IEEE Trans Neural Syst Rehabil Eng; 2016 May; 24(5):573-81. PubMed ID: 26057851
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  • 4. Preliminary investigation of residual limb plantarflexion and dorsiflexion muscle activity during treadmill walking for trans-tibial amputees.
    Silver-Thorn B, Current T, Kuhse B.
    Prosthet Orthot Int; 2012 Dec; 36(4):435-42. PubMed ID: 22581661
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  • 6. Powered ankle-foot prosthesis to assist level-ground and stair-descent gaits.
    Au S, Berniker M, Herr H.
    Neural Netw; 2008 May; 21(4):654-66. PubMed ID: 18499394
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  • 8. Functional Assessment of a Myoelectric Postural Controller and Multi-Functional Prosthetic Hand by Persons With Trans-Radial Limb Loss.
    Segil JL, Huddle SA, Weir RFF.
    IEEE Trans Neural Syst Rehabil Eng; 2017 Jun; 25(6):618-627. PubMed ID: 27390181
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  • 10. High density electromyography data of normally limbed and transradial amputee subjects for multifunction prosthetic control.
    Daley H, Englehart K, Hargrove L, Kuruganti U.
    J Electromyogr Kinesiol; 2012 Jun; 22(3):478-84. PubMed ID: 22269773
    [Abstract] [Full Text] [Related]

  • 11. Voluntary Control of Residual Antagonistic Muscles in Transtibial Amputees: Reciprocal Activation, Coactivation, and Implications for Direct Neural Control of Powered Lower Limb Prostheses.
    Huang S, Huang H.
    IEEE Trans Neural Syst Rehabil Eng; 2019 Jan; 27(1):85-95. PubMed ID: 30530332
    [Abstract] [Full Text] [Related]

  • 12. Movement Performance of Human-Robot Cooperation Control Based on EMG-Driven Hill-Type and Proportional Models for an Ankle Power-Assist Exoskeleton Robot.
    Ao D, Song R, Gao J.
    IEEE Trans Neural Syst Rehabil Eng; 2017 Aug; 25(8):1125-1134. PubMed ID: 27337719
    [Abstract] [Full Text] [Related]

  • 13. Myoelectric neural interface enables accurate control of a virtual multiple degree-of-freedom foot-ankle prosthesis.
    Tkach DC, Lipschutz RD, Finucane SB, Hargrove LJ.
    IEEE Int Conf Rehabil Robot; 2013 Jun; 2013():6650499. PubMed ID: 24187314
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  • 14. A noncontact capacitive sensing system for recognizing locomotion modes of transtibial amputees.
    Zheng E, Wang L, Wei K, Wang Q.
    IEEE Trans Biomed Eng; 2014 Dec; 61(12):2911-20. PubMed ID: 25014949
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  • 16. Real-time and offline performance of pattern recognition myoelectric control using a generic electrode grid with targeted muscle reinnervation patients.
    Tkach DC, Young AJ, Smith LH, Rouse EJ, Hargrove LJ.
    IEEE Trans Neural Syst Rehabil Eng; 2014 Jul; 22(4):727-34. PubMed ID: 24760931
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  • 18. Variable Cadence Walking and Ground Adaptive Standing With a Powered Ankle Prosthesis.
    Shultz AH, Lawson BE, Goldfarb M.
    IEEE Trans Neural Syst Rehabil Eng; 2016 Apr; 24(4):495-505. PubMed ID: 25955789
    [Abstract] [Full Text] [Related]

  • 19. Control of a powered ankle-foot prosthesis based on a neuromuscular model.
    Eilenberg MF, Geyer H, Herr H.
    IEEE Trans Neural Syst Rehabil Eng; 2010 Apr; 18(2):164-73. PubMed ID: 20071268
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