The morphology of the mouse masticatory musculature

• Published in: Journal of anatomy Vol. 223; no. 1; pp. 46 - 60
• Main Authors: Baverstock, Hester, Jeffery, Nathan S., Cobb, Samuel N.
• Format: Journal Article
• Language: English
• Published: England Wiley Subscription Services, Inc 01.07.2013; John Wiley & Sons, Ltd
• Subjects: Animals; contrast‐enhanced; jaw closing muscles; masseter; Masticatory Muscles - anatomy & histology; Mice; micro‐computed tomography; Models, Anatomic; murine; Mus musculus; muscular anatomy; Original; pterygoid; temporalis; Terminology as Topic; Tomography, X-Ray Computed; Zebrafish
• ISSN: 0021-8782; 1469-7580
• DOI: 10.1111/joa.12059

The mouse has been the dominant model organism in studies on the development, genetics and evolution of the mammalian skull and associated soft‐tissue for decades. There is the potential to take advantage of this well studied model and the range of mutant, knockin and knockout organisms with diverse craniofacial phenotypes to investigate the functional significance of variation and the role of mechanical forces on the development of the integrated craniofacial skeleton and musculature by using computational mechanical modelling methods (e.g. finite element and multibody dynamic modelling). Currently, there are no detailed published data of the mouse masticatory musculature available. Here, using a combination of micro‐dissection and non‐invasive segmentation of iodine‐enhanced micro‐computed tomography, we document the anatomy, architecture and proportions of the mouse masticatory muscles. We report on the superficial masseter (muscle, tendon and pars reflecta), deep masseter, zygomaticomandibularis (anterior, posterior, infraorbital and tendinous parts), temporalis (lateral and medial parts), external and internal pterygoid muscles. Additionally, we report a lateral expansion of the attachment of the temporalis onto the zygomatic arch, which may play a role in stabilising this bone during downwards loading. The data presented in this paper now provide a detailed reference for phenotypic comparison in mouse models and allow the mouse to be used as a model organism in biomechanical and functional modelling and simulation studies of the craniofacial skeleton and particularly the masticatory system.