Three-dimensional analysis of mandibular condyle position in patients with deviated mandibular prognathism

Abstract

The purpose of this study was to evaluate the bilateral difference in condyle position in patients with deviated mandibular prognathism. Patients with asymmetrical ( n = 28) and symmetrical mandibular prognathism ( n = 23) were compared using the three-dimensional (3D) reformatted image from cone beam computed tomography. Significant positional differences in the condyle and subcondyle region (sigmoid notch) were found between the deviated and contralateral sides in the group with asymmetrical mandibular prognathism, but not in the control group. The lateral condyle was more laterally and inferiorly positioned on the contralateral side than on the deviated side ( P < 0.05). The sigmoid notch was more laterally, superiorly, and posteriorly positioned on the deviated side ( P < 0.01). Interestingly, condyle width and height on the deviated side was narrower and shorter than on the contralateral side and in the control group. Menton deviation was closely correlated with the bilateral difference in condyle height and 3D position of the sigmoid notch ( P < 0.01). The degree of asymmetry was more highly correlated with condyle height than with the spatial orientation of the condyle head. The results demonstrated that mandibular prognathism with asymmetry is associated with bilateral differences in 3D morphology and orientation of the condyle. Therefore, clinicians should consider these variations during surgical planning.

The mandibular condyle is one of the key factors that determine the skeletal and occlusal relationship. Previous studies have suggested a close relationship between the temporomandibular joint (TMJ) and facial deformity . Facial asymmetry due to mandibular lateral deviation is an important feature in the aetiology of internal derangement of the TMJ . The incidence of internal derangement has been shown to be higher in patients with an asymmetrical class III facial deformity than in symmetrical class III patients . It has also been reported that the deviated side shows a steeper condyle eminence . However, previous studies on the position and morphology of the condyle performed using two-dimensional (2D) imaging, such as linear tomography, panoramic radiography, and open- and closed-mouth transcranial projections, have been subject to the limitations of the 2D imaging technique. Radiological examination of the TMJ is difficult because of the complicated anatomy, magnification errors, and superimposition of the adjacent anatomical structures. Recently, various three-dimensional (3D) imaging techniques have been utilized to evaluate the TMJ morphology to overcome the limitations of 2D imaging .

The 3D evaluation of deviated mandibular prognathism has shown that the condyle and the body of the mandible are significantly longer on the contralateral side of chin deviation . These differences in length suggest a major role for the condylar process in the aetiology of mandibular asymmetry. Most previous studies have shown a significant difference in TMJ space and condylar morphology between the two condyles in patients with facial deformity . These studies have focused on the relationship between the condyle and glenoid fossa rather than the spatial orientation and difference in 3D morphology of the condyle. In particular, there have been only a few studies on condylar position in patients with facial asymmetry performed using 3D reformatted images from computed tomography (CT). By comparing the 3D image data of patients with asymmetrical mandibular prognathism to those of control subjects with symmetrical prognathism, more insight could be gained into the potential aetiology of the facial asymmetry in patients with mandibular prognathism. Since orthognathic surgery in cases of facial asymmetry can greatly influence the TMJ position or function and surrounding muscular function, fundamental understanding of the 3D morphological features of the condyles in patients with asymmetrical mandibular prognathism is important in the diagnosis and treatment planning.

This study aimed to investigate whether there is any difference in the condyle and sigmoid notch positions in patients with and without mandibular deviation by using 3D coordinates. Any possible correlation between mandibular deviation and condylar positions was also evaluated. It was hypothesized that: (1) there is a difference between the condylar positions of the deviated and contralateral sides in patients with facial asymmetry, and (2) the degree of mandibular midline deviation is correlated to a larger condylar length on the deviated side. Therefore, an investigation was performed to determine the differences in condylar position in asymmetric and symmetric mandibular prognathism patients and the correlation between mandibular chin deviation and condylar position.

Materials and methods

Study subjects

This retrospective study included 51 patients with mandibular prognathism who had undergone orthognathic surgery at the affiliated hospital of Kyungpook National University in Daegu, Korea, between January 2013 and June 2014. The patients had been diagnosed with mandibular prognathism and an Angle class III molar relationship, with an A-point–nasion–B-point (ANB) angle of less than −1°. The cone beam computed tomography (CBCT) images obtained before orthognathic surgery for diagnostic purposes were used in this study. Patients with a history of facial trauma or infection, cleft lip/palate, hemifacial microsomia, previous TMJ surgery, or congenital muscular torticollis were excluded. The subjects were divided into two groups on the basis of the degree of chin deviation from the facial midline. Facial asymmetry was defined as chin deviation (menton or pogonion) of more than 4 mm from the facial midline . In this study, mandibular prognathism patients with menton (Me) deviation of less than 4 mm served as the control group and patients with Me deviation of more than 6 mm from the midsagittal plane formed the asymmetry group.

Image analysis

CBCT images were obtained to evaluate the condylar position using a CB MercuRay scanner (Hitachi Medical Corporation, Tokyo, Japan) under the following conditions: 19-cm field of view, 120-kVp tube voltage, and 15-mA tube current, resulting in a 0.4-mm voxel size. Patients were scanned in the upright position with their teeth in the intercuspal position. The 3D images were reconstructed using 3D software (Simplant O&O 2012; Materialise, Leuven, Belgium) and multiplanar reformatted images were acquired.

The 3D rendered head models were reoriented to reference planes, as reported in a previous study . The Frankfort horizontal (FH) plane was defined as the plane passing through both orbitales and right porion. The sagittal plane was defined as the plane perpendicular to the FH plane that passes through nasion and basion. The coronal plane was defined as the plane perpendicular to the FH plane and the sagittal plane that passes through the left porion. The perpendicular distances from each landmark to the midsagittal plane ( x ), coronal plane ( y ), and FH plane ( z ) were computed ( Fig. 1 ).

Fig. 1
The 3D reference planes. The Frankfort horizontal (FH) plane was defined as the plane passing through the right and left orbitale and the right porion. The sagittal plane was defined as the plane perpendicular to the FH plane that passes through nasion and basion. The coronal plane was defined as the plane perpendicular to the FH plane and sagittal plane that passes through left porion.

3D cephalometry was performed using the landmarks and measurements shown in Table 1 . Briefly, Lat-C was defined as the most lateral point of the condyle, Med-C as the most medial point of the condyle, and Cen-C as the mid-point of Lat-C and Med-C. Sub-C was defined as the lowest point of the sigmoid notch. The transverse width of the condyle and the height of the condyle were also measured in this study. The ‘deviated side’ was defined as the side with mandibular midline shift from the midsagittal reference plane, whereas the ‘contralateral side’ represented the side contralateral to the chin deviation ( Fig. 2 ).

Table 1
Definitions of the reference points, reference planes and measurement points.
Landmark Definition
Reference plane
Orbitale (Or) The midpoint of the infraorbital margin
Porion (Po) The most superior point of the external auditory meatus
Nasion (N) The most anterior point of the nasofrontal suture on the midsagittal plane
Basion (Ba) The midpoint of the anterior border of the foramen magnum
FH plane The plane including both Or and the right Po
Midsagittal plane The plane perpendicular to the FH plane and including N and Ba
Coronal reference plane The plane perpendicular to the FH plane and the midsagittal plane and including the right Po
Points
Lat-C The most lateral point of the condyle
Med-C The most medial point of the condyle
Cen-C The midpoint of Lat-C and Med-C
Sub-C The lowest point of the sigmoid notch
Lo1 The midpoint of the lower inter-incisal tip
Pogonion (Pog) The most anterior and midpoint on the symphysis of the mandible
Menton (Me) The most inferior and midpoint on the symphysis of the mandible
Measurements (mm)
Point x Perpendicular distance to the midsagittal plane (transverse position of the points)
Point y Perpendicular distance to the coronal plane (anteroposterior position of the points)
Point z Perpendicular distance to the FH plane (vertical position of the points)
Condyle width Transverse width of the condyle (Lat-C and Med-C distance)
Condyle height Distance from the centre of the condyle (Cen-C) to the sigmoid notch (Sub-C)

FH, Frankfort horizontal.

Fig. 2
Reference points and measurements in the condyle region. The deviated side was defined as the side of the mandibular midline shift from the midsagittal reference plane. The perpendicular distances from each landmark to each reference plane were measured. (A) Multiplanar reconstruction images for the identification of the landmarks. (B) 3D images of the asymmetry and control patients.

Data analysis and statistics

The measurements were analyzed statistically using SPSS version 12.0 (SPSS Inc., Chicago, IL, USA). To prevent inter-observer error, all processes were performed by one investigator (JSL). A test of reproducibility was conducted by comparing the measurements from the original examination to measurements obtained in repeated examinations of a random selection of the CBCT data from 10 patients after a 1-week interval. The method error was calculated as SE = √(∑ d 2 /2 n ), where d is the difference between double measurements and n is the number of paired double measurements . The method error of the linear measurements ranged from 0.52 mm to 0.87 mm, which was not statistically significant.

Bilateral differences within each group were analyzed using the paired t -test. Inter-group differences were compared with the Mann–Whitney U -test. There was no statistical difference between the measurements of the right and left side of the mandible in the control group (symmetrical prognathism). Therefore, the average value of the two sides in the control group was compared to each separate side in the asymmetry group. The relationship between the condylar position and mandibular deviation was evaluated using Pearson’s correlation analysis. The level of significance was set at 0.05 for all statistical analyses.

Results

The mean age of the patients in the asymmetry group ( n = 28) was 21.7 ± 3.0 years, and the mean age of the patients in the control group ( n = 23) was 20.4 ± 2.3 years. No statistically significant difference was found between the groups regarding age or sex. The average mandibular midline deviation at Me in the asymmetry group was 11.5 ± 3.2 mm and in the control group was 2.0 ± 1.0 mm ( Table 2 ).

Table 2
Demographic characteristics of the patients.
Characteristics Asymmetry group Control group P -value
Sample size ( n ) 28 23
Female, n (%) 16 (57.1%) 9 (39.1%) 0.200 a
Age, years, mean ± SD (range) 21.7 ± 3.0 (18–32) 20.4 ± 2.3 (17–24) 0.154 b
Menton deviation, mm, mean ± SD (range) 11.5 ± 3.2 (6.0–18.0) 2.0 ± 1.0 (0.3–3.6) <0.001 b
SD, standard deviation.

a Inter-group difference tested by χ 2 test.

b Inter-group difference tested by Mann–Whitney U -test.

With regard to the landmarks at the mandibular midline, the points Lo1, Pog, and Me were deviated significantly more from the midsagittal plane in the asymmetry group than in the control group ( P < 0.01). Patients with symmetrical mandibular prognathism had a more protruded chin compared to the asymmetry group, at the level of Pog and Me ( Table 3 ).

Table 3
Three-dimensional positions of the midpoints of the mandible (millimetres).
Asymmetry group Control group P-value a
Mean SD Mean SD
Lo1 ( x ) 7.9 2.7 1.2 1.4 <0.001 *
Lo1 ( y ) 89.8 5.6 95.1 7.9 0.011 *
Lo1 ( z ) 56.3 6.6 51.5 5.0 0.005 *
Pog ( x ) 11.1 3.2 2.0 1.0 <0.001 *
Pog ( y ) 84.9 9.0 94.3 10.6 0.067
Pog ( z ) 89.0 9.2 84.9 6.2 0.001 *
Me ( x ) 11.5 3.2 2.0 1.0 <0.001 *
Me ( y ) 78.2 9.5 88.6 10.8 0.001 *
Me ( z ) 96.7 8.7 92.1 6.3 0.036 *
SD, standard deviation.

a P -value for the inter-group difference.

* Significant difference.

Concerning the landmarks in the condylar region, no bilateral differences in the 3D positions of the condyle or sigmoid notch landmarks were found in the control group. In contrast, Lat-C was positioned more laterally and inferiorly on the contralateral side compared to the deviated side in the asymmetry group. As no difference in Med-C was found between the deviated side and contralateral side, a more laterally and inferiorly positioned Lat-C suggests a wider and higher condyle on the contralateral side. This was confirmed by the width and height measurements of the condyles. The differences in condylar width and condylar height were only present in the asymmetry group, not in the control group. Of note, the condyle of the deviated side in the asymmetry patients was narrower and shorter than that of the contralateral side and the mean values for both condyles in the control group.

The sigmoid notch (Sub-C) was found to be located more laterally, superiorly, and posteriorly on the deviated side compared to the contralateral side in the asymmetry group, whereas in the control group, no positional differences were found between the left and right sides. When comparing the position of Sub-C of the deviated side in the asymmetry group with the mean value of both sides in the control group, Sub-C was positioned more laterally and posteriorly in the first group ( Table 4 ).

Table 4
Comparison of bilateral measurements grouped by asymmetry and control patients (millimetres).
Asymmetry group Control group (5) Average of right and left ((3) and (4)) Comparison between variables
Contralateral side (1) Deviated side (2) Right (3) Left (4) Difference (5) − (1) Difference (5) − (2)
Mean SD Mean SD P -value a Mean SD Mean SD P -value a Mean SD Mean P -value b Mean P -value b
Lat-C ( x ) 62.5 3.5 61.4 4.4 0.012* 61.3 4.0 60.9 3.7 0.292 61.1 3.8 −1.45 0.156 −0.34 0.820
Lat-C ( y ) 13.9 3.8 12.1 2.8 0.072 14.5 2.9 13.4 2.2 0.093 14.0 2.1 0.10 0.865 1.89 0.006*
Lat-C ( z ) 9.8 3.0 8.3 3.2 0.007* 8.5 3.4 8.6 3.3 0.956 8.5 3.1 −1.27 0.148 0.26 0.813
Med-C ( x ) 43.9 2.4 43.9 3.1 0.921 41.7 2.7 41.3 2.1 0.296 41.5 2.3 −2.40 0.002* −2.45 0.004*
Med-C ( y ) 9.8 3.8 8.3 2.7 0.067 10.3 2.9 9.8 2.0 0.436 10.1 2.0 0.28 0.726 1.72 0.008*
Med-C ( z ) 7.7 2.8 7.7 2.8 0.969 6.9 2.5 6.4 2.1 0.254 6.6 2.0 −1.12 0.082 −1.09 0.106
Cen-C ( x ) 53.1 2.8 52.7 3.4 0.300 51.5 3.0 51.1 2.7 0.145 51.3 2.8 −1.83 0.036* −1.39 0.208
Cen-C ( y ) 11.7 3.8 10.2 2.4 0.101 12.4 2.8 11.6 2.0 0.196 12.0 2.0 0.33 0.806 1.80 0.002*
Cen-C ( z ) 8.8 2.6 7.8 2.8 0.105 7.6 2.1 7.5 2.4 0.793 7.5 2.0 −1.23 0.090 −0.32 0.557
Sub-C ( x ) 48.8 3.1 51.4 3.1 0.001* 49.2 2.7 48.9 2.5 0.408 49.0 2.5 0.20 0.820 −2.38 0.005*
Sub-C ( y ) 30.6 4.6 27.3 3.4 0.002* 31.6 4.3 31.2 4.0 0.458 31.4 3.9 0.86 0.643 4.18 0.001*
Sub-C ( z ) 22.6 4.1 19.2 4.7 <0.001* 20.9 3.9 21.1 4.1 0.500 21.0 3.9 −1.64 0.264 1.78 0.208
Condyle
Width 19.5 2.5 18.2 4.0 0.013* 20.6 2.6 20.2 3.0 0.334 20.4 2.6 0.91 0.218 2.15 0.017*
Height 24.2 3.8 20.8 3.9 <0.001* 23.6 4.0 24.2 4.1 0.243 23.9 3.9 −0.22 0.955 3.10 0.014*
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Dec 14, 2017 | Posted by in Oral and Maxillofacial Surgery | Comments Off on Three-dimensional analysis of mandibular condyle position in patients with deviated mandibular prognathism

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