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Pubmed for Handhelds

PUBMED FOR HANDHELDS

Journal Abstract Search

173 related items for PubMed ID: 31476188

  • 1. Pilot study of the microprocessor-controlled prosthetic knee with a novel hydraulic damper.
    Zhang Y, Cao W, Yu H, Meng Q, Chen W.
    Technol Health Care; 2020; 28(1):93-97. PubMed ID: 31476188
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  • 2. The comparison of transfemoral amputees using mechanical and microprocessor- controlled prosthetic knee under different walking speeds: A randomized cross-over trial.
    Cao W, Yu H, Zhao W, Meng Q, Chen W.
    Technol Health Care; 2018; 26(4):581-592. PubMed ID: 29710741
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  • 3. Assessment of transfemoral amputees using a passive microprocessor-controlled knee versus an active powered microprocessor-controlled knee for level walking.
    Creylman V, Knippels I, Janssen P, Biesbrouck E, Lechler K, Peeraer L.
    Biomed Eng Online; 2016 Dec 19; 15(Suppl 3):142. PubMed ID: 28105945
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  • 4. Impact of a stance phase microprocessor-controlled knee prosthesis on level walking in lower functioning individuals with a transfemoral amputation.
    Eberly VJ, Mulroy SJ, Gronley JK, Perry J, Yule WJ, Burnfield JM.
    Prosthet Orthot Int; 2014 Dec 19; 38(6):447-55. PubMed ID: 24135259
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  • 5. Safety and function of a prototype microprocessor-controlled knee prosthesis for low active transfemoral amputees switching from a mechanic knee prosthesis: a pilot study.
    Hasenoehrl T, Schmalz T, Windhager R, Domayer S, Dana S, Ambrozy C, Palma S, Crevenna R.
    Disabil Rehabil Assist Technol; 2018 Feb 19; 13(2):157-165. PubMed ID: 28399722
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  • 6. Enhancement of a prosthetic knee with a microprocessor-controlled gait phase switch reduces falls and improves balance confidence and gait speed in community ambulators with unilateral transfemoral amputation.
    Fuenzalida Squella SA, Kannenberg A, Brandão Benetti Â.
    Prosthet Orthot Int; 2018 Apr 19; 42(2):228-235. PubMed ID: 28691574
    [Abstract] [Full Text] [Related]

  • 7. Gait termination on a declined surface in trans-femoral amputees: Impact of using microprocessor-controlled limb system.
    Abdulhasan ZM, Scally AJ, Buckley JG.
    Clin Biomech (Bristol); 2018 Aug 19; 57():35-41. PubMed ID: 29908391
    [Abstract] [Full Text] [Related]

  • 8. Physiological parameters analysis of transfemoral amputees with different prosthetic knees.
    Li S, Cao W, Yu H, Meng Q, Chen W.
    Acta Bioeng Biomech; 2019 Aug 19; 21(3):135-142. PubMed ID: 31798017
    [Abstract] [Full Text] [Related]

  • 9. Differences in knee flexion between the Genium and C-Leg microprocessor knees while walking on level ground and ramps.
    Lura DJ, Wernke MM, Carey SL, Kahle JT, Miro RM, Highsmith MJ.
    Clin Biomech (Bristol); 2015 Feb 19; 30(2):175-81. PubMed ID: 25537443
    [Abstract] [Full Text] [Related]

  • 10. Comparative biomechanical analysis of current microprocessor-controlled prosthetic knee joints.
    Bellmann M, Schmalz T, Blumentritt S.
    Arch Phys Med Rehabil; 2010 Apr 19; 91(4):644-52. PubMed ID: 20382300
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  • 12. Comparative biomechanical evaluation of two technologically different microprocessor-controlled prosthetic knee joints in safety-relevant daily-life situations.
    Bellmann M, Köhler TM, Schmalz T.
    Biomed Tech (Berl); 2019 Aug 27; 64(4):407-420. PubMed ID: 30540556
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  • 14. The influence of a user-adaptive prosthetic knee across varying walking speeds: A randomized cross-over trial.
    Prinsen EC, Nederhand MJ, Sveinsdóttir HS, Prins MR, van der Meer F, Koopman HFJM, Rietman JS.
    Gait Posture; 2017 Jan 27; 51():254-260. PubMed ID: 27838569
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  • 16. Designs and performance of three new microprocessor-controlled knee joints.
    Thiele J, Schöllig C, Bellmann M, Kraft M.
    Biomed Tech (Berl); 2019 Feb 25; 64(1):119-126. PubMed ID: 29425102
    [Abstract] [Full Text] [Related]

  • 17. Design, Analysis, and Development of Low-Cost State-of-the-Art Magnetorheological-Based Microprocessor Prosthetic Knee.
    Qadir MU, Haq IU, Khan MA, Shah K, Chouikhi H, Ismail MA.
    Sensors (Basel); 2024 Jan 01; 24(1):. PubMed ID: 38203117
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