References
- Abousleiman, Y., A. H.-D. Cheng, L. Cui, E. Detournay, and J.-C. Roegiers. 1996. “Mandel’s problem revisited.” Géotechnique 46(2): 187–195.
- ANSYS, 2010. ANSYS mechanical APDL and mechanical applications theory reference, Release 13.0. Canonsburg, PA, USA: ANSYS, Inc.
- Armstrong, C. G., W. M. Lai, and V. C. Mow. 1984. “An analysis of the unconfined compression of articular cartilage.” Journal of biomechanical engineering 106(2): 165–173.
- Biot, M. A. 1941. “General theory of three-dimensional consolidation.” Journal of applied physics 12(2): 155–164.
- Brown, T. D., and R. J. Singerman. 1986. “Experimental determination of the linear biphasic constitutive coefficients of human fetal proximal femoral chondroepiphysis.” Journal of biomechanics 19(8): 597–605.
- Bursać, P. M., T. W. Obitz, S. R. Eisenberg, and D. Stamenović. 1999. “Confined and unconfined stress relaxation of cartilage: appropriateness of a transversely isotropic analysis.” Journal of biomechanics 32(10): 1125–1130.
- Cheng, A. H.-D. 1997. “Material coefficients of anisotropic poroelasticity.” International journal of rock mechanics and mining sciences 34(2): 199–205.
- Chung, C.-Y., Motavalli, M., and Mansour, J.M., 2012. Stress relaxation of cartilage under simple shear and compression: experiments and finite element analyses. In: Proceedings of the ASME 2012 summer bioengineering conference, 20–23 June, Farjardo, Puerto Rico. SBC2012-80145.
- Cohen, B., W. M. Lai, and V. C. Mow. 1998. “A transversely isotropic biphasic model for unconfined compression of growth plate and chondroepiphysis.” Journal of biomechanical engineering 120(4): 491–496.
- Detournay, E. and Cheng, A. H.-D., 1993. Fundamentals of poroelasticity. In: C. Fairhurst, ed. Comprehensive rock engineering: principles, practice & projects, Vol. II, analysis and design method, Oxford, England: Pergamon Press, 113–171.
- Laible, J. P., D. Pflaster, B. R. Simon, M. H. Krag, M. Pope, and L. D. Haugh. 1994. “A dynamic material parameter estimation procedure for soft tissue using a poroelastic finite element model.” Journal of biomechanical engineering 116(1): 19–29.
- Li, L. P., M. D. Buschmann, and A. Shirazi-Adl. 2000. “A fibril reinforced nonhomogeneous poroelastic model for articular cartilage: inhomogeneous response in unconfined compression.” Journal of biomechanics 33(12): 1533–1541.
- Mansour, J. M. 2004. “Biomechanics of cartilage.” In Kinesiology: the mechanics and pathomechanics of human movement, edited by Carol A. Oatis, 66–79. Philadelphia, PA: Lippincott Williams & Wilkins.
- Mow, V. C., S. C. Kuei, W. M. Lai, and C. G. Armstrong. 1980. “Biphasic creep and stress relaxation of articular cartilage in compression: theory and experiments.” Journal of biomechanical engineering 102(1): 73–84.
- Simon, B. R. 1992. “Multiphase poroelastic finite element models for soft tissue structures.” Applied mechanics reviews 45(6): 191–218.
- Simon, B.R., Wu, J.S.S., and Evans, J.H., 1983. Poroelastic mechanical models for the intervertebral disc. In: D.L. Bartel, ed. Advances in bioengineering, ASME winter annual meeting, 13-18 November, Boston, MA, USA, 106-107.
- Terzaghi, K. 1943. Theoretical soil mechanics. New York, NY: John Wiley.
- Wang, H. F. 2000. Theory of linear poroelasticity with applications to geomechanics and hydrogeology. Princeton, NJ: Princeton University Press.