These tools will no longer be maintained as of December 31, 2024. Archived website can be found here. PubMed4Hh GitHub repository can be found here. Contact NLM Customer Service if you have questions.


BIOMARKERS

Molecular Biopsy of Human Tumors

- a resource for Precision Medicine *

219 related articles for article (PubMed ID: 25889201)

  • 21. Bionic ankle-foot prosthesis normalizes walking gait for persons with leg amputation.
    Herr HM; Grabowski AM
    Proc Biol Sci; 2012 Feb; 279(1728):457-64. PubMed ID: 21752817
    [TBL] [Abstract][Full Text] [Related]  

  • 22. Variable-stiffness prosthesis improves biomechanics of walking across speeds compared to a passive device.
    Rogers-Bradley E; Yeon SH; Landis C; Lee DRC; Herr HM
    Sci Rep; 2024 Jul; 14(1):16521. PubMed ID: 39019986
    [TBL] [Abstract][Full Text] [Related]  

  • 23. Quantification of push-off and collision work during step-to-step transition in amputees walking at self-selected speed: Effect of amputation level.
    Sedran L; Bonnet X; Thomas-Pohl M; Loiret I; Martinet N; Pillet H; Paysant J
    J Biomech; 2024 Jan; 163():111943. PubMed ID: 38244403
    [TBL] [Abstract][Full Text] [Related]  

  • 24. Effects of toe length, foot arch length and toe joint axis on walking biomechanics.
    Honert EC; Bastas G; Zelik KE
    Hum Mov Sci; 2020 Apr; 70():102594. PubMed ID: 32217212
    [TBL] [Abstract][Full Text] [Related]  

  • 25. Coordination of push-off and collision determine the mechanical work of step-to-step transitions when isolated from human walking.
    Soo CH; Donelan JM
    Gait Posture; 2012 Feb; 35(2):292-7. PubMed ID: 22030156
    [TBL] [Abstract][Full Text] [Related]  

  • 26. Co-contraction patterns of trans-tibial amputee ankle and knee musculature during gait.
    Seyedali M; Czerniecki JM; Morgenroth DC; Hahn ME
    J Neuroeng Rehabil; 2012 May; 9():29. PubMed ID: 22640660
    [TBL] [Abstract][Full Text] [Related]  

  • 27. The influence of energy storage and return foot stiffness on walking mechanics and muscle activity in below-knee amputees.
    Fey NP; Klute GK; Neptune RR
    Clin Biomech (Bristol, Avon); 2011 Dec; 26(10):1025-32. PubMed ID: 21777999
    [TBL] [Abstract][Full Text] [Related]  

  • 28. Evaluation of a Powered Ankle-Foot Prosthesis during Slope Ascent Gait.
    Rábago CA; Aldridge Whitehead J; Wilken JM
    PLoS One; 2016; 11(12):e0166815. PubMed ID: 27977681
    [TBL] [Abstract][Full Text] [Related]  

  • 29. Impact of elastic ankle exoskeleton stiffness on neuromechanics and energetics of human walking across multiple speeds.
    Nuckols RW; Sawicki GS
    J Neuroeng Rehabil; 2020 Jun; 17(1):75. PubMed ID: 32539840
    [TBL] [Abstract][Full Text] [Related]  

  • 30. Energy-Optimal Human Walking With Feedback-Controlled Robotic Prostheses: A Computational Study.
    Handford ML; Srinivasan M
    IEEE Trans Neural Syst Rehabil Eng; 2018 Sep; 26(9):1773-1782. PubMed ID: 30040647
    [TBL] [Abstract][Full Text] [Related]  

  • 31. Human-prosthesis coordination: A preliminary study exploring coordination with a powered ankle-foot prosthesis.
    Fylstra BL; Lee IC; Huang S; Brandt A; Lewek MD; Huang HH
    Clin Biomech (Bristol, Avon); 2020 Dec; 80():105171. PubMed ID: 32932017
    [TBL] [Abstract][Full Text] [Related]  

  • 32. Prosthetic energy return during walking increases after 3 weeks of adaptation to a new device.
    Ray SF; Wurdeman SR; Takahashi KZ
    J Neuroeng Rehabil; 2018 Jan; 15(1):6. PubMed ID: 29374491
    [TBL] [Abstract][Full Text] [Related]  

  • 33. Adding a toe joint to a prosthesis: walking biomechanics, energetics, and preference of individuals with unilateral below-knee limb loss.
    McDonald KA; Teater RH; Cruz JP; Kerr JT; Bastas G; Zelik KE
    Sci Rep; 2021 Jan; 11(1):1924. PubMed ID: 33479374
    [TBL] [Abstract][Full Text] [Related]  

  • 34. Use of a powered ankle-foot prosthesis reduces the metabolic cost of uphill walking and improves leg work symmetry in people with transtibial amputations.
    Montgomery JR; Grabowski AM
    J R Soc Interface; 2018 Aug; 15(145):. PubMed ID: 30158189
    [TBL] [Abstract][Full Text] [Related]  

  • 35. 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]  

  • 36. Sensitivity of biomechanical outcomes to independent variations of hindfoot and forefoot stiffness in foot prostheses.
    Adamczyk PG; Roland M; Hahn ME
    Hum Mov Sci; 2017 Aug; 54():154-171. PubMed ID: 28499159
    [TBL] [Abstract][Full Text] [Related]  

  • 37. A simple exoskeleton that assists plantarflexion can reduce the metabolic cost of human walking.
    Malcolm P; Derave W; Galle S; De Clercq D
    PLoS One; 2013; 8(2):e56137. PubMed ID: 23418524
    [TBL] [Abstract][Full Text] [Related]  

  • 38. Energy storing and return prosthetic feet improve step length symmetry while preserving margins of stability in persons with transtibial amputation.
    Houdijk H; Wezenberg D; Hak L; Cutti AG
    J Neuroeng Rehabil; 2018 Sep; 15(Suppl 1):76. PubMed ID: 30255807
    [TBL] [Abstract][Full Text] [Related]  

  • 39. 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]  

  • 40. Effects of a powered ankle-foot prosthesis on kinetic loading of the unaffected leg during level-ground walking.
    Grabowski AM; D'Andrea S
    J Neuroeng Rehabil; 2013 Jun; 10():49. PubMed ID: 23758860
    [TBL] [Abstract][Full Text] [Related]  

    [Previous]   [Next]    [New Search]
    of 11.