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Development of the mandibular curve of spee and maxillary compensating curve: A finite element model
Journal article   Open access   Peer reviewed

Development of the mandibular curve of spee and maxillary compensating curve: A finite element model

Steven D Marshall, Karen Kruger, Robert G Franciscus and Thomas E Southard
PloS one, Vol.14(12), pp.e0221137-e0221137
12/26/2019
DOI: 10.1371/journal.pone.0221137
PMCID: PMC6932755
PMID: 31877131
url
https://doi.org/10.1371/journal.pone.0221137View
Published (Version of record) Open Access

Abstract

The curved planes of the human dentition seen in the sagittal view, the mandibular curve of Spee and the maxillary compensating curve, have clinical importance to modern dentistry and potential relevance to the craniofacial evolution of hominins. However, the mechanism providing the formation of these curved planes is poorly understood. To explore this further, we use a simplified finite element model, consisting of maxillary and mandibular "blocks", developed to simulate tooth eruption, and forces opposing eruption, during simplified masticatory function. We test our hypothesis that curved occlusal planes develop from interplay between tooth eruption, occlusal load, and mandibular movement. Our results indicate that our simulation of rhythmic chewing movement, tooth eruption, and tooth eruption inhibition, applied concurrently, results in a transformation of the contacting maxillary and mandibular block surfaces from flat to curved. The depth of the curvature appears to be dependent on the radius length of the rotating (chewing) movement of the mandibular block. Our results suggest mandibular function and maxillo-mandibular spatial relationship may contribute to the development of human occlusal curvature.
 Multidisciplinary Sciences Science & Technology Science & Technology - Other Topics

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