Articular cartilage is the bearing material of diarthrodial joints. Its primary mechanical function is to transmit large loads across the articular surfaces of joints with minimal friction and wear; under normal conditions, cartilage can maintain this function for seven to eight decades. From an engineering perspective, the mechanical behavior of cartilage is considered to be remarkable, unmatched by any traditional engineering bearing material. However, despite several decades of sophisticated biomechanical studies of cartilage, an accurate understanding of cartilage mechanics remains elusive due to its remarkable versatility and complexity. Studies have demonstrated that the mechanical response of articular cartilage may vary as a function of duration and rate of loading or deformation, i.e., cartilage exhibits viscoelasticity. Furthermore, it has been shown that the tensile stiffness of cartilage differs when testing the tissue parallel and perpendicular to the split line directions, i.e., it exhibits anisotropy. It has also been established that the stiffness of cartilage in compression may be one to two orders of magnitude smaller than in tension, i.e., it exhibits tension-compression nonlinearity. Various studies have also confirmed that these measured properties may vary from the superficial to the deep zone of cartilage, i.e., the tissue exhibits depth-dependent inhomogeneity. To date, no single constitutive model of articular cartilage has been able to describe its mechanical response under the various testing conditions described in the literature. The hypotheses of this proposal are that (1) cartilage is orthotropic, requiring more material constants than have been measured to date to describe its mechanical response; (2) the tension-compression nonlinearity of cartilage requires that some, but not all of these constants have different values in tension and compression; and (3) that a theoretical framework encompassing cartilage orthotropy and tension-compression nonlinearity, using mixture theory, can provide agreement between theory and experiment for all testing configurations; this agreement improves when incorporating tissue inhomogeneity in the analysis. Therefore, the specific aims of this proposal are to test human patellar cartilage samples in tension, compression, shear and permeation, along the three mutually perpendicular directions which are hypothesized to characterize the planes of material symmetry, such as to determine experimentally a complete set of elastic and permeability constants of cartilage; to determine whether these constants indeed describe an orthotropic material; to experimentally assess the depth-dependent inhomogeneity of cartilage; and to compare transient and equilibrium experimental responses to corresponding predictions from a newly proposed biphasic, octantwise orthotropic, conewise linear elasticity model with depth-dependent inhomogenous properties. To achieve these aims, it is proposed to use the most current techniques for measurement of tissue mechanical properties.

Agency
National Institute of Health (NIH)
Institute
National Institute of Arthritis and Musculoskeletal and Skin Diseases (NIAMS)
Type
Research Project (R01)
Project #
5R01AR046532-03
Application #
6497416
Study Section
Orthopedics and Musculoskeletal Study Section (ORTH)
Program Officer
Panagis, James S
Project Start
2000-02-01
Project End
2004-01-31
Budget Start
2002-02-01
Budget End
2003-01-31
Support Year
3
Fiscal Year
2002
Total Cost
$179,907
Indirect Cost
Name
Columbia University (N.Y.)
Department
Engineering (All Types)
Type
Schools of Engineering
DUNS #
064931884
City
New York
State
NY
Country
United States
Zip Code
10027
Albro, Michael B; Banerjee, Rajan E; Li, Roland et al. (2011) Dynamic loading of immature epiphyseal cartilage pumps nutrients out of vascular canals. J Biomech 44:1654-9
Canal Guterl, Clare; Hung, Clark T; Ateshian, Gerard A (2010) Electrostatic and non-electrostatic contributions of proteoglycans to the compressive equilibrium modulus of bovine articular cartilage. J Biomech 43:1343-50
Ateshian, Gerard A; Ricken, Tim (2010) Multigenerational interstitial growth of biological tissues. Biomech Model Mechanobiol 9:689-702
Ateshian, Gerard A; Maas, Steve; Weiss, Jeffrey A (2010) Finite element algorithm for frictionless contact of porous permeable media under finite deformation and sliding. J Biomech Eng 132:061006
Ateshian, Gerard A; Weiss, Jeffrey A (2010) Anisotropic hydraulic permeability under finite deformation. J Biomech Eng 132:111004
Albro, Michael B; Li, Roland; Banerjee, Rajan E et al. (2010) Validation of theoretical framework explaining active solute uptake in dynamically loaded porous media. J Biomech 43:2267-73
Ateshian, Gerard A; Morrison 3rd, Barclay; Hung, Clark T (2010) Modeling of active transmembrane transport in a mixture theory framework. Ann Biomed Eng 38:1801-14
Ateshian, Gerard A; Costa, Kevin D (2009) A frame-invariant formulation of Fung elasticity. J Biomech 42:781-5
Guterl, Clare Canal; Gardner, Thomas R; Rajan, Vikram et al. (2009) Two-dimensional strain fields on the cross-section of the human patellofemoral joint under physiological loading. J Biomech 42:1275-81
Park, S; Costa, K D; Ateshian, G A et al. (2009) Mechanical properties of bovine articular cartilage under microscale indentation loading from atomic force microscopy. Proc Inst Mech Eng H 223:339-47

Showing the most recent 10 out of 54 publications