Your search keyword '"Takahisa Shimazaki"' showing total 3 results

1. Stresses on the cervical column associated with vertical occlusal alteration

Author

Mitsuru Motoyoshi, Mizuki Wada, Takahisa Shimazaki, Shinkichi Namura, and Kohei Hosoi

Subjects

Adult, Male, Finite Element Analysis, Dentistry, Orthodontics, Models, Biological, Bite Force, Stress (mechanics), Dental Occlusion, Column (typography), Occlusal plane, Odontoid Process, medicine, Humans, Computer Simulation, Odontoid process, business.industry, Dental occlusion, Vertical Dimension, Finite element method, Sagittal plane, Biomechanical Phenomena, Bite force quotient, medicine.anatomical_structure, Masticatory Muscles, Cervical Vertebrae, Computer-Aided Design, Mastication, Stress, Mechanical, business, Geology, Malocclusion, Muscle Contraction

Abstract

The biomechanical effects on cervical vertebral columns (C1-C7) during mastication were calculated using a three-dimensional (3D) finite element method. To verify the biomechanical influences of vertical occlusal alteration to the cervical column, three finite element models (FEM) showing a normal (model A), a steep (model B), and a flat occlusal plane (model C) were constructed. The occlusal stress distribution showed various patterns for the three models; the stress extended to the anterior area as the occlusal plane became steeper. The plots of the stresses on the mid sagittal section of the cervical columns showed different patterns for the three models; the stress converged at the odontoid process in models A and B, whereas the stresses at C7 in model B tended to decrease compared with model A. Concentrated stress was observed at C5 in model C, supporting the hypothesis that vertical occlusal alteration could influence stress distribution in the cervical columns.

Published

2003

2. Biomechanical influences of head posture on occlusion: an experimental study using finite element analysis

Author

Tatsuyoshi Sugai, Mitsuru Motoyoshi, Shinkichi Namura, and Takahisa Shimazaki

Subjects

Dental Stress Analysis, Finite Element Analysis, Posture, Dentistry, Orthodontics, Models, Biological, Stress (mechanics), Position (vector), Atlas (anatomy), Occlusion, medicine, Humans, Computer Simulation, Craniofacial, Mathematics, Temporomandibular Joint, business.industry, Viscosity, Finite element method, Elasticity, Masticatory force, Biomechanical Phenomena, medicine.anatomical_structure, Masticatory Muscles, Cervical Vertebrae, Head (vessel), Mastication, business, Head, Malocclusion

Abstract

The biomechanical influences of head posture on the cervical column and craniofacial complex during masticatory simulation were quantified using three‐dimensional (3D) finite element analysis (FEA). Three types of finite element model (FEM) were designed to examine relationships between the position of the head and malocclusion. Model A was constructed to have a standardized cervical column curve, model B a forward inclined posture, and model C a backward inclined posture. The results of the spinal displacements revealed that model B moved in a forward direction and model C in a backward direction during masticatory simulation. The stress distributions on the cervical column (C1–C7) for models A, B, and C showed differences; stress converged at the atlas in model A, high‐level stresses were observed at the spinous processes of C6 and C7 in model C, and the stress converged at the anterior edge in the vertebral body of C4 of model B. Stress distribution on the occlusal plane and maxillofacial structure did not show absolute differences among the three models. Alteration of head posture was directly related to stress distribution on the cervical column, but may not always directly influence the occlusal state.

Published

2002

3. An experimental study on mandibular expansion: increases in arch width and perimeter

Author

Masayuki Hirabayashi, Mitsuru Motoyoshi, Shinkichi Namura, and Takahisa Shimazaki

Subjects

Molar, Dental Stress Analysis, Materials science, Finite Element Analysis, Orthodontics, Mandible, Lateral expansion, Mandibular first molar, Models, Biological, Orthodontics, Corrective, Perimeter, Mandibular second molar, Dental Arch, Imaging, Three-Dimensional, stomatognathic system, Premolar, medicine, Humans, Computer Simulation, Arch, Anatomy, Prognosis, Biomechanical Phenomena, medicine.anatomical_structure, Tooth

Abstract

SUMMARY The purpose of this study was to estimate the increase in arch perimeter associated with mandibular lateral expansion. The mandibular expansion was simulated using a three-dimensional (3D) finite element method (FEM) and a computer graphics technique (3D simulation). The centre of rotation of molars during movement accompanied by lateral expansion was calculated using 3D FEM. The geometry of the model was determined using the mandibular bone of an East Indian skeletal specimen and 1 mm computer tomogram (CT) slices. The 3D set-up simulation was then conducted using 3D computer graphics instead of performing a manual set-up. Rotational movement was induced in the buccal segment, from the first premolar to second molar, in the 3D set-up model around the location of the centre of rotation (4.5 mm below the root apex of the first molar) derived from the FEM. According to 3D simulation, the model showed an opening space of 1.43 mm between the canine and first premolar, and thus a change in arch perimeter of 2.86 mm. The tip of the mesio-lingual cusp of the first molar moved 3.88 mm laterally, resulting in a change in inter-molar width of 7.76 mm. These values mean that a 1 mm increase in arch width resulted in an increase in arch perimeter of 0.37 mm. This result would be of value clinically for prediction of the effects of mandibular expansion.

Published

2002