Andrew Boryor scite author profile

Objective: To evaluate the risk of root resorption, individual finite element models (FEMs) of extracted human maxillary first premolars were created, and the distribution of the hydrostatic pressure in the periodontal ligament (PDL) of these models was simulated. Materials and Methods: A continuous lingual torque of 3 Nmm and 6 Nmm respectively was applied in vivo to the aforementioned teeth. After extraction, FEMs of these double-rooted teeth were created based on high-resolution microcomputed tomographics (micro CT, voxel size: 35 microns). This high volumetric resolution made the recognition of very small resorption lacunae possible. Scanning electron micrographs of the root surfaces were created as well. This enabled the investigation of advantages and disadvantages of the different imaging techniques from the viewpoint of the examination of root resorption. Using the FEMs, the same loading conditions as applied in vivo were simulated. Results:The results of clinical examination and simulations were compared using the identical roots of the teeth. The regions that showed increased hydrostatic pressure (Ͼ0.0047 MPa) correlated well with the locations of root resorption for each tooth. Increased torque resulted in increased high-pressure areas and increased magnitudes of hydrostatic pressure, correlating with the experiments. Conclusion: If hydrostatic pressure exceeds typical human capillary blood pressure in the PDL, the risk of root resorption increases.

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Correspondences of hydrostatic pressure in periodontal ligament with regions of root resorption: A clinical and a finite element study of the same human teeth

Hohmann

Wolfram

Geiger

et al. 2009

Computer Methods and Programs in Biomedicine

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Influence of different modeling strategies for the periodontal ligament on finite element simulation results

Hohmann

Kober

Young

et al. 2011

American Journal of Orthodontics and Dentofacial Orthopedics

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Soft-tissue changes after maxillomandibular advancement surgery assessed with cone-beam computed tomography

Ryckman¹,

Harrison

Oliver

et al. 2010

American Journal of Orthodontics and Dentofacial Orthopedics

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Stress distribution and displacement analysis during an intermaxillary disjunction—A three-dimensional FEM study of a human skull

Boryor

Geiger

Hohmann

et al. 2008

Journal of Biomechanics

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Andrew Boryor

Periodontal Ligament Hydrostatic Pressure with Areas of Root Resorption after Application of a Continuous Torque Moment

Correspondences of hydrostatic pressure in periodontal ligament with regions of root resorption: A clinical and a finite element study of the same human teeth

Influence of different modeling strategies for the periodontal ligament on finite element simulation results

Soft-tissue changes after maxillomandibular advancement surgery assessed with cone-beam computed tomography

Stress distribution and displacement analysis during an intermaxillary disjunction—A three-dimensional FEM study of a human skull

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