Simulation of dental collisions and occlusal dynamics in the virtual environment

Summary Semi‐adjustable articulators have often been used to simulate occlusal dynamics, but advances in intra‐oral scanning and computer software now enable dynamics to be modelled mathematically. Computer simulation of occlusal dynamics requires accurate virtual casts, records to register them and...

Full description

Saved in:
Bibliographic Details
Published in:Journal of oral rehabilitation 2016-04, Vol.43 (4), p.269-278
Main Authors: Stavness, I. K., Hannam, A. G., Tobias, D. L., Zhang, X.
Format: Article
Language:English
Subjects:
articulators
Bite Force
collision simu-lation
Computer Simulation
Dental Articulators
Dental Impression Materials
Dental Models
Dental Occlusion
Dentistry
Humans
Image Processing, Computer-Assisted
Jaw Relation Record - methods
Mandible - anatomy & histology
Maxilla - anatomy & histology
occlusal dynamics
Reproducibility of Results
scanners
Software
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Summary Semi‐adjustable articulators have often been used to simulate occlusal dynamics, but advances in intra‐oral scanning and computer software now enable dynamics to be modelled mathematically. Computer simulation of occlusal dynamics requires accurate virtual casts, records to register them and methods to handle mesh collisions during movement. Here, physical casts in a semi‐adjustable articulator were scanned with a conventional clinical intra‐oral scanner. A coordinate measuring machine was used to index their positions in intercuspation, protrusion, right and left laterotrusion, and to model features of the articulator. Penetrations between the indexed meshes were identified and resolved using restitution forces, and the final registrations were verified by distance measurements between dental landmarks at multiple sites. These sites were confirmed as closely approximating via measure‐ments made from homologous transilluminated vinylpolysiloxane interocclusal impressions in the mounted casts. Movements between the indexed positions were simulated with two models in a custom biomechanical software platform. In model DENTAL, 6 degree‐of‐freedom movements were made to minimise deviation from a straight line path and also shaped by dynamic mesh collisions detected and resolved mathematically. In model ARTIC, the paths were further constrained by surfaces matching the control settings of the articulator. Despite these differences, the lower mid‐incisor point paths were very similar in both models. The study suggests that mathematical simulation utilising interocclusal ‘bite’ registrations can closely replicate the primary movements of casts mounted in a semi‐adjustable articulator. Additional indexing positions and appropriate software could, in some situations, replace the need for mechanical semi‐adjustable articulation and/or its virtual representation.
ISSN:0305-182X
1365-2842
DOI:10.1111/joor.12374