A 3D computer-aided design system applied to diagnosis and treatment planning in orthodontics and orthognathic surgery.

The purpose of this article is to describe a newly developed 3D computer-aided design (CAD) system for the diagnostic set-up of casts in orthodontic diagnosis and treatment planning, and its preliminary clinical applications. The system comprises a measuring unit which obtains 3D information from the dental model using laser scanning, and a personal computer to generate the 3D graphics. When measuring the 3D shape of the model, to minimize blind sectors, the model is scanned from two different directions with the slit-ray laser beam by rotating the mounting angle of the model on the measuring device. For computed simulation of tooth movement, the representative planes, defined by the anatomical reference points, are formed for each individual tooth and are arranged along a guideline descriptive of the individual arch form. Subsequently, the 3D shape is imparted to each of the teeth arranged on the representative plane to form an arrangement of the 3D profile. When necessary, orthognathic surgery can be simulated by moving the mandibular dental arch three-dimensionally to establish the optimum occlusal relationship. Compared with hand-made set-up models, the computed diagnostic cast has advantages such as high-speed processing and quantitative evaluation on the amount of 3D movement of the individual tooth relative to the craniofacial plane. Trial clinical applications demonstrated that the use of this system facilitated the otherwise complicated and time-consuming mock surgery for treatment planning in orthognathic surgery.

[1]  M Okada,et al.  [Statistical and dynamic analysis of dental arch form in adult human with normal occlusion]. , 1974, [Osaka Daigaku shigaku zasshi] The journal of Osaka University Dental Society.

[2]  J. Scott,et al.  The Shape of the Dental Arches , 1957, Journal of dental research.

[3]  K. H. Lu An orthogonal analysis of the form, symmetry and asymmetry of the dental arch. , 1966, Archives of oral biology.

[4]  F Duret,et al.  CAD-CAM in dentistry. , 1988, Journal of the American Dental Association.

[5]  Yoshinobu Maeda,et al.  A CAD/CAM System for Removable Dentures. Part 1. A System for Complete Denture Fabrication. , 1993 .

[6]  L. F. Mills,et al.  EPIDEMIOLOGICAL STUDIES OF MALALIGNMENT, A METHOD FOR COMPUTING DENTAL ARCH CIRCUMFERENCE. , 2009, The Angle orthodontist.

[7]  S H Pepe,et al.  Polynomial and catenary curve fits to human dental arches. , 1975, Journal of dental research.

[8]  A. Burdi,et al.  A catenary analysis of the maxillary dental arch during human embryogenesis , 1966, The Anatomical record.

[9]  F. Barbakow,et al.  Chairside computer-aided direct ceramic inlays. , 1989, Quintessence international.

[10]  T Kuroda,et al.  Three-dimensional dental cast analyzing system using laser scanning. , 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.

[11]  C. A. Hawley Determination of the normal arch, and its application to orthodontia , 1905 .

[12]  T Kuroda,et al.  [High accuracy measuring device for dental cast--using device with flat laser beam]. , 1992, Kokubyo Gakkai zasshi. The Journal of the Stomatological Society, Japan.

[13]  G. Izard,et al.  New method for the determination of the normal arch by the function of the face , 1927 .

[14]  J H Currier,et al.  A computerized geometric analysis of human dental arch form. , 1969, American journal of orthodontics.