161

The effect of mastication muscular tone on facial size in patients 
with Down syndrome

Margaretha Suharsini*, Josef Glinka SVD**, and Soekotjo Djokosalamoen***
*** Lecture Staff of Department of Pediatric Dentistry, Faculty of Dentistry, University of Indonesia
*** Professor Department of Anthropology, Faculty of Social Politics, Airlangga University
*** Professor Department of Orthodontics, Faculty of Dentistry, Airlangga University

abstract 

Muscular hypotonia is one of the clinical signs in patients with Down syndrome. As a characteristic of patients with Down syndrome, 
hypotonia is clearly evident in face expression and oral dysfunction. Dentocraniofacial growth abnormalities in patients with Down 
syndrome may be influenced by genetic and environmental factors. Stomatognathic system musculature as an environmental factor 
(factor outside the bone) can affect dentocraniofacial growth by orofacial muscles activities when chewing, swallowing, breathing, and 
speaking. Oral dysfunctions commonly seen in patients with Down syndrome are open mouth, protruding tongue posture, difficulties 
when chewing, swallowing, and speaking, drooling, and mouth breathing. The purpose of this study was to observe how the mastication 
muscular tone affecting the facial size of Down syndrome patient. Twenty five of 14–18 years old children with Down syndrome were 
diagnosed by clinical characteristic and cytogenetic examination. Mastication muscular tone was described by masseter and temporalis 
muscle synergy and oral function, whereas the facial size consisted of facial size of lateral, anteroposterior and vertical growth. The 
result of regression test revealed that the degree of mastication muscular tone has a significant effect on facial size of the anteroposterior 
growth and facial size of vertical growth, but did not significantly influence the facial size of lateral growth. 

Key words: mastication muscular tone, facial size, Down syndrome

 Correspondence: Margaretha Suharsini, c/o: Bagian Ilmu Kedokteran Gigi Anak, Fakultas Kedokteran Gigi Universitas Indonesia. 
Jln. Salemba Raya No. 4 Jakarta Pusat, Indonesia. 

introduction

The Down syndrome is one of the most common genetic 
disorders, which clinical neurologic disorders such as 
muscular hypotonia and mental retardation occur. Muscular 
hypotonia in children with Down syndrome may affect 
growth, such as motoric growth and speech impediment. 
Hypotonia in children with Down syndrome will raise 
difficulties to move against gravitation, thus resulted in 
inefficient motoric growth. The manifestations are delay 
in child’s ability to seat, stand, and walk. Children with 
Down syndrome are able to walk more or less in 2 years 
of age.1

In addition, hypotonia in children with Down syndrome 
can also manifest in weakness of orofacial musculature, i.e 
lips, tongue, and cheek. It produces an indistinguishable 
pronunciation, speech impediment, or stutters, because 
they cannot hold breathe long enough when saying a whole 
sentence. In this situation, oral muscular therapy as part of 
speech therapy program is recommended to increase the 
muscular tone.2

In normal condition, stomatognathic system musculature 
as an environmental factor (factor outside the bone) may 
influence dentocraniofacial growth. Stomatognathic 
system musculature that gives effect to dentocraniofacial 
is orofacial muscles’ activities in chewing, swallowing, 
breathing, and speaking. These orofacial muscles are 

referred to mastication, lips and surroundings, tongue, and 
facial muscles.3,4 

Hypotonia as a characteristic of patients with Down 
syndrome is clearly evident in face expressions and oral 
dysfunctions. Oral dysfunctions commonly seen in these 
patients are open mouth, protruding tongue, difficulties in 
chewing, swallowing, and speaking. In addition, drooling 
and mouth breathing are frequently observed in these 
patients.5,6,7 

Macroglossia is a frequent finding in Down syndrome, 
but it is not clear whether the apparent large tongue in these 
patients is anatomically enlarge or functionally enlarged 
as a result of an abnormal forward posture. The narrow 
maxilla results in lack of space for the tongue may lead 
the patient to protrude it. This can also gives impression 
of macroglossia.8 

Protruded tongue in Down syndrome patients is 
predicted to cause a dull gonion angle in the mandible, as 
well as anterior openbite. However, Fischer-Brandies9 in his 
study of children with Down syndrome 0–14 years of age 
found that gonion angle when they were baby was slightly 
smaller than normal babies (without Down syndrome). 
Moreover, he found no difference in gonion angle during 
growth to 14 years of age, so he concluded that protruded 
tongue in children with Down syndrome seems to have no 
effect to gonion angle. This needs a further study, because 
the likeness of gonion angle between Down syndrome 



162 Dent. J. (Maj. Ked. Gigi), Vol. 39. No. 4 October–December 2006: 161–164

patients and normal children can not be assessed only by 
protruded tongue, yet the forces of mastication muscles need 
to be considered. It is likely that oral muscular exercises 
can increase the force of mastication muscles; therefore the 
craniofacial bone abnormality can be minimized. 

Craniofacial can be divided into two sections: cranial 
section and facial section. Growth of facial section 
has a closer association with somatic growth and it 
occurs gradually. Begin with lateral growth, continued 
with anteroposterior growth, and ultimately vertical 
growth.10,11

Explanation above indicates that muscular hypotonia in 
patients with Down syndrome can produce disturbance in 
oral function, and affecting the bone growth in the region of 
mouth. Therefore, the purpose of this study was to observe 
the effect of mastication muscular tone on facial size in 
Down syndrome patients. 

materials and methods

In this study, male and female between 14–18 years 
of age with Down syndrome from Sekolah Luar Biasa 
(Special Schools) in Jakarta was selected. The diagnosis 
were established clinically by observing the clinical 
characteristic in children with Down syndrome, and by 
citogenetic examination, that was, a child with trisomy 
21 aberration. Twenty-five children with Down syndrome 
were chosen, after several approaches and examinations 
were carried out.

Mastication muscular tone acted as independent 
variable, described with:12 1) Electromiogram of masseter 
and temporalis muscle, afterward these muscles were 
joined as a single variable, that was, masseter-temporalis 
muscle synergy. 2) Oral function, that was total score of 
these examinations: a) swallowing; b) chewing, the amount 
of chew before swallowing ± 2 cm2 crackers; c) resting 
position between upper and lower lip; d) breath habit;  
e) drooling, involuntary saliva excretion; f) tongue in resting 
position; g) free way space measurement. Both variables of 
mastication muscular tone were analyzed, to obtain factor 
variable of muscular tone factor.

Facial size of lateral, anteroposterior, and vertical 
growth served as dependent variable:12 1) variables 
attributed to facial size of lateral growth were: Gonion-
Gonion (Go-Go), nose width, maxillary width, mandibular 
width, face width, inter orbits, Zygion-Zygion (Zy-Zy), 
Alae nasi-Alae nasi (Al-Al), Endocantion-Endocantion (En-
En); 2) variables attributed to facial size of anteroposterior 
growth were: maxillary length, mandibular length, Sella-
Nasion-Point A angle (S-N-A), S-N-B angle, Articulare-
Gonion-Menton angle (Ar-Go-Me); 3) variables attributed 
to facial size of vertical growth were: ANS-Menton 
(ANS-Me), Nasion-ANS (N-ANS), Nasion-Gnathion 
(N-Gn), Nasion-Subnasale (N-Sn), Ramus Mandibulae, 
Sella-Gonion (S-Go).

After factor analysis of all three variable groups was 

carried out, each factor variable of facial size of lateral 
growth, facial size of anteroposterior growth, and facial size 
of vertical growth was obtained. Regression test was carried 
out to observe the effect of degree of mastication muscular 
tone on each facial size in Down syndrome patients. 

results

The outcome of examinations carried out in 25 male 
and female with Down syndrome were mean and standard 
deviation (  ± SD) of electromyogram of masseter-
temporalis muscle synergy i.e. 596.28 ± 120.34 mm2/sec, 
and mean ± SD of oral functions total score, i.e. 11.36 ± 
3.25. These muscular tone variables were subjected to factor 
analysis, to attain factor variable of muscular tone.

Table 1.  Results of regression test regarding degree of mastication 
muscular tone effect on facial size in Down syndrome 
patients

Results of regression test regarding degree of mastication 
muscular tone effect on facial size in Down syndrome 
patients were listed in table 1. The test showed that the 
degree of mastication muscular tone has a significant 
effect on facial size of anteroposterior growth (p = 
0.012) and facial size of vertical growth (p = 0.020), 
but not significant on facial size of lateral growth  
(p = 0.527).

discussion

Bone is flexible and may react to functional tension and 
pressure, thus it can be suggested that form and function 
are intimately related. Functions that performed by muscles 
include mastication, deglutition, speech, face expressions, 
and respiration. Physiologically, tension and pressure can 
produce alteration in external form and internal structure of 
the bone. The amount of alteration within bone depends on 
the tension and pressure encountered. However, pressure 
from the muscle is within the limits of its morphogenetic 



163Suharsini: The effect of mastication muscular tone

pattern. The stimulation from muscle to a certain limit 
(optimal limit) will induce cell growth to become 
remodeling that may influence bone shape and size.13

The mastication process always relates to activities of 
mastication muscles. The impact of functional stimulation 
to craniofacial is mainly derived from mastication muscles 
activity. This stimulation will produce biomechanical forces 
and Piezo effect to the bone. Both effects will produce the 
distortion of collagen tissue, and will create both direct 
and indirect electric potential that induce osteoblastic and 
osteoclastic process.14

Kiliaridis15 stated that eating soft diet regularly 
will reduce the function of mastication, thus fibers of 
masticatory muscles will be smaller. Consequently, 
mastication or contraction strength will be reduced and 
produce changes in bone remodeling. This may influence 
the craniofacial bone growth. Moreover, Engstrom et al.16 
demonstrated that rats fed a soft diet will have diminution 
in degree of mastication function, which will change bone 
apposition pattern in cortical bone and upper facial sutures. 

Kiliaridis et al.17 proposed that weakened of mastication 
muscles may influence the size of gonion angle. 

In this study, regression test was carried out to observe 
the effect of degree of mastication muscular tone on 
facial size in patients with Down syndrome. The result 
of regression test indicates that the degree of mastication 
muscular tone has a significant effect on facial size of 
anteroposterior growth (p = 0,012) and vertical growth  
(p = 0.20), but not significant on facial size of lateral growth 
(p = 0,527). 

Factors of facial size of anteroposterior growth contain 
the length of maxilla, length of mandibula, and Ar-Go-Me 
angle (gonion angle). Those parts have a direct correlation 
to masseter muscle activities when function, considering 
masseter muscle have insertion on angulus and ramus 
mandibulae, and its origin is on arcus zygomaticus.18 

Kiliaridis et al.17 also stated that weakened of 
mastication muscles will reduce mechanical strength, that 
compress the mandible and resulting changes to gonion 
angle. The research performed in patients with myotonic 
dystrophy revealed that weakened of mastication muscle 
will reduce mechanical compression to the mandible, so the 
mandible will be pulled downward easily. The downward 
movement of mandible may be resulted from gravitation 
or probably by force of suprahyoid muscle downward. The 
mouth will likely to open, meanwhile posterior teeth will 
continue to erupt. Thus, anterior open bite will occur. As a 
result, gonion angle will be larger than normal.

A strong mastication muscle will amplify the rotation of 
mandible to anterior, thus gonion angle will be narrowed. 
Diet alteration will cause changes in dimension of maxilla 
and mandible. Soft diet can diminish the size of mastication 
muscles. Therefore, functional stimulation to bone will 
decrease, that may cause rotation of mandible backward, 
resulting the gonionangle larger than normal. The changes 
of dimension will directly affect both maxilla and mandible, 
because origin and insertion of mastication muscles are 

attached to them.19,20
DuBrul21 suggested that the site of growth of maxilla 

complex occurs prominently in several sutures in this 
region. The suture is running frontward-upward to 
backward-downward, therefore the maxilla complex grow 
in up-front direction. This will cause bone apposition 
in the entire posterior surface of maxilla, thus enlarging 
maxilla anteroposteriorly. In his study of rats fed a soft diet, 
Engstrom et al.16 demonstrated that soft diet will diminish 
the degree of mastication function, subsequently bone 
apposition in upper facial suture will undergo an alteration 
that affecting the suture closing process. Consequently, 
facial growth in anteroposterior direction is insufficient.

Based on explanation above, it can be assumed that 
muscular hypotonia in patients with Down syndrome will 
decrease the function of mastication, resulted in facial 
growth insufficiency in anteroposterior direction. Likewise 
soft diet will decrease muscle strength, muscular hypotonia 
in patients with Down syndrome most likely to give 
direct impact to the dimension of maxilla and mandible. 
In addition, muscular hypotonia will reduce mechanical 
strength that compress the mandible, thus gonion angle in 
patients with Down syndrome have a tendency to be larger 
than normal. For that reason, it can be concluded that the 
degree of mastication muscular tone in Down syndrome 
patients has an impact on the maxillary length, mandibular 
length, and gonion angle, in which all three of them are 
facial size of anteroposterior growth. 

The degree of mastication muscular tone also has 
a significant impact on facial size of vertical growth  
(p = 0.020). To describe this, masseter and temporalis 
muscle activities are open and close the mouth when eating, 
and speaking as well.18

Muscular hypotonia, or weakened of masticatory 
muscles, in Down syndrome patients reduces muscle 
stimulation to the bone, resulted in insufficiency of facial 
growth in vertical direction.

DuBrul21 proposed that vertical facial growth in 
subnasal region is augmenting, as a result of resorption in 
nasal floor and aposition in surface of palatum and alveolar 
bone, concurrently with teeth eruption. Muscular hypotonia 
in Down syndrome patients reduces mastication force, so 
it will also reduce the force from mandibular stroke to 
alveolar bone in upper jaw and afterward transmitted to 
palatum. Consequently, remodeling process in subnasal 
region will not be optimal, that will cause a lack of vertical 
facial size.

The result revealed that the degree of mastication 
muscular tone in Down syndrome patients has no influence 
on facial size of lateral growth (p = 0.527). Considering 
that fibers of masseter muscle run obliquely and temporalis 
muscle fibers runs vertically and obliquely, and their main 
functions are to elevate and retract the mandible,18,21 it is 
most likely that facial size of lateral growth is not influenced 
by masticatory muscles that largely move vertically in 
accordance with their fibers direction. 

According to DuBrul,21 there is only small amount of 
lateral facial growth in the posterior region because it is 
limited by os sphenoidale. Or else, it is likely that lateral 



164 Dent. J. (Maj. Ked. Gigi), Vol. 39. No. 4 October–December 2006: 161–164

facial growth have already completed in 12 years of age. 
Therefore, the muscle activity around facial region is 
not strong enough to exert influence upon lateral facial 
growth, what is more in Down syndrome patients who have 
masticatory muscular hypotonia. 

The result and discussion above revealed that the degree 
of mastication muscular tone in Down syndrome patients 
may influence the facial size of anteroposterior and vertical 
growth, but not the facial size of lateral growth.

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