Previous dynamic analyses of the temporomandibular joint (TMJ) disc have not included a true preload, i.e., a step stress or strain beyond the initial tare load. However, due to the highly nonlinear stress-strain response of the TMJ disc, we hypothesized that the dynamic mechanical properties would greatly depend on the preload, which could then, in part, account for the large variation in the tensile stiffnesses reported for the TMJ disc in the literature. This study is the first to report the dynamic mechanical properties as a function of prestress. As hypothesized, the storage modulus (E′) of the disc varied by a factor of 25 in the mediolateral direction and a factor of 200 in the anteroposterior direction, depending on the prestress. Multiple constant strain rate sweeps were extracted and superimposed via strain-rate frequency superposition (SRFS), which demonstrated that the strain rate amplitude and strain rate were both important factors in determining the TMJ disc material properties, which is an effect not typically seen with synthetic materials. The presented analysis demonstrated, for the first time, the applicability of viscoelastic models, previously applied to synthetic polymer materials, to a complex hierarchical biomaterial such as the TMJ disc, providing a uniquely comprehensive way to capture the viscoelastic response of biological materials. Finally, we emphasize that the use of a preload, preferably which falls within the linear region of the stress-strain curve, is critical to provide reproducible results for tensile analysis of musculoskeletal tissues. Therefore, we recommend that future dynamic mechanical analyses of the TMJ disc be performed at a controlled prestress corresponding to a strain range of 5–10%.
Issue Section:
Research Papers
References
1.
Kuboki
, T.
, Shinoda
, M.
, Orsini
, M. G.
, and Yamashita
, A.
, 1997
, “Viscoelastic Properties of the Pig Temporomandibular Joint Articular Soft Tissues of the Condyle and Disc
,” J. Dent. Res.
, 76
(11
), pp. 1760
–1769
.10.1177/002203459707601107012.
Beatty
, M. W.
, Bruno
, M. J.
, Iwasaki
, L. R.
, and Nickel
, J. C.
, 2001
, “Strain Rate Dependent Orthotropic Properties of Pristine and Impulsively Loaded Porcine Temporomandibular Joint Disk
,” J. Biomed. Mater. Res.
, 57
(1
), pp. 25
–34
.10.1002/1097-4636(200110)57:1<25::AID-JBM1137>3.0.CO;2-H3.
Tanaka
, E.
, and van Eijden
, T.
, 2003
, “Biomechanical Behavior of the Temporomandibular Joint Disc
,” Crit. Rev. Oral. Biol. Med.
, 14
(2
), pp. 138
–150
.10.1177/1544111303014002074.
Detamore
, M. S.
, and Athanasiou
, K. A.
, 2003
, “Motivation, Characterization, and Strategy for Tissue Engineering the Temporomandibular Joint Disc
,” Tissue Eng.
, 9
(6
), pp. 1065
–1087
.10.1089/107632703607279915.
Detamore
, M. S.
, and Athanasiou
, K. A.
, 2003
, “Structure and Function of the Temporomandibular Joint Disc: Implications for Tissue Engineering
,” J. Oral Maxillofac. Surg.
, 61
(4
), pp. 494
–506
.10.1053/joms.2003.500966.
Beek
, M.
, Koolstra
, J. H.
, van Ruijven
, L. J.
, and van Eijden
, T. M.
, 2000
, “Three-Dimensional Finite Element Analysis of the Human Temporomandibular Joint Disc
,” J. Biomech.
, 33
(3
), pp. 307
–316
.10.1016/S0021-9290(99)00168-27.
Donzelli
, P. S.
, Gallo
, L. M.
, Spilker
, R. L.
, and Palla
, S.
, 2004
, “Biphasic Finite Element Simulation of the TMJ Disc From In Vivo Kinematic and Geometric Measurements
,” J. Biomech.
, 37
(11
), pp. 1787
–1791
.10.1016/j.jbiomech.2004.01.0298.
Tanaka
, E.
, del Pozo
, R.
, Tanaka
, M.
, Asai
, D.
, Hirose
, M.
, Iwabe
, T.
, and Tanne
, K.
, 2004
, “Three-Dimensional Finite Element Analysis of Human Temporomandibular Joint With and Without Disc Displacement During Jaw Opening
,” Med. Eng. Phys.
, 26
(6
), pp. 503
–511
.10.1016/j.medengphy.2004.03.0019.
Koolstra
, J. H.
, 2003
, “Number Crunching With the Human Masticatory System
,” J. Dent. Res.
, 82
(9
), pp. 672
–676
.10.1177/15440591030820090310.
Detamore
, M. S.
, and Athanasiou
, K. A.
, 2003
, “Tensile Properties of the Porcine Temporomandibular Joint Disc
,” ASME J. Biomech. Eng.
, 125
(4
), pp. 558
–565
.10.1115/1.158977811.
Rees
, L. A.
, 1954
, “The Structure and Function of the Mandibular Joint
,” Br. Dent. J.
, 96
(6
), pp. 125
–133
.12.
Athanasiou
, K. A.
, Almarza
, A. J.
, Detamore
, M. S.
, and Kalpacki
, K. N.
, 2009
, Tissue Engineering of Temporomandibular Joint Cartilage
, Morgan and Claypool
, San Rafael, CA.13.
Teng
, S.
, Xu
, Y.
, Cheng
, M.
, and Li
, Y.
, 1991
, “Biomechanical Properties and Collagen Fiber Orientation of TMJ Discs in Dogs: Part 2. Tensile Mechanical Properties of the Discs
,” J. Craniomandib. Disord.
, 5
(2
), pp. 107
–114
.14.
Scapino
, R. P.
, Obrez
, A.
, and Greising
, D.
, 2006
, “Organization and Function of the Collagen Fiber System in the Human Temporomandibular Joint Disk and Its Attachments
,” Cells Tissues Organs
, 182
(3–4
), pp. 201
–225
.10.1159/00009396915.
Tanne
, K.
, Tanaka
, E.
, and Sakuda
, M.
, 1991
, “The Elastic Modulus of the Temporomandibular Joint Disc From Adult Dogs
,” J. Dent. Res.
, 70
(12
), pp. 1545
–1548
.10.1177/0022034591070012140116.
Beek
, M.
, Aarnts
, M. P.
, Koolstra
, J. H.
, Feilzer
, A. J.
, and van Eijden
, T. M.
, 2001
, “Dynamic Properties of the Human Temporomandibular Joint Disc
,” J. Dent. Res.
, 80
(3
), pp. 876
–880
.10.1177/0022034501080003060117.
Tanaka
, E.
, Kawai
, N.
, Hanaoka
, K.
, Van Eijden
, T.
, Sasaki
, A.
, Aoyama
, J.
, Tanaka
, M.
, and Tanne
, K.
, 2004
, “Shear Properties of the Temporomandibular Joint Disc in Relation to Compressive and Shear Strain
,” J. Dent. Res.
, 83
(6
), pp. 476
–479
.10.1177/15440591040830060818.
Tanaka
, E.
, Kikuzaki
, M.
, Hanaoka
, K.
, Tanaka
, M.
, Sasaki
, A.
, Kawai
, N.
, Ishino
, Y.
, Takeuchi
, M.
, and Tanne
, K.
, 2003
, “Dynamic Compressive Properties of Porcine Temporomandibular Joint Disc
,” Eur. J. Oral Sci.
, 111
(5
), pp. 434
–439
.10.1034/j.1600-0722.2003.00066.x19.
Tanaka
, E.
, Aoyama
, J.
, Tanaka
, M.
, Van Eijden
, T.
, Sugiyama
, M.
, Hanaoka
, K.
, Watanabe
, M.
, and Tanne
, K.
, 2003
, “The Proteoglycan Contents of the Temporomandibular Joint Disc Influence Its Dynamic Viscoelastic Properties
,” J. Biomed. Mater. Res. Part A
, 65
(3
), pp. 386
–392
.10.1002/jbm.a.1049620.
Tanaka
, E.
, Aoyama
, J.
, Tanaka
, M.
, Murata
, H.
, Hamada
, T.
, and Tanne
, K.
, 2002
, “Dynamic Properties of Bovine Temporomandibular Joint Disks Change With Age
,” J. Dent. Res.
, 81
(9
), pp. 618
–622
.10.1177/15440591020810090821.
Koolstra
, J. H.
, Tanaka
, E.
, and Van Eijden
, T. M.
, 2007
, “Viscoelastic Material Model for the Temporomandibular Joint Disc Derived From Dynamic Shear Tests or Strain–Relaxation Tests
,” J. Biomech.
, 40
(10
), pp. 2330
–2334
.10.1016/j.jbiomech.2006.10.01922.
Beatty
, M. W.
, Nickel
, J. C.
, Iwasaki
, L. R.
, and Leiker
, M.
, 2003
, “Mechanical Response of the Porcine Temporomandibular Joint Disc to an Impact Event and Repeated Tensile Loading
,” J. Orofac. Pain
, 17
(2
), pp. 160
–166
.23.
Snider
, G. R.
, Lomakin
, J.
, Singh
, M.
, Gehrke
, S. H.
, and Detamore
, M. S.
, 2008
, “Regional Dynamic Tensile Properties of the TMJ Disc
,” J. Dent. Res.
, 87
(11
), pp. 1053
–1057
.10.1177/15440591080870111224.
Fernandez
, P.
, Rey
, M. J. L.
, and Canteli
, A. F.
, 2011
, “Viscoelastic Characterisation of the Temporomandibular Joint Disc in Bovines
,” Strain
, 47
(2
), pp. 188
–193
.10.1111/j.1475-1305.2008.00502.x25.
Lamela
, M. J.
, Fernández
, P.
, Ramos
, A.
, Fernández-Canteli
, A.
, and Tanaka
, E.
, 2013
, “Dynamic Compressive Properties of Articular Cartilages in the Porcine Temporomandibular Joint
,” J. Mech. Behav. Biomed. Mater.
, 23
, pp. 62
–70
.10.1016/j.jmbbm.2013.04.00626.
Tanaka
, E.
, Kawai
, N.
, Van Eijden
, T.
, Watanabe
, M.
, Hanaoka
, K.
, Nishi
, M.
, Iwabe
, T.
, and Tanne
, K.
, 2003
, “Impulsive Compression Influences the Viscous Behavior of Porcine Temporomandibular Joint Disc
,” Eur. J. Oral Sci.
, 111
(4
), pp. 353
–358
.10.1034/j.1600-0722.2003.00049.x27.
Herring
, S. W.
, 2003
, “TMJ Anatomy and Animal Models
,” J. Musculoskeletal and Neuronal Interact.
, 3
(4
), pp. 391
–394
.28.
Herring
, S. W.
, 2003
, “TMJ Anatomy and Animal Models
,” J. Musculoskeletal and Neuronal Interact.
, 3
(4
), pp. 406
–397
.29.
Oloyede
, A.
, Flachsmann
, R.
, and Broom
, N. D.
, 1992
, “The Dramatic Influence of Loading Velocity on the Compressive Response of Articular-Cartilage
,” Connect. Tissue Res.
, 27
(4
), pp. 211
–224
.10.3109/0300820920900699730.
Tanaka
, E.
, Tanaka
, M.
, Aoyama
, J.
, Watanabe
, M.
, Hattori
, Y.
, Asai
, D.
, Iwabe
, T.
, Sasaki
, A.
, Sugiyama
, M.
, and Tanne
, K.
, 2002
, “Viscoelastic Properties and Residual Strain in a Tensile Creep Test on Bovine Temporomandibular Articular Discs
,” Arch. Oral Biol.
, 47
(2
), pp. 139
–146
.10.1016/S0003-9969(01)00096-631.
Chin
, L. P. Y.
, Aker
, F. D.
, and Zarrinnia
, K.
, 1996
, “The Viscoelastic Properties of the Human Temporomandibular Joint Disc
,” J. Oral Maxillofac. Surg.
, 54
(3
), pp. 315
–318
.10.1016/S0278-2391(96)90751-X32.
Tanaka
, E.
, Hanaoka
, K.
, van Eijden
, T.
, Tanaka
, M.
, Watanabe
, M.
, Nishi
, M.
, Kawai
, N.
, Murata
, H.
, Hamada
, T.
, and Tanne
, K.
, 2003
, “Dynamic Shear Properties of the Temporomandibular Joint Disc
,” Int. Am. Assoc. Dent.Res.
, 82
, pp. 228
–231
.10.1177/15440591030820031533.
Singh
, M.
, and Detamore
, M. S.
, 2008
, “Tensile Properties of the Mandibular Condylar Cartilage
,” ASME J. Biomech. Eng.
, 130
(1
), p. 011009
.10.1115/1.283806234.
Allen
, K. D.
, and Athanasiou
, K. A.
, 2005
, “A Surface-Regional and Freeze-Thaw Characterization of the Porcine Temporomandibular Joint Disc
,” Ann. Biomed. Eng.
, 33
(7
), pp. 951
–962
.10.1007/s10439-005-3872-635.
Ferry
, J. D.
, 1980
, Viscoelastic Properties of Polymers
, Wiley
, New York.
36.
Inman
, D. J.
, 2000
, Engineering Vibration
, Prentice-Hall
, Englewood Cliffs, NJ
.37.
Klemuk
, S. A.
, and Titze
, I. R.
, 2004
, “Viscoelastic Properties of Three Vocal-Fold Injectable Biomaterials at Low Audio Frequencies
,” Laryngoscope
, 114
(9
), pp. 1597
–1603
.10.1097/00005537-200409000-0001838.
Mavrilas
, D.
, Sinouris
, E. A.
, Vynios
, D. H.
, and Papageorgakopoulou
, N.
, 2005
, “Dynamic Mechanical Characteristics of Intact and Structurally Modified Bovine Pericardial Tissues
,” J. Biomech.
, 38
(4
), pp. 761
–768
.10.1016/j.jbiomech.2004.05.01939.
Menard
, K. P.
, 1999
, Dynamic Mechanical Analysis: A Practical Introduction
, CRC
, Boca Raton
.40.
Meredith
, N.
, Alleyne
, D.
, and Cawley
, P.
, 1996
, “Quantitative Determination of the Stability of the Implant-Tissue Interface Using Resonance Frequency Analysis
,” Clin. Oral Implants Res.
, 7
(3
), pp. 261
–267
.10.1034/j.1600-0501.1996.070308.x41.
Wang
, T. G.
, Hsiao
, T. Y.
, Wang
, C. L.
, and Shau
, Y. W.
, 2007
, “Resonance Frequency in Patellar Tendon
,” Scand. J. Med. Sci. Sports
, 17
(5
), pp. 535
–538
.10.1111/j.1600-0838.2006.00618.x42.
Park
, S.
, and Ateshian
, G. A.
, 2006
, “Dynamic Response of Immature Bovine Articular Cartilage in Tension and Compression, and Nonlinear Viscoelastic Modeling of the Tensile Response
,” ASME J. Biomech. Eng.
, 128
(4
), pp. 623
–630
.10.1115/1.220620143.
Wyss
, H. M.
, Miyazaki
, K.
, Mattsson
, J.
Hu
, Z. B.
, Reichman
, D. R.
, and Weitz
, D. A.
, 2007
, “Strain-Rate Frequency Superposition: A Rheological Probe of Structural Relaxation in Soft Materials
,” Phys. Rev. Lett.
, 98
(23
), p. 4
.10.1103/PhysRevLett.98.23830344.
Koenderink
, G. H.
, Atakhorrami
, M.
, MacKintosh
, F. C.
, and Schmidt
, C. F.
, 2006
, “High-Frequency Stress Relaxation in Semiflexible Polymer Solutions and Networks
,” Phys. Rev. Lett.
, 96
(13
), p. 138307
.10.1103/PhysRevLett.96.13830745.
Gardel
, M. L.
, Shin
, J. H.
, MacKintosh
, F. C.
, Mahadevan
, L.
, Matsudaira
, P. A.
, and Weitz
, D. A.
, 2004
, “Scaling of F-Actin Network Rheology to Probe Single Filament Elasticity and Dynamics
,” Phys. Rev. Lett.
, 93
(18
), p. 188102
.10.1103/PhysRevLett.93.18810246.
Hoffman
, B. D.
, Massiera
, G.
, and Crocker
, J. C.
, 2005
, “Forced Unfolding of Protein Domains Determines Cytoskeletal Rheology
,” Bull. Am. Phys. Soc.
, 1
, p. 31003
.47.
Kong
, H. J.
, Wong
, E.
, and Mooney
, D. J.
, 2003
, “Independent Control of Rigidity and Toughness of Polymeric Hydrogels
,” Macromolecules
, 36
(12
), pp. 4582
–4588
.10.1021/ma034137w48.
Schwartz
, M. H.
, Leo
, P. H.
, and Lewis
, J. L.
, 1994
, “A Microstructural Model for the Elastic Response of Articular-Cartilage
,” J. Biomech.
, 27
(7
), pp. 865
–873
.10.1016/0021-9290(94)90259-349.
Stokes
, J. R.
, and Frith
, W. J.
, 2008
, “Rheology of Gelling and Yielding Soft Matter Systems
,” Soft Matter
, 4
(6
), pp. 1133
–1140
.10.1039/b719677f50.
Mohan
, P. H.
, and Bandyopadhyay
, R.
, 2008
, “Phase Behavior and Dynamics of a Micelle-Forming Triblock Copolymer System
,” Phys. Rev. E
, 77
(4
), p. 7
.10.1103/PhysRevE.77.04180351.
Tanaka
, E.
, Detamore
, M. S.
, and Mercuri
, L. G.
, 2008
, “Degenerative Disorders of the Temporomandibular Joint: Etiology, Diagnosis, and Treatment
,” J. Dent. Res.
, 87
(4
), pp. 296
–307
.10.1177/154405910808700406Copyright © 2014 by ASME
You do not currently have access to this content.
