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 *

215 related articles for article (PubMed ID: 30362460)

  • 1. Flow structure modifications by leading-edge tubercles on a 3D wing.
    Kim H; Kim J; Choi H
    Bioinspir Biomim; 2018 Oct; 13(6):066011. PubMed ID: 30362460
    [TBL] [Abstract][Full Text] [Related]  

  • 2. Power reduction and the radial limit of stall delay in revolving wings of different aspect ratio.
    Kruyt JW; van Heijst GF; Altshuler DL; Lentink D
    J R Soc Interface; 2015 Apr; 12(105):. PubMed ID: 25788539
    [TBL] [Abstract][Full Text] [Related]  

  • 3. The tubercles on humpback whales' flippers: application of bio-inspired technology.
    Fish FE; Weber PW; Murray MM; Howle LE
    Integr Comp Biol; 2011 Jul; 51(1):203-13. PubMed ID: 21576119
    [TBL] [Abstract][Full Text] [Related]  

  • 4. Combined particle-image velocimetry and force analysis of the three-dimensional fluid-structure interaction of a natural owl wing.
    Winzen A; Roidl B; Schröder W
    Bioinspir Biomim; 2016 Apr; 11(2):026005. PubMed ID: 27033298
    [TBL] [Abstract][Full Text] [Related]  

  • 5. Particle-image velocimetry investigation of the fluid-structure interaction mechanisms of a natural owl wing.
    Winzen A; Roidl B; Schröder W
    Bioinspir Biomim; 2015 Sep; 10(5):056009. PubMed ID: 26372422
    [TBL] [Abstract][Full Text] [Related]  

  • 6. On the high-lift characteristics of a bio-inspired, slotted delta wing.
    Sheppard KA; Rival DE
    Bioinspir Biomim; 2018 Apr; 13(3):036008. PubMed ID: 29447117
    [TBL] [Abstract][Full Text] [Related]  

  • 7. Effects of leading-edge tubercles on wing flutter speeds.
    Ng BF; New TH; Palacios R
    Bioinspir Biomim; 2016 Apr; 11(3):036003. PubMed ID: 27070824
    [TBL] [Abstract][Full Text] [Related]  

  • 8. Investigation of a bio-inspired lift-enhancing effector on a 2D airfoil.
    Johnston J; Gopalarathnam A
    Bioinspir Biomim; 2012 Sep; 7(3):036003. PubMed ID: 22498691
    [TBL] [Abstract][Full Text] [Related]  

  • 9. Feather roughness reduces flow separation during low Reynolds number glides of swifts.
    van Bokhorst E; de Kat R; Elsinga GE; Lentink D
    J Exp Biol; 2015 Oct; 218(Pt 20):3179-91. PubMed ID: 26347563
    [TBL] [Abstract][Full Text] [Related]  

  • 10. The effect of aspect ratio on the leading-edge vortex over an insect-like flapping wing.
    Phillips N; Knowles K; Bomphrey RJ
    Bioinspir Biomim; 2015 Oct; 10(5):056020. PubMed ID: 26451802
    [TBL] [Abstract][Full Text] [Related]  

  • 11. Hydrodynamic design of the humpback whale flipper.
    Fish FE; Battle JM
    J Morphol; 1995 Jul; 225(1):51-60. PubMed ID: 7650744
    [TBL] [Abstract][Full Text] [Related]  

  • 12. The role of the leading edge vortex in lift augmentation of steadily revolving wings: a change in perspective.
    Nabawy MRA; Crowther WJ
    J R Soc Interface; 2017 Jul; 14(132):. PubMed ID: 28747395
    [TBL] [Abstract][Full Text] [Related]  

  • 13. Ground effect on the aerodynamics of three-dimensional hovering wings.
    Lu H; Lua KB; Lee YJ; Lim TT; Yeo KS
    Bioinspir Biomim; 2016 Oct; 11(6):066003. PubMed ID: 27780156
    [TBL] [Abstract][Full Text] [Related]  

  • 14. Three-dimensional flow structures and evolution of the leading-edge vortices on a flapping wing.
    Lu Y; Shen GX
    J Exp Biol; 2008 Apr; 211(Pt 8):1221-30. PubMed ID: 18375846
    [TBL] [Abstract][Full Text] [Related]  

  • 15. A predictive model of the drag coefficient for a revolving wing at low Reynolds number.
    Oh S; Choi H
    Bioinspir Biomim; 2018 Aug; 13(5):054001. PubMed ID: 30039801
    [TBL] [Abstract][Full Text] [Related]  

  • 16. The function of the alula in avian flight.
    Lee SI; Kim J; Park H; Jabłoński PG; Choi H
    Sci Rep; 2015 May; 5():9914. PubMed ID: 25951056
    [TBL] [Abstract][Full Text] [Related]  

  • 17. Unsteady forces and flows in low Reynolds number hovering flight: two-dimensional computations vs robotic wing experiments.
    Wang ZJ; Birch JM; Dickinson MH
    J Exp Biol; 2004 Jan; 207(Pt 3):449-60. PubMed ID: 14691093
    [TBL] [Abstract][Full Text] [Related]  

  • 18. Dragonfly flight: free-flight and tethered flow visualizations reveal a diverse array of unsteady lift-generating mechanisms, controlled primarily via angle of attack.
    Thomas AL; Taylor GK; Srygley RB; Nudds RL; Bomphrey RJ
    J Exp Biol; 2004 Nov; 207(Pt 24):4299-323. PubMed ID: 15531651
    [TBL] [Abstract][Full Text] [Related]  

  • 19. Unsteady aerodynamic forces of a flapping wing.
    Wu JH; Sun M
    J Exp Biol; 2004 Mar; 207(Pt 7):1137-50. PubMed ID: 14978056
    [TBL] [Abstract][Full Text] [Related]  

  • 20. The effects of wing twist in slow-speed flapping flight of birds: trading brute force against efficiency.
    Thielicke W; Stamhuis EJ
    Bioinspir Biomim; 2018 Aug; 13(5):056015. PubMed ID: 30043756
    [TBL] [Abstract][Full Text] [Related]  

    [Next]    [New Search]
    of 11.