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 *

170 related articles for article (PubMed ID: 22244093)

  • 1. The speed of sound through trabecular bone predicted by Biot theory.
    Yoon YJ; Chung JP; Bae CS; Han SY
    J Biomech; 2012 Feb; 45(4):716-8. PubMed ID: 22244093
    [TBL] [Abstract][Full Text] [Related]  

  • 2. Empirical angle-dependent Biot and MBA models for acoustic anisotropy in cancellous bone.
    Lee KI; Hughes ER; Humphrey VF; Leighton TG; Choi MJ
    Phys Med Biol; 2007 Jan; 52(1):59-73. PubMed ID: 17183128
    [TBL] [Abstract][Full Text] [Related]  

  • 3. Biot theory: a review of its application to ultrasound propagation through cancellous bone.
    Haire TJ; Langton CM
    Bone; 1999 Apr; 24(4):291-5. PubMed ID: 10221540
    [TBL] [Abstract][Full Text] [Related]  

  • 4. Predictions of angle dependent tortuosity and elasticity effects on sound propagation in cancellous bone.
    Aygün H; Attenborough K; Postema M; Lauriks W; Langton CM
    J Acoust Soc Am; 2009 Dec; 126(6):3286-90. PubMed ID: 20000942
    [TBL] [Abstract][Full Text] [Related]  

  • 5. In vitro acoustic waves propagation in human and bovine cancellous bone.
    Cardoso L; Teboul F; Sedel L; Oddou C; Meunier A
    J Bone Miner Res; 2003 Oct; 18(10):1803-12. PubMed ID: 14584891
    [TBL] [Abstract][Full Text] [Related]  

  • 6. Transient ultrasound propagation in porous media using Biot theory and fractional calculus: application to human cancellous bone.
    Fellah M; Fellah ZE; Mitri FG; Ogam E; Depollier C
    J Acoust Soc Am; 2013 Apr; 133(4):1867-81. PubMed ID: 23556556
    [TBL] [Abstract][Full Text] [Related]  

  • 7. The effect of charge density on the velocity and attenuation of ultrasound waves in human cancellous bone.
    Yoon YJ
    J Biomech; 2018 Oct; 79():54-57. PubMed ID: 30122518
    [TBL] [Abstract][Full Text] [Related]  

  • 8. A description of transversely isotropic sound absorbing porous materials by transfer matrices.
    Khurana P; Boeckx L; Lauriks W; Leclaire P; Dazel O; Allard JF
    J Acoust Soc Am; 2009 Feb; 125(2):915-21. PubMed ID: 19206868
    [TBL] [Abstract][Full Text] [Related]  

  • 9. Ultrasonic wave propagation in human cancellous bone: application of Biot theory.
    Fellah ZE; Chapelon JY; Berger S; Lauriks W; Depollier C
    J Acoust Soc Am; 2004 Jul; 116(1):61-73. PubMed ID: 15295965
    [TBL] [Abstract][Full Text] [Related]  

  • 10. Inhomogeneity of tissue-level strain distributions in individual trabeculae: mathematical model studies of normal and osteoporosis cases.
    Gefen A; Portnoy S; Diamant I
    Med Eng Phys; 2008 Jun; 30(5):624-30. PubMed ID: 17697794
    [TBL] [Abstract][Full Text] [Related]  

  • 11. Spectral analysis and connectivity of porous microstructures in bone.
    Golden KM; Benjamin Murphy N; Cherkaev E
    J Biomech; 2011 Jan; 44(2):337-44. PubMed ID: 21094945
    [TBL] [Abstract][Full Text] [Related]  

  • 12. Estimation of critical and viscous frequencies for Biot theory in cancellous bone.
    Hughes ER; Leighton TG; Petley GW; White PR; Chivers RC
    Ultrasonics; 2003 Jul; 41(5):365-8. PubMed ID: 12788218
    [TBL] [Abstract][Full Text] [Related]  

  • 13. Fabric dependence of wave propagation in anisotropic porous media.
    Cowin SC; Cardoso L
    Biomech Model Mechanobiol; 2011 Feb; 10(1):39-65. PubMed ID: 20461539
    [TBL] [Abstract][Full Text] [Related]  

  • 14. Application of Biot's theory to ultrasonic characterization of human cancellous bones: determination of structural, material, and mechanical properties.
    Pakula M; Padilla F; Laugier P; Kaczmarek M
    J Acoust Soc Am; 2008 Apr; 123(4):2415-23. PubMed ID: 18397044
    [TBL] [Abstract][Full Text] [Related]  

  • 15. Increased calcium content and inhomogeneity of mineralization render bone toughness in osteoporosis: mineralization, morphology and biomechanics of human single trabeculae.
    Busse B; Hahn M; Soltau M; Zustin J; Püschel K; Duda GN; Amling M
    Bone; 2009 Dec; 45(6):1034-43. PubMed ID: 19679206
    [TBL] [Abstract][Full Text] [Related]  

  • 16. A multiscale poromicromechanical approach to wave propagation and attenuation in bone.
    Morin C; Hellmich C
    Ultrasonics; 2014 Jul; 54(5):1251-69. PubMed ID: 24457030
    [TBL] [Abstract][Full Text] [Related]  

  • 17. Investigation of an anisotropic tortuosity in a biot model of ultrasonic propagation in cancellous bone.
    Hughes ER; Leighton TG; White PR; Petley GW
    J Acoust Soc Am; 2007 Jan; 121(1):568-74. PubMed ID: 17297810
    [TBL] [Abstract][Full Text] [Related]  

  • 18. Predictions of the modified Biot-Attenborough model for the dependence of phase velocity on porosity in cancellous bone.
    Lee KI; Humphrey VF; Leighton TG; Yoon SW
    Ultrasonics; 2007 Nov; 46(4):323-30. PubMed ID: 17573089
    [TBL] [Abstract][Full Text] [Related]  

  • 19. Effect of porosity distribution in the propagation direction on ultrasound waves through cancellous bone.
    Hosokawa A
    IEEE Trans Ultrason Ferroelectr Freq Control; 2010 Jun; 57(6):1320-8. PubMed ID: 20529708
    [TBL] [Abstract][Full Text] [Related]  

  • 20. Numerical and experimental study on the wave attenuation in bone--FDTD simulation of ultrasound propagation in cancellous bone.
    Nagatani Y; Mizuno K; Saeki T; Matsukawa M; Sakaguchi T; Hosoi H
    Ultrasonics; 2008 Nov; 48(6-7):607-12. PubMed ID: 18589470
    [TBL] [Abstract][Full Text] [Related]  

    [Next]    [New Search]
    of 9.