81

Mandibular morphology of the Mongoloid race in Medan according 
to age groups

Maria Sitanggang and Trelia Boel
Department of Oral and Maxillofacial Radiology,
Faculty of Dentistry, Universitas Sumatera Utara
Medan - Indonesia

abstract

Background: The mandible constitutes part of the craniofacial bone that plays an important role in determining an individual’s 
facial profile. The mandible grows and develops throughout life from the prenatal phase up to old age when it becomes and edentulous. 
Changes in the mandible can be measured using radiographs. These establish several parameters of mandibular morphology, including: 
ramus height, condylion height, body length, condylion angle, symphysis height, symphysis width and symphysis angle. Purpose: This 
study aimed to determined differences in the mandibular morphology of members of the mongoloid racial group in Medan according to 
age as measured by cephalometric radiography. Methods: This investigation constituted analytical research using cross-sectional study 
with a total sample of 150 individuals divided according to age: group 1 (aged 4-12 years), group 2 (aged 13-24 years, group 3 (aged 
25-34 years), group 4 (aged 35-60 years) and group of 5 (aged > 60 years). The parameters were computerized by means of a digital 
cephalometric radiograph, the resulting data being analized with one-way ANOVA and LSD. Results: The mean value of the highest 
to the lowest ramus height, and symphysis height from the five age groups, sequentially, were in group 3, group 4, group 5, group 2, 
and group 1. The mean value from the highest to the lowest of body length, condylion height, condylion angle, and symphysis width, 
sequentially, were in group 3, group 4, group 2, group 5, and group 1. The mean value from the highest to the lowest of symphysis 
angle, sequentially, were in group 1, group 3, group 4, group 2, and  group 5. Conclusion: The mandibular morphology of each age 
group differs in Mongoloid races in Medan based on lateral cephalometric radiography in which changes are may be affected by the 
state of teeth and age.

Keywords: mandibular morphology; cephalometric radiograph; age group

Correspondence: Maria Sitanggang, Department of Oral and Maxillofacial Radiology, Faculty of Dentistry, Universitas Sumatera 
Utara, Jl. Alumni no. 2, Kampus USU, Medan 40132, Indonesia. E-mail: manaomi79@gmail.com

Dental Journal
(Majalah Kedokteran Gigi)

2018 June; 51(2): 81–85

Research Report

introduction

The mandible is a part of the body that can be used in 
determining race, sex and age of an individual.1,2 Skeletal 
anomalies that often occur are not only caused by the 
condition of the teeth, but also because of mandibular 
anomalies.3 In dentistry, especially orthodontics, the 
mandible is used to determine a person's facial profile. 
In prosthodontics, particularly in edentulous patients, the 
determination of vertical dimension is influenced by the 
maxillary, mandibular, temporomandibular joints and 
masticatory muscles.4

Growth and development that begins at childbirth 
and continues into old age will produce changes in the 

mandible. Research on growth and development has been 
widely conducted, indicating that the most rapid and intense 
changes occurs during infancy and childhood. Mandibular 
vertical growth occurs through bone remodelling along 
with alveolar process development and dental eruption. 
Posterior borders of the condyle and ramus are very 
active in mandible growth with new bone deposition and 
remodelling, while the anterior surface undergoes bone 
resorption.5

The ramus height, condyle height, condyle angle, 
mandible length (overall length) and condylion angle are all 
parameters that undergo changes in the shape and the size of 
the growing and developing mandible.6–9 After the first year 
of life, mandibular growth is more selective.10 According to 

DOI: 10.20473/j.djmkg.v51.i2.p81–85

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
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82Sitanggang and Boel/Dent. J. (Majalah Kedokteran Gigi) 2018 June; 51(2): 81–85

Enlow and Harris who conducted a study of 25 mandibles 
in children aged 4-12 years, the lingual and buccal cortex of 
the condyle neck is formed by the endosteal bone. The size 
of the gonial angle is reduced (140°) to provide additional 
space for permanent teeth formation. The coronoid process 
will experience movement through the periosteal bone 
incision that occurs continuously. At the age of 5-6 years, 
growth of the ramus and mandibular bodies is believed to 
occur mainly in parallel with changes in the midface. The 
growth of the ramus increases anteroposteriorally, in that 
vertical growth in the ramus is associated with maxillary 
growth and maxillary teeth eruption. Liu et al.6 conducted 
a study of the size of the mandible from the first 6 months 
until the fifth year of a person’s life. The condyle, posterior 
ramus, inferior ramus, gonion, posterior body and point "B" 
will change more in the superior and posterior.6

In general, edentulism affect both general and oral 
health which, in turn, will influence quality of life. Several 
studies conducted on the mandible suggest that there are 
morphological and anatomical changes between dentate 
and edentulous individuals.11,12 Changes in the structure 
and function of the masticatory muscles in edentulous 
individuals due to old age, indicate a decrease in activity 
and muscle density rather than individuals who have lost 
all their teeth.9 

This study was conducted to determine differences 
in the mandibular morphology of Mongoloid individuals 
in Medan according to age as identified by means of 
cephalometric radiography. Several parameters of 
morphology mandibular are ramus height, condylion height, 
body length, condylion angle, symphysis height, symphysis 
width and symphysis angle. 

materials and methods

This analytical research was conducted using cross-
sectional design and carried out at the Unit of Oral-
Maxillofacial Radiology, Faculty of Dentistry, Universitas 
Sumatera Utara. The research population consisted of 
members of three successive generations of the Mongoloid 
race in Medan, divided into groups of 30 individuals. 

A sample selection method was applied by purposive 
sampling method adhering to fulfilled inclusion and 
exclusion criteria. Inclusion criteria: Group 1 (age 4-12 
years): in primary dentition phase: complete primary 
dentition and never having undergone orthodontic treatment 
during the mixed dentition period: there is no premature 
loss of deciduous teeth, no permanent teeth are missing, 
dentures are not employed and orthodontic treatment has 
never been applied. Group 2 (age 13-24 years): dentures 
are not employed, and orthodontic treatment has never 
been applied. During the mixed dentition period, there is 
no premature loss of deciduous teeth, and no permanent 
teeth are missing. During the permanent dentition period, 
the teeth are complete (28 teeth with the exception of the 
third molars). Group 3 (age 25-34 years): the teeth are 

complete (28 teeth with the exception of the third molars) 
and orthodontic treatment has never been applied. Group 
4 (35-60 years): the teeth are complete (28 teeth with the 
exception of the third molars) and orthodontic treatment 
has never been applied. Group 5 (aged >60 years): fully 
edentulous and orthodontic treatment has never been 
applied.

Exclusion criteria: has suffered from and/or received 
treatment for systemic diseases, has undergone jaw surgery, 
odontectomy, has suffered from micrognathia, pathological 
conditions in the mandible, still possesses deciduous teeth, 
has experienced deep caries with exposure of the pulp and 
crown loss, has received treatment of the full crown or 
space maintainer/space regainer. 

After completing the informed consent form, a lateral 
digital cephalometric radiograph (2D) was taken for each 
sample using an Instrumentarium Orthopantomograph 
model QC 200 D 1-4-1, 2012.  The parameters were 
computerized by a digital cephalometric radiograph 
(Figure. 1). A one-way ANOVA test was performed to 
analyze the calculated data with p<0.05. Ethical clearance 
was obtained from the Research Ethics Committees of the 
Faculty of Medicine, Universitas Sumatera Utara No. 345/
TGL/KEPK FK USU-RSUP HAM/2017.

results

The results of the normality test using a one-sample 
Kolmogorov-Smirnov Test confirmed that the variables are 
normally distributed with p>0.05. Table 1 shows the mean 
values and significant differences (Multiple Comparison 
LSD Test result) of all variables  (ramus height, symphysis 
height, body length, condylion height, condylion angle, 
symphysis width and symphysis angle) in five age groups 
(p value <0.05). The mean value of ramus height and 
symphysis height sequentially from the highest to the lowest 
were in group 3, group 4, group 5, group 2 and group 1. The 
mean value of body length, condylion height, condylion 
angle and symphysis width sequentially from the highest 
to the lowest  were in group 3, group 4, group 2, group 
5 and group 1. The mean value of the symphysis angle 
sequentially from the highest to the lowest were in group 
1, group 3, group 4, group 2, and group 5. 

discussion

In this study, the average values of the ramus and 
symphisis height of the five age groups showing the mean 
value sequentially from the highest to the lowest as follows:  
group 3, group 4, group 5, group 2 and group 1. There was 
a significant difference in ramus and symphisis height 
between group 1 and the other groups. After birth, the 
mandibular body gradually extends towards the horizontal 
especially behind the foramen mentale to produce a site 
for three permanent teeth. Meanwhile, the high vertical 

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v51.i2.p81–85

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83 Sitanggang and Boel/Dent. J. (Majalah Kedokteran Gigi) 2018 June; 51(2): 81–85

Table 1. The mean value of the result of the measurement of mandibular morphological parameters

Mandibular 
morphological 

parameters
Groups Mean ± SD

Post Test LSD 

Group 1 Group 2 Group 3 Group 4 Group 5

Ramus height
(Ar-Go)

1 40.973± 3.599 .000* .000* .000*  .000*

2 48.803±4.020 .000* .094 .614 .903

3 51.010±6.828 .000* .094 .241 .121

4 49.467±5.728 .000* .614 .241 .702

5 48.963±4.512 .000* .903 .121 .702

Condylion height 
(Co-Ar)

1 8.163±1.854 .005* .000* .000* .315

2 9.420±1.516 .005* .004* .260 .065

3 11.143±2.484 .000* .004* .072 .000*

4 10.103±2.260 .000* .260 .072 .003*

5 8.547±1.500 .315 .065 .000* .003*

Body length
(Go-Gn)

1 67.373±4.078 .000* .000* .000* .000*

2 75.437±4.467 .000* .000* .193 .705 

3 80.037±4.162 .000* .000* .008* .000*

4 76.940±4.852 .000* .193 .008* .094

5 75.000±4.674 .000* .705 .000* .094

Condylion Angle
(Go-Co-Me)

1 33.917±3.006 .000* .000* .000* .050*

2 37.150±3.116 .000* .234 .784 .061

3 38.150±2.949 .000* .234 .359 .002

4 37.380±3.698 .000* .784 .359 .032*

5 35.570±3.366 .050* .061 .002 .032*

Symphysis height

1 12.893±1.638 .000* .000* .000* .000*

2 17.343±1.899 .000* .049* .329 .826

3 18.337±2.274 .000* .049* .316 .079

4 17.833±2.090 .000* .329 .316 .449

5 17.453±1.711 .000* .826 .079 .449

Symphysis 
width

1 12.813±1.513 .011* .000* .001* .153

2 13.747±1.590 .011* .001* .503 .256

3 15.033±1.393 .000* .001* .005* .000*

4 13.990±1.266 .001* .503 .005* .072

5 13.333±1.217 .153 .256 .000* .072

Symphysis 
angle

1 86.453±5.052 .192 .944 .261 .000*

2 84.530±5.960 .192 .217 .856 .000*

3 86.350±5.558 .944 .217 .291 .000*

4 84.797±6.291 .261 .856 .291 .000*

5 75.557±5.468 .000* .000* .000* .000*

*Multiple Comparison LSD test, the mean diff. (mean differences) is significant at the level of 0.05.

direction of the ramus increases in accordance with the 
growth of the alveolar bone that will be the site for the dental 
root and the development of the permanent tooth. High 
differences in ramus also occur in patients aged between 
11 and 69 years. The highest average score was identified 
in the 20-29 year age group.13

The mean value of body length, condylion height, 
condylion angle and symphysis width from the highest to 
the lowest is, sequentially, in group 3, group 4, group 2, 

group 5 and group 1. There was a significant difference in 
body length, condylion height and condylion angle between 
group 1 and the other groups, and a significant difference 
in condylion height and symphysis width between group 1 
and all other groups, except group 5. Other studies on the 
height of the condylion  in non edentulous and edentulous 
groups using panoramic radiography showed that the mean 
high value of condyles in the non-edentulous group was 
greater than in the edentulous group.7

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
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84Sitanggang and Boel/Dent. J. (Majalah Kedokteran Gigi) 2018 June; 51(2): 81–85

The mean value of symphysis angle from the highest 
to the lowest  was sequentially in group 1, group 3, group 
4, group 2,and group 5. The mean value of the symphysis 
angle showed a significant difference between group 5 and 
the other groups. As teeth in the mandible erupt, they will 
move upwards and slightly forward. The normal rotation 
of the mandible causes that section on the anterior portion 
to grow upward. This rotation changes the pathway of the 
eruption of the incisor tending to lead it more posteriorly and 
the molars to further migrate mesially during growth.14

In this study, not all parameters showed significant 
differences in each age group which may be due to the 
age range used being very wide. Along with tooth eruption 
in the mandible, the process of growth and development 
of the mandible also involves remodeling, anterior and 
inferior displacement (aposition). The endocondrium of 
the condyle hardens, thereby affecting the growth of the 
posterior mandible. Apposition and remodeling will cause 
the mandible to grow larger.8,15

Condyle experiences considerable activity as the 
mandible moves and grows downward and forward. 
Apposition occurs at the posterior boundary of the ramus 
and the alveolar process. Resorption occurs along the 

anterior border of the ramus extending the alveolar border 
and maintaining the antero-posterior dimension of the 
ramus. The cephalometric study shows that the body 
of the mandible maintains a relatively constant angular 
relationship with the ramus. A slight change in the gonial 
angle after muscle activity works properly. The mandible's 
alveolar process grows upward and outward in a widening 
arc. This allows the dental arch to accommodate a larger 
permanent tooth.10 The length of the mandible increase due 
to the posterior apposition of the ramus and resorption of the 
anterior ramus. The increase in mandibular height is largely 
due to growth of the alveolar bone. The chin becomes more 
prominent as the mandible is elongated and there is only 
a slight increase of bone in the chin, However, it does not 
occur again after adolescence.8,15

A considerable body of research has been conducted to 
evaluate mandibular morphology, such as the measurement 
of ramus and condyle. Post-natal changes in mandibular 
morphology are thought to be affected by mastication 
and the age of the patient. Age, systemic factors and 
tooth loss may alter mandibular morphology.6,7,11,16,17 

Age and changes in the function and structure of the 
mastication muscles in edentulous patients appear to 

8 
 

 

 

 

 

 
Figure 1. Measurements on lateral cephalometric radiography. 
Ramus height: The distance measured from one point Ar to Go.1  Condylion height: The distance measured from 
the height of the ramus to the most superior point of the condyle.7 Body length: The distance measured from Go 
to Gn.15 Condylion  angle: The angle formed by Go-Co-Me.6 Symphysis height: The distance from point B to 
the most inferior point of simphisis1 Symphysis width: The distance from the most anterior border to the 
posterior simphisis.1 Symphysis angle: The posterosuperior angle formed by the line through the point Me and 
point B in the mandible plane.1 

 

 

 

Figure 1. Measurements on lateral cephalometric radiography.

Ramus height: The distance measured from one point Ar to Go.1  Condylion height: The distance measured from the height of the 
ramus to the most superior point of the condyle.7 Body length: The distance measured from Go to Gn.15 Condylion  angle: The angle 
formed by Go-Co-Me.6 Symphysis height: The distance from point B to the most inferior point of simphisis1 Symphysis width: The 
distance from the most anterior border to the posterior simphisis.1 Symphysis angle: The posterosuperior angle formed by the line 
through the point Me and point B in the mandible plane.1

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v51.i2.p81–85

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85 Sitanggang and Boel/Dent. J. (Majalah Kedokteran Gigi) 2018 June; 51(2): 81–85

decrease contraction  and lower muscle density than in 
their counterparts who still possess their teeth. Because 
the masseter and medial pterygoideus muscles exert force 
in the gonial corner area, the contraction strength of these 
muscles also affects the mandible's basic shape.2,9

The morphology of superficial masseter muscles in 
the gonial region is wider in dentate subjects than in their 
edentulous counterparts. Muscle mastication changes in 
function and structure according to the age of the edentulous 
subject. In computed tomographic scans, the activity of 
electromyography and lower muscle density is greater in 
edentulous subjects than dentulous subjects. The occurrence 
of masticatory muscle atrophy may be one of the factors that 
cause changes in the mandible.8,11,15–17 Another factor likely 
to induce such changes is the loss of intermaxillary support 
due to missing teeth, thereby permitting the masseter and 
medial pterygoid muscles to exert unrestricted tension on 
the mandible.15 The conclusion of this study is that group 
3 has the highest mean value of  mandibular morphology. 
There is a difference in the mandibular morphology 
of members of the Mongoloid race resident in Medan 
according to age identified by cephalometric radiography, 
in which the morphological differences in the mandible may 
be affected by the age and condition of the teeth. 

acknowledgement

This research was conducted with the financial 
support of the TALENTA grant fund of the Universitas 
Sumatera Utara No: 325/UN5.2.3.1/PPM/KP-TALENTA 
USU/2017.

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Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v51.i2.p81–85

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v51.i2.p81-85