Braz J Oral Sci. 15(4):242-247

Comparative dimensional tomographic study 
of the mandibular condyle of individuals with 

transverse maxillary deficiency
Andréa Guedes Barreto Gonçales1, Victor Tieghi Neto2, Eduardo Sanches Gonçales3, Ana Lúcia Álvares Capelozza4

1DDS, MsC. Stomatology Department. São Paulo University. Bauru Dental School
2DDS, PhD. Stomatology Department. São Paulo University. Bauru Dental School

 3DDS, PhD. Associated Professor of Oral and Maxillofacial Surgery. Stomatology Department. São Paulo University. Bauru Dental School
 4DDS, PhD. Full Professor of Radiology. Stomatology Department. São Paulo University. Bauru Dental School

Correspondence to:
Andréa Guedes Barreto Gonçales

FOB/USP. Departamento de Estomatologia 
Al. Otávio Pinheiro Brizolla, 9-75. CEP: 17017901 

Tel: +55 14 32358241 
e-mail: andreagoncales72@gmail.com

Abstract

Transverse maxillary deficiency is characterized by posterior uni or bilateral crossbite, crowded and 
rotated teeth, as well as high palate. Its treatment in adult individuals is surgically assisted rapid 
palatal expansion. The aim of this study was to verify the occurrence of dimensional alterations in 
the mandibular condyles of patients with TMD submitted to surgically assisted maxillary expansion. 
Measurements of the mandibular condyles using the DISTANCE tool in cone beam computed 
tomography iCat software were performed. The values obtained were submitted to statistical 
analysis by the paired t-test and the results showed statistically significant dimensional reduction 
in the axial posterior-anterior lateral (-0.74mm), axial posterior-anterior lateral left (-0.90mm) and 
coronal medium right (-1.24mm) dimensions. The coronal inferior (1.13mm), coronal inferior left 
(1.78mm) and coronal superior-inferior right (0.76mm) measurements showed statistically significant 
dimensional increase. The results allowed us to conclude that dimensional alterations occurred 
in the mandibular condyles in individuals with maxillary transversal deficiency that underwent 
surgically assisted rapid palatal expansion (SAPE), which can be understood by remodeling, since 
they are characterized by dimensional increase or reduction, depending on the location where the 
measurement was performed.

Keywords: Computed tomography. Malocclusion. Mandibular condyle.

Introduction
 
The dento-facial skeletal deformities can be defined as a defect of conformation 

of an organ or body part and result from changes in the growth and development of 
the bones of the face, especially maxilla and mandible. However other structures, 
organs and systems related to bones involved may be affected, causing problems 
in positioning of teeth, dental arches, masticatory function, phonation, swallowing, 
temporomandibular joints, breathing and facial aesthetics1. Transverse maxillary 
deficiency (TMD) is characterized by posterior uni or bilateral crossbite, crowded and 
rotated teeth, as well as high palate2,3. 

There are three basic alternatives for the treatment of TMD: orthopedic 
maxillary expansion, surgically assisted palatal expansion (SAPE) and Le Fort I 

Received for publication: July 06, 2016
Accepted: August 25, 2016 

Original Article Braz J Oral Sci.
October | December 2016 - Volume 15, Number 4  

http://dx.doi.org/10.20396/bjos.v15i4.8650028



243

segmental osteotomy. SAPE is indicated for the treatment of 
subjects with TMD larger than 5 mm, orthodontic/orthopedic 
expansion failure, need of expansion greater than 7 mm and for 
individuals with TMD and skeletal age of 15 years or more2,. 
The treatment of TMD in individuals with skeletal maturity is 
surgically assisted palatal expansion (SAPE) and this treatment 
has shown good results4, even with the description of different 
surgical techniques2.

The effects of SAPE are observed not only in the dental 
arch5, but also in the adjacent structures6-10 and mandibular 
dental arch11. The procedure is not free of complications, such 
as the occurrence of pain in the temporomandibular joint (TMJ) 
in 3% of the cases, mobility (3%) and loss (3%) of the upper 
central incisors, sinusitis (6%), paresthesia (3%), bleeding (3%), 
external resorption of teeth (3%) and displacement and tilt of 
the teeth (3%)12.

Cone beam computed tomography (CBCT) has been used in 
the planning and follow up of oral and maxillofacial surgeries, 
allowing the comparison of bone changes13. Since SAPE exerts 
effects on the adjacent maxillary structures, like changes in 
occlusion during this procedure, possible pain and changes in 
the TMJ, and that CBCT images allow the visualization and 
measurements of bony structures, the aim of the present study was 
to verify the occurrence of dimensional changes in mandibular 
condyles of individuals with TMD that underwent SAPE.

Material and methods
 

In the present study, measurements were done by the use 
of CBCT of the mandibular condyles. For this, preoperative and 
postoperative  measurements (mm) of mandibular condyle of 14 
individuals that underwent SAPE were done. It was approved by 
the Research Ethics Committee of the Bauru School of Dentistry 
of São Paulo University (Protocol no. 1702011/11-30-2011). In 
axial view, measurements of the lateral-medial, posterior-anterior 
lateral, posterior-anterior central and posterior-anterior medial 
sizes of the articular surface were performed. In the coronal 
reformats, the superior lateral-medial, inferior lateral-medial, 
medium lateral-medial and superior-inferior sizes were measured.

All scans were performed on an i-CAT Classic (Imaging 
Science International, Hatfield, Pennsylvania, USA) using the 
following protocol: 0.3mm voxel and Extended Height 20/20sec. 
The CBCTs were filed on CD and the linear measurement tool 
(DISTANCE) of the i-Cat Vision program was used for obtaining 
the measurements as described below.

On the i-Cat Vision homepage, we choose the name of the 
individual and open the CBCT by double clicking on the individual 
name. After the CBCT loads, the Screen MPR option was selected, 
obtaining the sagittal, axial and coronal views (Figures 1, 2 and 3).

The standardization of the condyle positions was obtained 
as follows: the mandible image was positioned on sagittal 
reformatting showing the articular cavity, articular eminence, 
mandibular angle, ramus and condyle. In this image, we positioned 
the red reference line (corresponding to axial reformatting) at the 
lower point of the articular eminence surface. The blue reference 
line (corresponding to the coronal reformatting) was positioned 

in the center of the condyle, perpendicular to the red reference 
line. The Distance tool was used to determine the center of the 
condyle by the measurement of the distance from the posterior to 
the anterior portion of the condyle surface on the red reference line. 
The condyle center corresponded to half the distance measured 
on the red reference line (Figure 1) and all the measures done 
in the axial and coronal views (figures 2 and 3) were made with 
this standardization.

The measures done on axial reformatting are shown in 
Figure 2: a) the lateral-medial distance of the articular surface 
measured between the lateral and medial  condyle poles (axial 
lateral-medial), b) posterior-anterior lateral size of the condyle 
articular surface measured in the lateral portion of the condyle, 
c) posterior-anterior central size of the condyle articular surface 
measured in the central portion of the condyle, d) posterior-anterior 
medial size of the condyle articular surface measured in the medial 
portion of the condyle. 

For the determination of the sites to be measured, the 
distance between the lateral and medial poles of the condyles was 
initially measured (axial lateral-medial measurement) on axial 
reformatting. The center of this measure determined the position 
of the axial posterior-anterior central measurement, which was 
measured perpendicular to the external surfaces. Similarly, the 
axial posterior-anterior lateral and medial distances were measured, 
since its position corresponded to half the distance between the 
condyle center (axial posterior-anterior central measurement) and 
the lateral and medial poles, respectively (Figure 2).

Comparative dimensional tomographic study of the mandibular condyle of individuals with transverse maxillary deficiency

Braz J Oral Sci. 15(4):242-247

Fig.1. Standardization of the positioning in sagittal reformatting.



244

The following measurements were performed on coronal 
reformatting: a) the lateral-medial superior size, measured 
from the lateral to medial surface at the bottom of the condyle 
joint surface (Coronal superior measurement), b) medium 
medial-lateral size, measured from lateral to the medial, in the 
intermediate portion of the condyle, equidistant from the upper 
and lower measures, c) inferior medial-lateral size, measured 
from the lateral to medial in the lower portion of the condyle, 
and d) superior-inferior measure, taken from the articular surface 
of the condyle center until the lower cortical bone (Figure 3).

In a similar way implemented in axial reformatting, 
on coronal reformatting the locations to be measured were 
standardized as follows: the distance between the lateral and 
medial poles of the condyle were measured at the lower bound 
of the articular surface and this was the superior coronal 
measurement. At the center of this measurement, perpendicular 
to the outer surface of the articular surface, from upper to lower, 
the Coronal Superior-inferior measurement was done. The 
lower bound of this measure was the intersection of the central 
measurement line with the external cortical of the condyle. 
The distance between the Coronal Superior measurement and 
the lower limit of the condyle was then measured. It was then 
divided into three and the Coronal medium measurement was 
measured in the lateral-medial sense in the upper third of the 
measure, while the Coronal Inferior measurement was performed 
in the lower third, also in the medial-lateral direction (Figure 3).

All measurements were obtained in preoperative and 
postoperative CBCTs, tabulated and submitted to statistical 
analysis by paired t test. After 15 days of the completion of the 
first data collection14, all measurements were redone to determine 
the random and systematic error by the Intraclass Correlation 
Coefficient (ICC)15.

Results

We used 28 CBCTs from fourteen individuals with TMD, 
submitted to SAPE. Five of the individuals were men and nine 
were women, with an average age of 24.28 years (DP 4.39). 
Six individuals (42.86%) used the Hass expander device while 
8 (57.15%) used the Hyrax expander device. The average 
postoperative period was 192 days (SD 16.03). 

Table 1 shows the average (A), standard deviation (SD), 
difference between preoperative and postoperative averages (dif), 
paired t-test result (p), when the right and left condyles were 
considered together, while Table 2 represents the average (A), 
standard deviation (SD), difference between preoperative and 
postoperative averages (dif), paired t-test result (p), when the 
right and left condyles were considered separately.

In general, it was observed that there were changes in 
dimensional mandibular condyles, characterized by increase or 
decrease, depending on the site of the measure. The analysis of 
the condyles together (per individual) was shown to be similar 
to the analysis of the isolated condyles. Thus, the results of 
the measures showed an increase in the axial lateral-medial 
(0.19mm), axial posterior-anterior central (0.15 mm), coronal 
superior (0.27 mm), coronal inferior (1.13 mm) and coronal 

 Comparative dimensional tomographic study of the mandibular condyle of individuals with transverse maxillary deficiency

Braz J Oral Sci. 15(4):242-247

Fig.2. Axial measurements: lateral-medial (red), posterior-anterior central (green), 
posterior-anterior lateral (pink) and posterior-anterior medial (light pink), carried out 
in the condyles. The other measures that appear (yellow, light blue and salmon) were 
performed to determine the locations of the axial measurements.

Fig.3. Coronal Superior measurements (red), Coronal Superior-inferior measurement 
(green), Coronal Medium measurement (salmon) and Coronal Inferior measurement 
(orange), carried out in the condyles on coronal reformatting. The other measures that 
appear (yellow, light pink, pink and light blue) were performed to determine the locations 
of the coronal measures.



245 Comparative dimensional tomographic study of the mandibular condyle of individuals with transverse maxillary deficiency

superior-inferior (0.48 mm) measures. The reduction of the 
measures was observed at the axial posterior-anterior lateral 
(-0.74 mm), axial posterior-anterior medial (-0.35 mm) and 
coronal medium (-0.28 mm) measures. Only the axial posterior-
anterior lateral and coronal inferior measures were statistically 
significant (Table 1).

axial posterior-anterior central right (0.62 mm), axial posterior-
anterior central right (0.42 mm), coronal superior left (0.67 
mm), coronal inferior right (0.47 mm) and left (1.78 mm) and 
coronal superior-inferior right (0.76 mm) and left (0.20 mm) 
measures. The isolated analysis of each condyle allowed us to 
also see a reduction in axial dimensions of the posterior-anterior 
lateral right (-0.58 mm) and left (-0.90 mm), posterior-anterior 
central left (-0.11 mm), posterior-anterior medial right (-0.05 
mm) and left (-0.65 mm), coronal superior right (-0.15 mm) 
and coronal medium right (-1.24 mm). When we analyzed the 
condyles separately, apart from the axial posterior-anterior lateral 
left, coronal medium right, coronal superior left and coronal 
superior-inferior right measures (table 2), these values were not 
statistically significant.

For error analysis, the ICC was used; all measures were 
carried out by the same examiner and respecting the time of no 
less than 15 days. The ICC was excellent, since all their values 
were greater than 0.75. 

Discussion

In individuals who have reached skeletal maturity due to 
the consolidation of craniofacial sutures16, the TMD treatment 
is orthodontic and surgical and the surgical step is known as 
Surgically Assisted Maxillary Expansion (SAPE)2,3. After the 
surgical procedure, maxillary expansion itself is accomplished 
by gradual, periodic and successive activation of the expander 
device that results in distribution of forces through the maxillas 
and adjacencies, which lead to the separation and enlargement 
of them17,18.

The occurrence of TMJ pain was evidenced in 3% of the 
cases of individuals subjected to SAPE12, which may be considered 
a low incidence, and the incidence of other complications was 
also low, even though those that occurred more often reached a 
maximum of 6% (sinusitis)12. The incidence of TMJ pain allow 
us to believe that the anatomical configuration of the human face, 
especially the relationship between the maxilla and mandible, 
TMJs, muscles of mastication and the dental occlusion may lead 
to the occurrence of SAPE effects in the mandible. It should be 
noted that Albuquerque et al.12 (2013) considered TMJ pain in a 
generic form, perhaps not only including isolated pain in the TMJ, 
but also muscle aches. Since the mandibular condyle is one of the 
components of TMJ, by the factors described above, it is subjected 
to the effects of  SAPE. This study was a retrospective study that 
evaluated only the preoperative and postoperative CBCT of the 
individuals submitted to SAPE. Thus there are no conditions to 
discuss about signs and symptoms or even about clinical features 
as Albuquerque et al.12 (2013) did.

Our results corroborate the aforementioned because 
there were changes in the dimensional mandibular condyles, 
characterized by increase or decrease, based in the preoperative 
and postoperative measurements carried out, depending on the 
measure. Such changes could have taken place, for example, by 
the occlusal overload generated by premature dental contacts, 
leading to changes of mandibular position and eventually in the 
condyle remodeling.

Braz J Oral Sci. 15(4):242-247

Table 1 - Average (A), standard deviation (SD), difference between 
preoperative (Preop) and postoperative (Postop) averages (dif), 
paired t-test result (p), when the right and left condyles were 
considered together (same individual) (*p<0.05).

Measure Preop Postop
A SD A SD dif. p

Axial Lateral-medial 18.32 2.51 18.51 2.53 0.19 0.372
Axial Posterior-anterior 

lateral 7.05 1.15 6.31 1.02 -0.74 0.001*

Axial Posterior-anterior 
central 7.32 1.36 7.47 1.49 0.15 0.487

Axial Posterior-anterior 
medial 6.86 1.15 6.51 1.33 -0.35 0.147

Coronal Superior 14.87 2.48 15.14 2.76 0.27 0.320
Coronal Medium 13.62 2.53 13.33 2.85 -0.28 0.410
Coronal Inferior 7.25 1.21 8.37 1.78 1.13 0.000*

Coronal Superior - inferior 18.58 3.25 19.06 3.66 0.48 0.090

Table 2 - Average (A), standard deviation (SD), difference between 
preoperative (Preop) and postoperative (Postop) averages (dif), 
paired t-test result (p), when the right and left condyles were 
considered separate (*p<0.05). R = right. L = Left.

Measure Preop Postop
A SD A SD dif. p

Axial Lateral-medial R 18.61 2.51 18.65 2.64 0.05 0.860
Axial Lateral-medial L 18.03 2.56 18.37 2.51 0.34 0.344

Axial Posterior-anterior 
lateral R 6.61 1.18 6.03 0.97 -0.58 0.094

Axial Posterior-anterior 
lateral L 7.49 0.98 6.59 1.02 -0.90 0.005*

Axial Posterior-anterior 
central R 6.89 1.36 7.31 1.67 0.42 0.303

Axial Posterior-anterior 
central L 7.74 1.27 7.63 1.33 -0.11 0.513

Axial Posterior-anterior 
medial R 6.69 1.51 6.65 1.43 -0.05 0.889

Axial Posterior-anterior 
medial L 7.02 0.63 6.37 1.26 -0.65 0.061

Coronal Superior R 14.54 2.72 14.39 2.70 -0.15 0.621
Coronal Superior L 15.21 2.27 15.89 2.70 0.68 0.121
Coronal Medium R 13.54 2.91 12.30 3.00 -1.24 0.000*
Coronal Medium L 13.69 2.19 14.36 2.36 0.67 0.234
Coronal Inferior R 7.07 1.38 7.54 1.70 0.47 0.123
Coronal Superior L 7.42 1.04 9.20 1.48 1.78 0.000*

Coronal Superior-infe-
rior R 18.16 3.69 18.92 3.88 0.76 0.007*

Coronal Superior-infe-
rior L 19.00 2.81 19.20 3.58 0.20 0.694

When analyzed separately, each condyle showed an increase 
in axial lateral-medial right (0.05 mm) and left (0.34 mm), 



However, even when an increase in dimensions of axial 
measures occurs, when separately analyzing each condyle, only the 
axial posterior-anterior lateral left, coronal medium right, coronal 
superior left and coronal superior-inferior right measurements were 
statistically significant (*p<0.05). Such fact might demonstrate 
that the remodeling occurs preferentially in certain areas and these 
areas may vary according to the occlusal interference and because 
of this, they are asymmetrical. It is expected that where there was 
a statistically significant decrease of the measures, the condyle 
was reabsorbed and a statistically significant increase occurred 
because of bone formation. 

The TMJ is a bilateral joint in which both sides work 
simultaneously, and therefore we also evaluated the condyles in 
sets. Similarly, only the axial posterior-anterior lateral and coronal 
inferior measures were statistically significant. It is believed that, 
even when the individual is considered, the occlusal interference 
might be responsible for possible asymmetric condyle remodeling.

Although studies19-21 showed that occlusal forces can affect 
the condyle morphology and may lead to condyle remodeling and 
CBCT was a useful tool for monitoring condylar bone changes, 
it should be noted that the statistical result found can be due 
the number of studied subjects or the methodology employed. 
This study did not verify the occurrence of occlusal changes and 
premature contacts, as well as the presence or absence of symptoms 
related to TMJs or masticatory muscles. Thus, one can only infer 
the occurrences just described.

With regard to the method employed, the applicability of 
CBCT in Dentistry appears to be questionable because some 
studies19,22-26 claimed that the CBCT was a reliable and accurate 
method for verification of changes and carry out measures in 
TMJ as a whole and specifically in the mandibular condyles. 
This is especially true when the sagittal and coronal views are 
considered, being efficient in the determination of changes related 
to the positioning and shape of the condyle and joint surfaces27,28. 

It is believed that cited studies , corroborated the 
methodology used, since they correlated CBCT with dimensional 
and positioning and shape changes of condyles. Despite having 
difficulties in detection by the CBCT of the condylar defect 
smaller than 2mm29,30, this difficulty would not be expected to 
occur in the present study, since the distances representing the 
condylar dimensions were measured, but not bone defects. t. In 
addition, the ICC15 was excellent, confirming the accuracy of 
the measurements performed.

Thus, based on the methodology used and the sample studied, 
it seems justified to conclude that in individuals with TMD 
submitted to SAPE, dimensional changes occur in the mandibular 
condyles, perhaps by remodeling, since they were characterized 
by an increase and reduction of the condylar dimensions.

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