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Journal Abstract Search

348 related items for PubMed ID: 18236120

  • 1.
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  • 3. Fluid dynamic models of flagellar and ciliary beating.
    Dillon RH, Fauci LJ, Omoto C, Yang X.
    Ann N Y Acad Sci; 2007 Apr; 1101():494-505. PubMed ID: 17344534
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  • 4. The chirality of ciliary beats.
    Hilfinger A, Jülicher F.
    Phys Biol; 2008 Mar 19; 5(1):016003. PubMed ID: 18356578
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  • 5. Using Lagrangian coherent structures to analyze fluid mixing by cilia.
    Lukens S, Yang X, Fauci L.
    Chaos; 2010 Mar 19; 20(1):017511. PubMed ID: 20370301
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  • 6. A model of flagellar and ciliary functioning which uses the forces transverse to the axoneme as the regulator of dynein activation.
    Lindemann CB.
    Cell Motil Cytoskeleton; 1994 Mar 19; 29(2):141-54. PubMed ID: 7820864
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  • 7. Computation of the internal forces in cilia: application to ciliary motion, the effects of viscosity, and cilia interactions.
    Gueron S, Levit-Gurevich K.
    Biophys J; 1998 Apr 19; 74(4):1658-76. PubMed ID: 9545031
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  • 8. Effect of viscosity on metachrony in mucus propelling cilia.
    Gheber L, Korngreen A, Priel Z.
    Cell Motil Cytoskeleton; 1998 Apr 19; 39(1):9-20. PubMed ID: 9453710
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  • 9. Flagellar and ciliary beating: the proven and the possible.
    Lindemann CB, Lesich KA.
    J Cell Sci; 2010 Feb 15; 123(Pt 4):519-28. PubMed ID: 20145000
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  • 10. Biophysical aspects and modelling of ciliary motility.
    Holwill ME, Foster GF, Hamasaki T, Satir P.
    Cell Motil Cytoskeleton; 1995 Feb 15; 32(2):114-20. PubMed ID: 8681391
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  • 11. Curvature regulation of the ciliary beat through axonemal twist.
    Sartori P, Geyer VF, Howard J, Jülicher F.
    Phys Rev E; 2016 Oct 15; 94(4-1):042426. PubMed ID: 27841522
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  • 12. Energetic considerations of ciliary beating and the advantage of metachronal coordination.
    Gueron S, Levit-Gurevich K.
    Proc Natl Acad Sci U S A; 1999 Oct 26; 96(22):12240-5. PubMed ID: 10535905
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  • 13. Geometric Clutch model version 3: the role of the inner and outer arm dyneins in the ciliary beat.
    Lindemann CB.
    Cell Motil Cytoskeleton; 2002 Aug 26; 52(4):242-54. PubMed ID: 12112138
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  • 14. Efficient mucociliary transport relies on efficient regulation of ciliary beating.
    Braiman A, Priel Z.
    Respir Physiol Neurobiol; 2008 Nov 30; 163(1-3):202-7. PubMed ID: 18586580
    [Abstract] [Full Text] [Related]

  • 15. Time-dependent measure of a nanoscale force-pulse driven by the axonemal dynein motors in individual live sperm cells.
    Allen MJ, Rudd RE, McElfresh MW, Balhorn R.
    Nanomedicine; 2010 Aug 30; 6(4):510-5. PubMed ID: 20060073
    [Abstract] [Full Text] [Related]

  • 16. On metachronism in ciliary systems: a model describing the dependence of the metachronal wave properties on the intrinsic ciliary parameters.
    Gheber L, Priel Z.
    Cell Motil Cytoskeleton; 1990 Aug 30; 16(3):167-81. PubMed ID: 2364445
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  • 17. A moving image of flagella: news and views on the mechanisms involved in axonemal beating.
    Cosson J.
    Cell Biol Int; 1996 Feb 30; 20(2):83-94. PubMed ID: 8935152
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  • 18. A model for the oscillatory motion of single dynein molecules.
    Goedecke DM, Elston TC.
    J Theor Biol; 2005 Jan 07; 232(1):27-39. PubMed ID: 15498590
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  • 19. The dynein-triggered ciliary motion in embryonic nodes: an exploratory study based on computational models.
    Chen D, Zhong Y, Shinohara K, Nishida T, Hasegawa T, Hamada H.
    Biomed Mater Eng; 2014 Jan 07; 24(6):2495-501. PubMed ID: 25226950
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  • 20. The Motion of An Inv Nodal Cilium: a Realistic Model Revealing Dynein-Driven Ciliary Motion with Microtubule Mislocalization.
    Yu Y, Shinohara K, Xu H, Li Z, Nishida T, Hamada H, Xu Y, Zhou J, Shao D, Li X, Chen D.
    Cell Physiol Biochem; 2018 Jan 07; 51(6):2843-2857. PubMed ID: 30562762
    [Abstract] [Full Text] [Related]

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