Three-dimensional mechanical environment of orthodontic tooth movement and root resorption.

INTRODUCTION The tension-compression theory of bone mechanotransduction is ubiquitous in orthodontics. However, partly due to deficiencies in the characterization of the mechanical environment, there is no consensus on the mechanisms that link stimuli to root resorption and bone response. In this study, we analyzed the predominant directions of tension and compression in the alveolar structures. METHODS An idealized tooth model was constructed with computer-aided design for finite element stress analysis. The principal stress magnitudes and directions were calculated in tipping and translation. RESULTS The highest principal stress magnitudes in the root, periodontal ligament (PDL), and alveolar surface occurred predominantly in the longitudinal, radial, and hoop directions, respectively. On the compression side, the only structure consistently in compression in all directions was the PDL; however, magnitudes were different in different directions. CONCLUSIONS In the same region of root, PDL, and bone, there can be compression in 1 structure and tension in another. At a given point in a structure, compression and tension can coexist in different directions. Magnitudes of compression and tension are typically different in different directions. Because of direction swaps between principal stresses, previously published data of only stress magnitude plots can be confusing and perhaps impossible to understand or correlate with biological responses. To prevent ambiguities, a reference to a principal stress should include not only the structure, but also its predominant direction. Combined stress magnitude and direction results suggest that the PDL is the initiator of mechanotransduction.

[1]  Wai-Fah Chen,et al.  Handbook of Structural Engineering , 1997 .

[2]  A Natali,et al.  Viscoelastic Response of the Periodontal Ligament: An Experimental–Numerical Analysis , 2004, Connective tissue research.

[3]  Alexander G Robling,et al.  Biomechanical and molecular regulation of bone remodeling. , 2006, Annual review of biomedical engineering.

[4]  B Melsen,et al.  Tissue reaction to orthodontic tooth movement--a new paradigm. , 2001, European journal of orthodontics.

[5]  R Viecilli,et al.  Optimization of μCT data processing for modelling of dental structures in orthodontic studies , 2007, Computer methods in biomechanics and biomedical engineering.

[6]  J Cobo,et al.  Dentoalveolar stress from bodily tooth movement at different levels of bone loss. , 1996, American journal of orthodontics and dentofacial orthopedics : official publication of the American Association of Orthodontists, its constituent societies, and the American Board of Orthodontics.

[7]  C Bourauel,et al.  Determination of the centre of resistance in an upper human canine and idealized tooth model. , 1999, European journal of orthodontics.

[8]  N. Brezniak,et al.  Orthodontically induced inflammatory root resorption. Part I: The basic science aspects. , 2009, The Angle orthodontist.

[9]  R P Franke,et al.  [Experiments to determine the time dependent material properties of the periodontal ligament]. , 2002, Biomedizinische Technik. Biomedical engineering.

[10]  Werner Götz,et al.  Correlation of stress and strain profiles and the distribution of osteoclastic cells induced by orthodontic loading in rat. , 2004, European journal of oral sciences.

[11]  K. Otsuka,et al.  Optimal compressive force induces bone formation via increasing bone sialoprotein and prostaglandin E(2) production appropriately. , 2005, Life sciences.

[12]  T R Katona,et al.  Stress analysis of bone modeling response to rat molar orthodontics. , 1995, Journal of biomechanics.

[13]  C. Provatidis,et al.  Numerical Estimation of the Centres of Rotation and Resistance in Orthodontic Tooth Movement. , 1999, Computer methods in biomechanics and biomedical engineering.

[14]  J. Nickel,et al.  Speed of tooth movement is related to stress and IL-1 gene polymorphisms. , 2006, American journal of orthodontics and dentofacial orthopedics : official publication of the American Association of Orthodontists, its constituent societies, and the American Board of Orthodontics.

[15]  C. Provatidis,et al.  A comparative FEM-study of tooth mobility using isotropic and anisotropic models of the periodontal ligament. Finite Element Method. , 2000, Medical engineering & physics.

[16]  R. Viecilli Self-corrective T-loop design for differential space closure. , 2006, American journal of orthodontics and dentofacial orthopedics : official publication of the American Association of Orthodontists, its constituent societies, and the American Board of Orthodontics.

[17]  M. Yamaguchi,et al.  Cathepsins B and L Increased during Response of Periodontal Ligament Cells to Mechanical Stress In Vitro , 2004, Connective tissue research.

[18]  Jie Chen,et al.  Complete orthodontic load systems on teeth in a continuous full archwire: the role of triangular loop position. , 2007, American journal of orthodontics and dentofacial orthopedics : official publication of the American Association of Orthodontists, its constituent societies, and the American Board of Orthodontics.

[19]  B. Epker,et al.  Correlation of Bone Resorption and Formation with the Physical Behavior of Loaded Bone , 1965, Journal of dental research.

[20]  A. Martin Schwarz,et al.  Tissue changes incidental to orthodontic tooth movement , 1932 .

[21]  R. Stubley The influence of transseptal fibers on incisor position and diastema formation. , 1976, American journal of orthodontics.

[22]  P. Vig Orthodontics, current principles and techniques , 1985 .

[23]  Y. Nishijima,et al.  Levels of RANKL and OPG in gingival crevicular fluid during orthodontic tooth movement and effect of compression force on releases from periodontal ligament cells in vitro. , 2006, Orthodontics & craniofacial research.

[24]  K. Reitan The initial tissue reaction incident to orthodontic tooth movement as related to the influence of function; an experimental histologic study on animal and human material. , 1951, Acta odontologica Scandinavica. Supplementum.

[25]  E. Chan,et al.  Physical properties of root cementum: part 7. Extent of root resorption under areas of compression and tension. , 2006, American journal of orthodontics and dentofacial orthopedics : official publication of the American Association of Orthodontists, its constituent societies, and the American Board of Orthodontics.

[26]  Y Zilberman,et al.  Osseous adaptation to continuous loading of rigid endosseous implants. , 1984, American journal of orthodontics.

[27]  Sarandeep S. Huja,et al.  Bone modeling: biomechanics, molecular mechanisms, and clinical perspectives , 2004 .

[28]  D. Zaffe,et al.  Histomorphometric study of bone reactions during orthodontic tooth movement in rats. , 1999, Bone.

[29]  N. Brezniak,et al.  Orthodontically induced inflammatory root resorption. Part II: The clinical aspects. , 2009, The Angle orthodontist.

[30]  T R Katona,et al.  The influence of PDL principal fibers in a 3-dimensional analysis of orthodontic tooth movement. , 2001, American journal of orthodontics and dentofacial orthopedics : official publication of the American Association of Orthodontists, its constituent societies, and the American Board of Orthodontics.

[31]  Vinod Krishnan,et al.  Cellular, molecular, and tissue-level reactions to orthodontic force. , 2006, American journal of orthodontics and dentofacial orthopedics : official publication of the American Association of Orthodontists, its constituent societies, and the American Board of Orthodontics.

[32]  C J Burstone,et al.  Centers of rotation with transverse forces: an experimental study. , 1991, American journal of orthodontics and dentofacial orthopedics : official publication of the American Association of Orthodontists, its constituent societies, and the American Board of Orthodontics.

[33]  A. Kuijpers-Jagtman,et al.  Optimum force magnitude for orthodontic tooth movement: a systematic literature review. , 2009, The Angle orthodontist.

[34]  B. Melsen,et al.  The Finite Element Method: a Tool to Study Orthodontic Tooth Movement , 2005, Journal of dental research.

[35]  J. Argüelles,et al.  Initial stress induced in periodontal tissue with diverse degrees of bone loss by an orthodontic force: tridimensional analysis by means of the finite element method. , 1993, American journal of orthodontics and dentofacial orthopedics : official publication of the American Association of Orthodontists, its constituent societies, and the American Board of Orthodontics.

[36]  Jiliang Li,et al.  The P2X7 Nucleotide Receptor Mediates Skeletal Mechanotransduction* , 2005, Journal of Biological Chemistry.

[37]  S. Baumrind,et al.  A reconsideration of the propriety of the "pressure-tension" hypothesis. , 1969, American journal of orthodontics.

[38]  C. Bourauel,et al.  [Numerical study of tension and strain distribution around rat molars]. , 2003, Biomedizinische Technik. Biomedical engineering.

[39]  P. Turley,et al.  Three-dimensional finite element analysis of stress in the periodontal ligament of the maxillary first molar with simulated bone loss. , 2001, American journal of orthodontics and dentofacial orthopedics : official publication of the American Association of Orthodontists, its constituent societies, and the American Board of Orthodontics.

[40]  Christina Dorow,et al.  Development of a Model for the Simulation of Orthodontic Load on Lower First Premolars Using the Finite Element Method , 2005, Journal of Orofacial Orthopedics / Fortschritte der Kieferorthopädie.