Biomechanical behaviour of bovine temporomandibular articular discs with age.

The purpose was to evaluate age-associated changes in the creep and restoration properties of bovine temporomandibular joint (TMJ) discs under and after sustained tensile stress. Forty discs were obtained from 7- and 10-year-old cattle, referred to as the adult and mature adult groups, respectively. Tension of 1.0 MPa was applied and sustained for 20 min to specimens from ten right discs and of 1.5 MPa to specimens from ten left discs. After the period of tension for the study of creep, the specimens were removed from the tension devices and their restoration observed for 20 min. For comparative purposes the relevant results for a young adult group were recruited from data on 3-year-old bovine TMJ discs reported in a previous study on viscoelastic properties. In all the specimens the time-dependent creep curves showed a marked change in strain during the initial 5 s, but the elastic moduli at the onset of stress were significantly larger in the mature adult group than in the other groups. After 20-min creep, the strains were decreased in relation to the age of the specimen and were significantly smaller in the mature adult than in the young adult. With regard to regional differences, the medial specimens exhibited significantly smaller strains than the central ones in all three age groups. Furthermore, the residual strains after 20-min restoration also decreased slightly with age. It is concluded that the bovine TMJ disc becomes stiff and acquires the capacity to recover from continuous deformation during growth and maturation. These findings suggest that the TMJ disc can modify its viscoelasticity in order to withstand extrinsic functional stresses.

[1]  Van C. Mow,et al.  Is the Nucleus Pulposus a Solid or a Fluid? Mechanical Behaviors of the Nucleus Pulposus of the Human Intervertebral Disc , 1996, Spine.

[2]  W. Cook,et al.  Mechanical properties of some polymer materials used for tooth positioners. , 1994, Australian dental journal.

[3]  E. Tanaka,et al.  The Elastic Modulus of the Temporomandibular Joint Disc from Adult Dogs , 1991, Journal of dental research.

[4]  Shu Chien,et al.  Handbook of Bioengineering , 1986 .

[5]  Y. Nakagawa,et al.  Calcifications of the disc of the temporomandibular joint. , 2008, Journal of oral pathology & medicine : official publication of the International Association of Oral Pathologists and the American Academy of Oral Pathology.

[6]  P. Canham,et al.  The behaviour of collagen fibres in stress relaxation and stress distribution in the jaw-joint disc of rabbits. , 1996, Archives of oral biology.

[7]  J. Burch,et al.  Evaluation of shear stress of the human temporomandibular joint disc. , 1998, Journal of orofacial pain.

[8]  M. Kido,et al.  Postnatal development of substance P-, calcitonin gene-related peptide- and neuropeptide Y-like immunoreactive nerve fibres in the synovial membrane of the rat temporomandibular joint. , 1996, Archives of oral biology.

[9]  H. Vogel Influence of maturation and aging on mechanical and biochemical properties of connective tissue in rats , 1980, Mechanisms of Ageing and Development.

[10]  G E Kempson,et al.  Mechanical properties of articular cartilage. , 1972, The Journal of physiology.

[11]  Savio Lau-Yuen Woo,et al.  Frontiers in Biomechanics , 1986, Springer New York.

[12]  Viscoelastic properties of canine temporomandibular joint disc in compressive load-relaxation. , 1999, Archives of oral biology.

[13]  E. Tanaka,et al.  Mechanical properties of human articular disk and its influence on TMJ loading studied with the finite element method. , 2001, Journal of oral rehabilitation.

[14]  T. Kuboki,et al.  Viscoelastic Properties of the Pig Temporomandibular Joint Articular Soft Tissues of the Condyle and Disc , 1997, Journal of dental research.

[15]  A Oloyede,et al.  The dramatic influence of loading velocity on the compressive response of articular cartilage. , 1992, Connective tissue research.

[16]  E H Burger,et al.  Mechanical stress and osteogenesis in vitro , 1992, Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research.

[17]  P. Staple Advances in oral biology , 1964 .

[18]  R. F. Ker,et al.  Fatigue quality of mammalian tendons. , 2000, The Journal of experimental biology.

[19]  M. Kido,et al.  Postnatal development of protein gene product 9.5‐ and calcitonin gene‐related peptide‐like immunoreactive nerve fibers in the rat temporomandibular joint , 1996, The Anatomical record.

[20]  S. Woo,et al.  Biomechanics of Tendons and Ligaments , 1986 .

[21]  H. Amstutz,et al.  Canine tendon studies. II. Biomechanical evaluation of normal and regrown canine tendons. , 1976, Journal of biomedical materials research.

[22]  P. Scott,et al.  Changes in the chemical composition of the bovine temporomandibular joint disc with age. , 1996, Archives of oral biology.

[23]  P. Westesson,et al.  Morphologic changes in the temporomandibular joint in different age groups. An autopsy investigation. , 1994, Oral surgery, oral medicine, and oral pathology.