Morphological Observation of the Medial Pterygoid Muscle by the Superimposition of Images Obtained by Lateral Cephalogram and MRI

Abstract

Objective

To observe the morphological relationship between the maxillofacial skeleton and medial pterygoid muscle by superimposing images constructed by MRI on a cephalogram.

Design

Cross-sectional study.

Setting

The Departments of Maxillofacial Orthognathics and Orthodontics, Tokyo Medical and Dental University.

Participants

Sixteen patients (5 males and 11 females, aged between 13.5 and 27.5 years) with various craniofacial skeletal patterns, who were about to start orthodontic treatment.

Methods

Lateral cephalometric radiographs and MRI scans were obtained and their images uploaded to a computer using a digitizer. The area of the medial pterygoid muscle was selected by binarization from the MRI. The mid-sagittal-plane MRI with a complete superimposed sagittal image of the medial pterygoid muscle was superimposed on the cephalogram using anatomical structures situated in the mid-sagittal plane of the head and shapes that could be identified from both the radiograph and the MRI image.

Results

These combined images showed various shapes of the medial pterygoid muscle. The inclination axis of the medial pterygoid muscle was correlated with various cephalometric variables including SNB (r=0.658), Facial angle (r=0.601), ramus inclination (r=0.676) and Ba-Po% (r=0.585).

The volume of the medial pterygoid muscle was also correlated with cephalometric variables such as ramus inclination (r=0.453), Ba-Nmm (r=0.676), Ba-Po% (depth) (r=0.447), Ar-Go% (depth) (r=0.444) and Ar-Go% (actual length) (r=0.532).

Conclusions

Morphometric analysis using a superimposed image of the medial pterygoid muscle produced from a cephalogram and MRI may help explain the influence of the medial pterygoid muscle inclination axis and volume on the shape of the mandibular bone, especially the shape of the ramus.

Keywords

Medial pterygoid muscle MRI cephalogram superimposition ramus

Get full access to this article

View all access options for this article.

References

Weijs

, Hillen

Relationships between masticatory muscle cross-section and skull shape. J Dent Res 1984; 63:1154–57.

Weijs

Hillen

Correlations between the cross-sectional area of the jaw muscles and craniofacial size and shape. Am J Phys Anthropol 1986; 70:423–31.

Gionhaku

, Lowe

Relationship between jaw muscle volume and craniofacial form. J Dent Res 1989; 68:805–09.

Benington

, Gardener

, Hunt

Masseter muscle volume measured using ultrasonography and its relationship with facial morphology. Eur J Orthod 1999; 21:659–70.

Ota

, Yotsui

, Kawamoto

Relationship between craniofacial morpohology and the volume and inclination of the medial pterygoid muscle. Shika Igaku (J Osaka Odontol Soc) 2006; 69(1): 1–8.

van Spronsen

, Koolstra

, van Ginkel

, Weijs

, Valk

, Prahl-Anderson

Relationships between the orientation and moment arms of the human jaw muscles and normal craniofacial morphology. Eur J Orthod 1997; 19 (3): 313–28.

van Spronsen

, Weijs

, Valk

, Prahl

Andersen B

, van Ginkel

. Relationships between jaw muscle cross-sections and craniofacial morphology in normal adults, studied with magnetic resonance imaging. Eur J Orthod 1991; 13: 351–61.

Hannam

, Wood

Relationships between the size and spatial morphology of human masseter and medial pterygoid muscles, the craniofacial skeleton, and jaw biomechanics. Am J Phys Anthropol 1989; 80:429–45.

van Spronsen

, Weijs

, Valk

, Prahl-Andersen

, van Ginkel

. A comparison of jaw muscle cross-sections of long-face and normal adults. J Dent Res 1992; 71(6): 1279–85.

10.

van Spronsen

, Weijs

, Valk

, Prahl-Andersen

, van Ginkel

. Comparison of jaw-muscle bite-force cross-sections obtained by means of magnetic resonance imaging and high-resolution CT scanning. J Dent Res 1989; 68(12): 1765–70.

11.

Goto

, Yahagi

, Nakamura

, Tokumori

, Langenbach

GEJ

, Yoshiura

In vivo cross-sectional area of human jaw muscles varies with section location and jaw position. J Dent Res 2005; 84(6): 570–75.

12.

, Yuasa

, Yoshiura

, Kanda

Quantitative analysis of masticatory muscles using computed tomography. Dentomaxillofac Radiol 1994; 23:154–58.

13.

Higashino

Relationship between jaws and the masseter muscle by superimposing MR images on the cephalogram. Kokubyo Gakkai Zasshi 2006; 73(1): 116–24.

14.

Koolstra

, van Eijden

TMGJ

, van Spronsen

, Weijs

, Valk

Computer-assisted estimation of lines of action of human masticatory muscles reconstructed in vivo by means of magnetic resonance imaging of parallel sections. Arch Oral Biol 1990; 35:549–56.

15.

Hsu

, Shiau

, Chen

, Liu

Measurement of the size and orientation of human masseter and medial pterygoid muscles. Proc Natl Sci Counc Repub China B 2001; 25(1): 45–49.

16.

Sasaki

, Hannam

, Wood

Relationships between the size, position, and angulation of human jaw muscles and unilateral first molar bite force. J Dent Res 1989; 68(3): 499–503.

17.

Goto

, Nishida

, Yahagi

, Size and orientation of masticatory muscles in patients with mandibular laterognathism. J Dent Res 2006; 85(6): 552–56.

18.

van Spronsen

, Weijs

, van Ginkel

, Prahl

Andersen B.

Jaw muscle orientation and moment arms of long-face and normal adults. J Dent Res 1996; 75(6): 1372–80.

19.

, Chen

The volume of muscles of mastication in patients receiving mandibular contouring surgery: a comparative study. J Plast Reconstr Aesthet Surg 2007; 60(2): 125–29.

20.

Lamey

, Burnett

, Fartash

, Clifford

, McGovern

Migraine and masticatiory muscle volume, bite force, and craniofacial morphology. Headache 2001; 41(1): 49–56.

21.

Goto

, Tokumori

, Nakamura

, Volume changes in human masticatory muscles between jaw closing and opening. J Dent Res 2002; 81:428–32.

22.

, Mardini

, Chen

Volumetric change in the muscles of mastication following resection of mandibular angles: a long-term follow up. Ann Plas Surg 2005; 54:615–21.

23.

Boom

HPW

, van Spronsen

, van Ginkel

, van Schijndel

, Castelijns

, Tuinzing

. A comparison of human jaw muscle cross-sectional area and volume in long-and short-face subjects, using MRI. Arch Oral Biol 2008; 53 (3): 273–81.

24.

Chan

, Woods

, Stella

Mandibular muscle morphology in children with different vertical facial patterns: a 3-dimensional computed tomography study. Am J Orthod Dentofacial Orthop 2008; 133(1): 10e1–13.

25.

Newton

, Abel

, Robertson

, Yemm

Changes in human masseter and medial pterygoid muscles with age: a study by computed tomography. Gerodontics 1987; 3:151–54.

26.

Dicker

, van Spronsen

, van Ginkel

, Adaptation of jaw closing muscles after surgical mandibular advancement procedures in different vertical craniofacial types: a magnetic resonance imaging study. Oral Surg Oral Med Oral Pathol Oral Radiol Endod 2007; 103:475–82.

27.

Kitai

, Fuji

, Murakami

, Furukawa

, Kreiborg

, Takada

Human masticatory muscle volume and zygomatico-mandibular form in adults with mandibular prognathism. J Dent Res 2002; 81(11): 752–56.

28.

Fukui

, Takdokoro

, Himuro

, Yamaguchi

, Ohno

Postoperative evaluation of mandibular prognathism corrected by sagittal splitting osteotomy. Nippon Kyosei Shika Gakkai Zasshi 1989; 48(1): 48–58.