Modelling cartilage mechanobiology.

The growth, maintenance and ossification of cartilage are fundamental to skeletal development and are regulated throughout life by the mechanical cues that are imposed by physical activities. Finite element computer analyses have been used to study the role of local tissue mechanics on endochondral ossification patterns, skeletal morphology and articular cartilage thickness distributions. Using single-phase continuum material representations of cartilage, the results have indicated that local intermittent hydrostatic pressure promotes cartilage maintenance. Cyclic tensile strains (or shear), however, promote cartilage growth and ossification. Because single-phase material models cannot capture fluid exudation in articular cartilage, poroelastic (or biphasic) solid/fluid models are often implemented to study joint mechanics. In the middle and deep layers of articular cartilage where poroelastic analyses predict little fluid exudation, the cartilage phenotype is maintained by cyclic fluid pressure (consistent with the single-phase theory). In superficial articular layers the chondrocytes are exposed to tangential tensile strain in addition to the high fluid pressure. Furthermore, there is fluid exudation and matrix consolidation, leading to cell 'flattening'. As a result, the superficial layer assumes an altered, more fibrous phenotype. These computer model predictions of cartilage mechanobiology are consistent with results of in vitro cell and tissue and molecular biology experiments.

[1]  F Eckstein,et al.  Knee cartilage of spinal cord-injured patients displays progressive thinning in the absence of normal joint loading and movement. , 2002, Arthritis and rheumatism.

[2]  Gerard A. Ateshian,et al.  Interstitial Fluid Pressurization During Confined Compression Cyclical Loading of Articular Cartilage , 2000, Annals of Biomedical Engineering.

[3]  P. D. Rushfeldt,et al.  Improved techniques for measuring in vitro the geometry and pressure distribution in the human acetabulum. II Instrumented endoprosthesis measurement of articular surface pressure distribution. , 1981, Journal of biomechanics.

[4]  D R Carter,et al.  Mechanical induction in limb morphogenesis: the role of growth-generated strains and pressures. , 2002, Bone.

[5]  J. Z. Zhu,et al.  The finite element method , 1977 .

[6]  F. Hirche,et al.  Fibroblasts in Mechanically Stressed Collagen Lattices Assume a “Synthetic” Phenotype* , 2001, The Journal of Biological Chemistry.

[7]  J. Trueta,et al.  Studies of the Development and Decay of the Human Frame , 1968 .

[8]  Maximilian Reiser,et al.  Functional analysis of articular cartilage deformation, recovery, and fluid flow following dynamic exercise in vivo , 1999, Anatomy and Embryology.

[9]  T. Stammberger,et al.  Patellar cartilage deformation in vivo after static versus dynamic loading. , 2000, Journal of biomechanics.

[10]  E. Stüssi,et al.  The effects of immobilization on the characteristics of articular cartilage: current concepts and future directions. , 2002, Osteoarthritis and cartilage.

[11]  Q Q Wu,et al.  Mechanoregulation of chondrocyte proliferation, maturation, and hypertrophy: ion-channel dependent transduction of matrix deformation signals. , 2000, Experimental cell research.

[12]  S. S. Stevens,et al.  Mechanobiology in the development, maintenance, and degeneration of articular cartilage. , 2000, Journal of rehabilitation research and development.

[13]  Y. Kato,et al.  The effects of high magnitude cyclic tensile load on cartilage matrix metabolism in cultured chondrocytes. , 2000, European journal of cell biology.

[14]  S J Shefelbine,et al.  Development of the femoral bicondylar angle in hominid bipedalism. , 2002, Bone.

[15]  F. J. Dzida,et al.  Comparative study of the intrinsic mechanical properties of the human acetabular and femoral head cartilage , 1991, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[16]  A Shirazi-Adl,et al.  A fibril-network-reinforced biphasic model of cartilage in unconfined compression. , 1999, Journal of biomechanical engineering.

[17]  G A Ateshian,et al.  Experimental verification and theoretical prediction of cartilage interstitial fluid pressurization at an impermeable contact interface in confined compression. , 1998, Journal of biomechanics.

[18]  J S Jurvelin,et al.  Volumetric changes of articular cartilage during stress relaxation in unconfined compression. , 2000, Journal of biomechanics.

[19]  R. Huiskes,et al.  Biophysical stimuli on cells during tissue differentiation at implant interfaces , 1997 .

[20]  Thiennu H. Vu,et al.  Matrix metalloproteinases: effectors of development and normal physiology. , 2000, Genes & development.

[21]  M. Biot General Theory of Three‐Dimensional Consolidation , 1941 .

[22]  W M Lai,et al.  An analysis of the unconfined compression of articular cartilage. , 1984, Journal of biomechanical engineering.

[23]  Takashi Ushida,et al.  Hydrostatic fluid pressure enhances matrix synthesis and accumulation by bovine chondrocytes in three‐dimensional culture , 2002, Journal of cellular physiology.

[24]  R. Teitge,et al.  Factors affecting articular cartilage thickness in osteoarthritis and aging. , 1994, The Journal of rheumatology.

[25]  S. Agarwal,et al.  Low Magnitude of Tensile Strain Inhibits IL-1β-dependent Induction of Pro-inflammatory Cytokines and Induces Synthesis of IL-10 in Human Periodontal Ligament Cells in vitro , 2001, Journal of dental research.

[26]  W C Hayes,et al.  Flow-independent viscoelastic properties of articular cartilage matrix. , 1978, Journal of biomechanics.

[27]  P. Eggli,et al.  Chondrocyte biosynthesis correlates with local tissue strain in statically compressed adult articular cartilage , 1997, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[28]  H. Yokota,et al.  Altered mRNA level of matrix metalloproteinase-13 in MH7A synovial cells under mechanical loading and unloading. , 2001, Bone.

[29]  V. Mow,et al.  Biphasic creep and stress relaxation of articular cartilage in compression? Theory and experiments. , 1980, Journal of biomechanical engineering.

[30]  Yue Zhang,et al.  Indian hedgehog Is an Essential Component of Mechanotransduction Complex to Stimulate Chondrocyte Proliferation* , 2001, The Journal of Biological Chemistry.

[31]  D R Carter,et al.  The role of mechanical loading histories in the development of diarthrodial joints , 1988, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[32]  A. Grodzinsky,et al.  Variationally derived 3-field finite element formulations for quasistatic poroelastic analysis of hydrated biological tissues , 1998 .

[33]  D. Carter,et al.  Rabbit knee immobilization: Bone remodeling precedes cartilage degradation , 1992, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[34]  P. D. Rushfeldt,et al.  Improved techniques for measuring in vitro the geometry and pressure distribution in the human acetabulum--I. Ultrasonic measurement of acetabular surfaces, sphericity and cartilage thickness. , 1981, Journal of biomechanics.

[35]  D. R. Carter,et al.  In vitro stimulation of articular chondrocyte mRNA and extracellular matrix synthesis by hydrostatic pressure , 1996, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[36]  G A Ateshian,et al.  A Conewise Linear Elasticity mixture model for the analysis of tension-compression nonlinearity in articular cartilage. , 2000, Journal of biomechanical engineering.

[37]  A.,et al.  THE VASCULARITY AND REMODELLING OF SUBCHONDRAL BONE AND CALCIFIED CARTILAGE IN ADULT HUMAN FEMORAL AND HUMERAL HEADS , 2005 .

[38]  A. Grodzinsky,et al.  Mechanical and physicochemical determinants of the chondrocyte biosynthetic response , 1988, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[39]  D P Fyhrie,et al.  Influences of Mechanical Stress on Prenatal and Postnatal Skeletal Development , 1987, Clinical orthopaedics and related research.

[40]  D P Fyhrie,et al.  Relation of coxarthrosis to stresses and morphogenesis. A finite element analysis. , 1987, Acta orthopaedica Scandinavica.

[41]  R W Mann,et al.  Cartilage stresses in the human hip joint. , 1994, Journal of biomechanical engineering.

[42]  C. Herberhold,et al.  In situ measurement of articular cartilage deformation in intact femoropatellar joints under static loading. , 1999, Journal of biomechanics.

[43]  D. Griffin,et al.  Finite-Element Analysis , 1975 .

[44]  P J Prendergast,et al.  Biophysical stimuli on cells during tissue differentiation at implant interfaces , 1997 .

[45]  J H Heegaard,et al.  Mechanically modulated cartilage growth may regulate joint surface morphogenesis , 1999, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[46]  C. Jacobs,et al.  Mechanisms contributing to fluid‐flow‐induced Ca2+ mobilization in articular chondrocytes , 1999, Journal of cellular physiology.

[47]  H J Kurrat,et al.  The thickness of the cartilage in the hip joint. , 1978, Journal of anatomy.

[48]  F Eckstein,et al.  Age-related changes in the morphology and deformational behavior of knee joint cartilage. , 2001, Arthritis and rheumatism.

[49]  Robert B. Salter,et al.  Skeletal Function and Form. Mechanobiology of Skeletal Development, Aging, and Regeneration. , 2001 .

[50]  P. Bullough,et al.  The vascularity and remodelling of subchondrial bone and calcified cartilage in adult human femoral and humeral heads. An age- and stress-related phenomenon. , 1977, Journal of Bone and Joint Surgery-british Volume.