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 *

164 related articles for article (PubMed ID: 11454286)

  • 41. Aspect ratio effects on revolving wings with Rossby number consideration.
    Lee YJ; Lua KB; Lim TT
    Bioinspir Biomim; 2016 Sep; 11(5):056013. PubMed ID: 27608653
    [TBL] [Abstract][Full Text] [Related]  

  • 42. Time-resolved vortex wake of a common swift flying over a range of flight speeds.
    Henningsson P; Muijres FT; Hedenström A
    J R Soc Interface; 2011 Jun; 8(59):807-16. PubMed ID: 21131333
    [TBL] [Abstract][Full Text] [Related]  

  • 43. Numerical simulation of X-wing type biplane flapping wings in 3D using the immersed boundary method.
    Tay WB; van Oudheusden BW; Bijl H
    Bioinspir Biomim; 2014 Sep; 9(3):036001. PubMed ID: 24584155
    [TBL] [Abstract][Full Text] [Related]  

  • 44. Passive aeroelastic deflection of avian primary feathers.
    Klaassen van Oorschot B; Choroszucha R; Tobalske BW
    Bioinspir Biomim; 2020 Jul; 15(5):056008. PubMed ID: 32470956
    [TBL] [Abstract][Full Text] [Related]  

  • 45. Field estimates of body drag coefficient on the basis of dives in passerine birds.
    Hedenström A; Liechti F
    J Exp Biol; 2001 Mar; 204(Pt 6):1167-75. PubMed ID: 11222132
    [TBL] [Abstract][Full Text] [Related]  

  • 46. A family of vortex wakes generated by a thrush nightingale in free flight in a wind tunnel over its entire natural range of flight speeds.
    Spedding GR; Rosén M; Hedenström A
    J Exp Biol; 2003 Jul; 206(Pt 14):2313-44. PubMed ID: 12796450
    [TBL] [Abstract][Full Text] [Related]  

  • 47. How swifts control their glide performance with morphing wings.
    Lentink D; Müller UK; Stamhuis EJ; de Kat R; van Gestel W; Veldhuis LL; Henningsson P; Hedenström A; Videler JJ; van Leeuwen JL
    Nature; 2007 Apr; 446(7139):1082-5. PubMed ID: 17460673
    [TBL] [Abstract][Full Text] [Related]  

  • 48. Flight of the honeybee. V. Drag and lift coefficients of the bee's body; implications for flight dynamics.
    Nachtigall W; Hanauer-Thieser U
    J Comp Physiol B; 1992; 162(3):267-77. PubMed ID: 1613166
    [TBL] [Abstract][Full Text] [Related]  

  • 49. Ontogeny of aerodynamics in mallards: comparative performance and developmental implications.
    Dial TR; Heers AM; Tobalske BW
    J Exp Biol; 2012 Nov; 215(Pt 21):3693-702. PubMed ID: 22855612
    [TBL] [Abstract][Full Text] [Related]  

  • 50. Unconventional lift-generating mechanisms in free-flying butterflies.
    Srygley RB; Thomas AL
    Nature; 2002 Dec; 420(6916):660-4. PubMed ID: 12478291
    [TBL] [Abstract][Full Text] [Related]  

  • 51. Air-permeable hole-pattern and nose-droop control improve aerodynamic performance of primary feathers.
    Eder H; Fiedler W; Pascoe X
    J Comp Physiol A Neuroethol Sens Neural Behav Physiol; 2011 Jan; 197(1):109-17. PubMed ID: 20938776
    [TBL] [Abstract][Full Text] [Related]  

  • 52. Pigeons produce aerodynamic torques through changes in wing trajectory during low speed aerial turns.
    Ros IG; Badger MA; Pierson AN; Bassman LC; Biewener AA
    J Exp Biol; 2015 Feb; 218(Pt 3):480-90. PubMed ID: 25452503
    [TBL] [Abstract][Full Text] [Related]  

  • 53. 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]  

  • 54. Vortex-wake interactions of a flapping foil that models animal swimming and flight.
    Lentink D; Muijres FT; Donker-Duyvis FJ; van Leeuwen JL
    J Exp Biol; 2008 Jan; 211(Pt 2):267-73. PubMed ID: 18165254
    [TBL] [Abstract][Full Text] [Related]  

  • 55. Clap and fling mechanism with interacting porous wings in tiny insect flight.
    Santhanakrishnan A; Robinson AK; Jones S; Low AA; Gadi S; Hedrick TL; Miller LA
    J Exp Biol; 2014 Nov; 217(Pt 21):3898-909. PubMed ID: 25189374
    [TBL] [Abstract][Full Text] [Related]  

  • 56. The relationship between 3-D kinematics and gliding performance in the southern flying squirrel, Glaucomys volans.
    Bishop KL
    J Exp Biol; 2006 Feb; 209(Pt 4):689-701. PubMed ID: 16449563
    [TBL] [Abstract][Full Text] [Related]  

  • 57. Numerical assessment of wake-based estimation of instantaneous lift in flapping flight of large birds.
    Colognesi V; Ronsse R; Chatelain P
    PLoS One; 2023; 18(5):e0284714. PubMed ID: 37141190
    [TBL] [Abstract][Full Text] [Related]  

  • 58. Dynamics of the vortex wakes of flying and swimming vertebrates.
    Rayner JM
    Symp Soc Exp Biol; 1995; 49():131-55. PubMed ID: 8571221
    [TBL] [Abstract][Full Text] [Related]  

  • 59. Biomechanics and physiology of gait selection in flying birds.
    Tobalske BW
    Physiol Biochem Zool; 2000; 73(6):736-50. PubMed ID: 11121347
    [TBL] [Abstract][Full Text] [Related]  

  • 60. Energy considerations and flow fields over whiffling-inspired wings.
    Sigrest P; Wu N; Inman DJ
    Bioinspir Biomim; 2023 May; 18(4):. PubMed ID: 37141892
    [TBL] [Abstract][Full Text] [Related]  

    [Previous]   [Next]    [New Search]
    of 9.