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 *

159 related articles for article (PubMed ID: 25320064)

  • 1. Wing tucks are a response to atmospheric turbulence in the soaring flight of the steppe eagle Aquila nipalensis.
    Reynolds KV; Thomas AL; Taylor GK
    J R Soc Interface; 2014 Dec; 11(101):20140645. PubMed ID: 25320064
    [TBL] [Abstract][Full Text] [Related]  

  • 2. Soaring energetics and glide performance in a moving atmosphere.
    Taylor GK; Reynolds KV; Thomas AL
    Philos Trans R Soc Lond B Biol Sci; 2016 Sep; 371(1704):. PubMed ID: 27528788
    [TBL] [Abstract][Full Text] [Related]  

  • 3. Automatic aeroelastic devices in the wings of a steppe eagle Aquila nipalensis.
    Carruthers AC; Thomas AL; Taylor GK
    J Exp Biol; 2007 Dec; 210(Pt 23):4136-49. PubMed ID: 18025013
    [TBL] [Abstract][Full Text] [Related]  

  • 4. Wing rapid responses and aerodynamics of fruit flies during headwind gust perturbations.
    Gu M; Wu J; Zhang Y
    Bioinspir Biomim; 2020 Jul; 15(5):056001. PubMed ID: 32470950
    [TBL] [Abstract][Full Text] [Related]  

  • 5. Bird wings act as a suspension system that rejects gusts.
    Cheney JA; Stevenson JPJ; Durston NE; Song J; Usherwood JR; Bomphrey RJ; Windsor SP
    Proc Biol Sci; 2020 Oct; 287(1937):20201748. PubMed ID: 33081609
    [TBL] [Abstract][Full Text] [Related]  

  • 6. The gliding speed of migrating birds: slow and safe or fast and risky?
    Horvitz N; Sapir N; Liechti F; Avissar R; Mahrer I; Nathan R
    Ecol Lett; 2014 Jun; 17(6):670-9. PubMed ID: 24641086
    [TBL] [Abstract][Full Text] [Related]  

  • 7. Aerodynamic response of a red-tailed hawk to discrete transverse gusts.
    Bamford C; Swiney P; Nix J; Hedrick TL; Raghav V
    Bioinspir Biomim; 2024 Apr; 19(3):. PubMed ID: 38467074
    [TBL] [Abstract][Full Text] [Related]  

  • 8. Turbulence explains the accelerations of an eagle in natural flight.
    Laurent KM; Fogg B; Ginsburg T; Halverson C; Lanzone MJ; Miller TA; Winkler DW; Bewley GP
    Proc Natl Acad Sci U S A; 2021 Jun; 118(23):. PubMed ID: 34074786
    [TBL] [Abstract][Full Text] [Related]  

  • 9. How oscillating aerodynamic forces explain the timbre of the hummingbird's hum and other animals in flapping flight.
    Hightower BJ; Wijnings PW; Scholte R; Ingersoll R; Chin DD; Nguyen J; Shorr D; Lentink D
    Elife; 2021 Mar; 10():. PubMed ID: 33724182
    [TBL] [Abstract][Full Text] [Related]  

  • 10. Wing morphology, flight type and migration distance predict accumulated fuel load in birds.
    Vincze O; Vágási CI; Pap PL; Palmer C; Møller AP
    J Exp Biol; 2019 Jan; 222(Pt 1):. PubMed ID: 30446537
    [TBL] [Abstract][Full Text] [Related]  

  • 11. Use of multiple modes of flight subsidy by a soaring terrestrial bird, the golden eagle Aquila chrysaetos, when on migration.
    Katzner TE; Turk PJ; Duerr AE; Miller TA; Lanzone MJ; Cooper JL; Brandes D; Tremblay JA; Lemaître J
    J R Soc Interface; 2015 Nov; 12(112):. PubMed ID: 26538556
    [TBL] [Abstract][Full Text] [Related]  

  • 12. A contralateral wing stabilizes a hovering hawkmoth under a lateral gust.
    Han JS; Han JH
    Sci Rep; 2019 Nov; 9(1):17397. PubMed ID: 31757991
    [TBL] [Abstract][Full Text] [Related]  

  • 13. The gust-mitigating potential of flapping wings.
    Fisher A; Ravi S; Watkins S; Watmuff J; Wang C; Liu H; Petersen P
    Bioinspir Biomim; 2016 Aug; 11(4):046010. PubMed ID: 27481211
    [TBL] [Abstract][Full Text] [Related]  

  • 14. Aerodynamic robustness in owl-inspired leading-edge serrations: a computational wind-gust model.
    Rao C; Liu H
    Bioinspir Biomim; 2018 Jul; 13(5):056002. PubMed ID: 29882513
    [TBL] [Abstract][Full Text] [Related]  

  • 15. 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]  

  • 16. A trapezoidal wing equivalent to a Janatella leucodesma's wing in terms of aerodynamic performance in the flapping flight of a butterfly model.
    Suzuki K; Yoshino M
    Bioinspir Biomim; 2019 Feb; 14(3):036003. PubMed ID: 30634176
    [TBL] [Abstract][Full Text] [Related]  

  • 17. Multi-cored vortices support function of slotted wing tips of birds in gliding and flapping flight.
    KleinHeerenbrink M; Johansson LC; Hedenström A
    J R Soc Interface; 2017 May; 14(130):. PubMed ID: 28539482
    [TBL] [Abstract][Full Text] [Related]  

  • 18. A chordwise offset of the wing-pitch axis enhances rotational aerodynamic forces on insect wings: a numerical study.
    van Veen WG; van Leeuwen JL; Muijres FT
    J R Soc Interface; 2019 Jun; 16(155):20190118. PubMed ID: 31213176
    [TBL] [Abstract][Full Text] [Related]  

  • 19. Wing inertia and whole-body acceleration: an analysis of instantaneous aerodynamic force production in cockatiels (Nymphicus hollandicus) flying across a range of speeds.
    Hedrick TL; Usherwood JR; Biewener AA
    J Exp Biol; 2004 Apr; 207(Pt 10):1689-702. PubMed ID: 15073202
    [TBL] [Abstract][Full Text] [Related]  

  • 20. Efficiency of lift production in flapping and gliding flight of swifts.
    Henningsson P; Hedenström A; Bomphrey RJ
    PLoS One; 2014; 9(2):e90170. PubMed ID: 24587260
    [TBL] [Abstract][Full Text] [Related]  

    [Next]    [New Search]
    of 8.