Mandibular and temporomandibular morphologic characteristics of patients with suspected unilateral condylar hyperplasia: a CT study

López, Diego Fernando; Botero, Juliana Ruiz; Muñoz, Juan M.; Cardenas-Perilla, Rodrigo A.

doi:10.1590/2177-6709.25.2.061-068.oar

ABSTRACT

Introduction:

Facial asymmetry associated with unilateral condylar hyperplasia (UCH) is a complicated clinical condition.

Objective:

The objective of this study was to describe morphological characteristics of the mandible and the temporomandibular joint in patients with facial asymmetry, using computed tomography and 3D reconstruction.

Methods:

A retrospective observational study was performed with patients displaying facial asymmetry evaluated by single photon emission computed tomography (SPECT)/CT analysis, for suspected UCH, between 2015 and 2018. The following variables were compared between the affected side (producing the asymmetry) and the contralateral side (side to where the jaw is deflected): condylar length, condylar medial and lateral pole length, mandibular ramus length, intra-articular spaces, articular eminence height and position of the posterior wall of the glenoid fossa.

Results:

Forty-three patients (21 women, mean age: 20.7 ± 7.25 years) with facial asymmetry were included, 19 patients presented right side deviation and 24 patients had left side deviation. Condylar length, lateral pole length, the sum of maximum values and articular eminence height were greater in the affected side (p< 0.05). A positive correlation was found between the position of the posterior wall of the glenoid fossa and the articular eminence height in the affected side (r = 0.442).

Conclusions:

In patients with suspected UCH, evaluated through CT, craniofacial measurements showed significantly larger condylar length and the condylar sum of maximum values in the affected side. A positive correlation was found between the increased dimensions of the articular eminence and the more posterior position of the glenoid fossa in the affected side.

Keywords:
Facial asymmetry; Condylar hyperplasia; Temporomandibular joint; Computed tomography

RESUMO

Introdução:

A assimetria facial associada à hiperplasia condilar unilateral (HCU) é uma condição clínica complexa.

Objetivo:

O objetivo desse estudo foi descrever as características morfológicas da mandíbula e da articulação temporomandibular de pacientes com assimetria facial, usando tomografia computadorizada e reconstruções tridimensionais.

Métodos:

Esse estudo observacional retrospectivo foi realizado em pacientes com assimetria facial e suspeita de HCU, avaliados por meio da análise de tomografia computadorizada de emissão de fóton único (SPECT)/TC, entre os anos de 2015 e 2018. As seguintes variáveis foram comparadas entre o lado afetado (responsável pela assimetria) e o lado contralateral (lado para onde a arcada estava desviada): comprimento condilar, comprimento dos polos medial e lateral do côndilo, comprimento do ramo mandibular, espaços intra-articulares, altura da eminência articular e posição da parede posterior da fossa glenoide.

Resultados:

A amostra constituiu-se de 43 pacientes (21 mulheres, idade média: 20,7 ? 7,25 anos) com assimetria facial, da qual 19 pacientes apresentavam desvio do lado direito e 24, do lado esquerdo. O comprimento condilar, o comprimento do polo lateral, a soma dos valores máximos e a altura da eminência articular foram maiores no lado afetado (p< 0,05). Foi encontrada uma correlação positiva entre a posição da parede posterior da fossa glenoide e a altura da eminência articular no lado afetado (r = 0,442).

Conclusão:

Em pacientes com suspeita de HCU, avaliados por meio de TC, as medidas craniofaciais mostraram um comprimento condilar e a soma dos valores condilares máximos significativamente maiores no lado afetado. Foi encontrada uma correlação positiva entre as dimensões aumentadas da eminência articular e a posição mais posterior da fossa glenoide no lado afetado.

Palavras-chave:
Assimetria facial; Hiperplasia condilar; Articulação temporomandibular; Tomografia computadorizada

INTRODUCTION

The temporomandibular joint (TMJ) is one of the more complex systems of the human body.¹1 Merigue LF, Conti ACCF, Oltramari-Navarro PVP, Navarro RL, Almeida MR. Tomographic evaluation of the temporomandibular joint in malocclusion subjects: condylar morphology and position. Braz Oral Res. 2016;30. pii: S1806-83242016000100222. TMJ morphologic asymmetries and disorders may be related to a number of different factors, which include inflammatory and degenerative diseases, postural disorders, trauma, premature dental contacts and dentoskeletal asymmetries.¹1 Merigue LF, Conti ACCF, Oltramari-Navarro PVP, Navarro RL, Almeida MR. Tomographic evaluation of the temporomandibular joint in malocclusion subjects: condylar morphology and position. Braz Oral Res. 2016;30. pii: S1806-83242016000100222.

2 Valladares JV, Estrela C, Bueno MR, Guedes OA, Porto OCL, Pécora JD. Mandibular condyle dimensional changes in subjects from 3 to 20 years of age using Cone-Beam Computed Tomography: A preliminary study. Dental Press J Orthod. 2010;15(5):172-81.^-³3 Bayram M, Kayipmaz S, Sezgin OS, Kucuk M. Volumetric analysis of the mandibular condyle using cone beam computed tomography. Eur J Radiol. 2012 Aug;81(8):1812-6. A common anatomic difference between TMJs of the same subject is clinically perceived as a facial asymmetry, with a reported prevalence of 21 to 85%.⁴4 Severt TR, Proffit WR. The prevalence of facial asymmetry in the dentofacial deformities population at the University of North Carolina. Int J Adult Orthodon Orthognath Surg. 1997;12(3):171-6. The etiology is not well established, but may be related to genetic or environmental factors appearing during fetal life, childhood or puberty. These factors include Unilateral Condylar Hyperplasia (UCH),⁵5 Kim S-J, Lee K-J, Lee S-H, Baik H-S. Morphologic relationship between the cranial base and the mandible in patients with facial asymmetry and mandibular prognathism. Am J Orthod Dentofacial Orthop. 2013;144(3):330-40. functional disharmonies of the masticatory muscles, dominance of a brain hemisphere,⁶6 Bjoerk A, Bjoerk L. Artificial deformation and cranio-facial asymmetry in ancient Peruvians. J Dent Res. 1964 May-June;43:353-62. plagiocephalia, unilateral craniosynostosis, hypoplasic condyle, idiopathic condylar resorption or other unidentified processes. Detection timing contributes to the expression level of the asymmetry.⁷7 Pirttiniemi PM. Associations of mandibular and facial asymmetries--a review. Am J Orthod Dentofacial Orthop. 1994;106(2):191-200. Changes in position or morphology of the glenoid fossa during growth and functional changes in the mandibular condyle may also have an influence in the development of malocclusions and facial asymmetries as a morphological and functional expression of the alteration, otherwise the occlusion and dental position may modulate their own development based on the continued remodeling of the articular tissues.⁸8 Kantomaa T. The shape of the glenoid fossa affects the growth of the mandible. Eur J Orthod. 1988 Aug;10(3):249-54.

9 Poikela A, Pirttiniemi P, Kantomaa T. Location of the glenoid fossa after a period of unilateral masticatory function in young rabbits. Eur J Orthod. 2000 Apr;22(2):105-12.^-¹⁰10 Sun L, Wang M, He J, Liu L, Chen S, Widmalm SE. Experimentally created nonbalanced occlusion effects on the thickness of the temporomandibular joint disc in rats. Angle Orthod. 2009 Jan;79(1):51-3. Condylar hyperplasia (CH) is a self-limiting pathologic condition, characterized by progressive condylar overgrowth, but may generate facial deformities compromising the condylar neck and mandibular ramus. The condition is most frequently unilateral, but there have been bilateral cases reported and may be accompanied by pain, occlusal changes and articular disfunctions.¹¹11 López DF, Corral S CM. Condylar hyperplasia: characteristics, manifestations, diagnosis and treatment. A topic review. Rev Fac Odontol Univ Antioquia. 2015;26(2):425-46.^,¹²12 Wolford LM, Movahed R, Perez DE. A classification system for conditions causing condylar hyperplasia. J Oral Maxillofac Surg. 2014;72(3):567-95. Condylar asymmetry may be due to overgrowth in vertical direction, a condition known as hemimandibular hyperplasia, or horizontal, known as hemimandibular elongation, or an hybrid form of them.¹³13 Norman JE, Painter DM. Hyperplasia of the mandibular condyle. A historical review of important early cases with a presentation and analysis of twelve patients. J Maxillofac Surg. 1980 Aug;8(3):161-75.^,¹⁴14 Cohen MMJ. Perspectives on craniofacial asymmetry. III. Common and/or well-known causes of asymmetry. Int J Oral Maxillofac Surg. 1995 Apr;24(2):127-33. Each type has different clinical and radiographic morphological characteristics.¹⁵15 Nitzan DW, Katsnelson A, Bermanis I, Brin I, Casap N. The clinical characteristics of condylar hyperplasia: experience with 61 patients. J Oral Maxillofac Surg. 2008;66(2):312-8. Recent technological advances in craniofacial imaging, particularly 3D computed tomography, provide volumetric information and virtual 3D reconstructions that are valuable to more precisely visualize the TMJ, as well as to obtain differential diagnosis of these asymmetries.¹⁶16 Berco M, Rigali PHJ, Miner RM, DeLuca S, Anderson NK, Will LA. Accuracy and reliability of linear cephalometric measurements from cone-beam computed tomography scans of a dry human skull. Am J Orthod Dentofacial Orthop. 2009;136(1):17.e1-9; discussion 17-8.^,¹⁷17 Rodrigues AF, Fraga MR, Vitral RWF. Computed tomography evaluation of the temporomandibular joint in Class I malocclusion patients: condylar symmetry and condyle-fossa relationship. Am J Orthod Dentofacial Orthop. 2009 Aug;136(2):192-8. The objective of this study was to describe morphological characteristics of the mandible and the temporomandibular joint in patients with facial asymmetry using computed tomography (CT) and 3D reconstruction.

MATERIAL AND METHODS

This study was approved by the Comité de Ética en Investigación del Centro Médico Imbanaco (CEI-285) and conducted according to the principles of the Declaration of Helsinki. A retrospective observational study was performed in 43 patients who had been sent to a high complexity nuclear medicine center for a single photon emission computed tomography (SPECT/CT) test, because they had progressive facial asymmetry and a positive association of extraoral and intraoral clinical findings with radiographic signs, leading to suspicion of a UCH, between January 2015 and December 2018. Mean age was 20.7 ± 7.25 year (range:11-44 years) and 21 were women.

The institutional registry of nuclear medicine department was reviewed to identify patients with a SPECT/CT study due to a preliminary clinical diagnosis of facial asymmetry and clinically suspected UCH. Patients with antecedents of TMJ surgery, orthognathic surgery, craniofacial trauma or syndromic dentofacial anomalies were excluded.

The CT cranial images were obtained from a PET/CT Biograph mCT20 (Siemens, Erlangen, Germany), without contrast medium and under the following parameters: section width: 1.5 mm, pitch 1.0 using Care Dose (dose adjusted to patient’s weight), and a 512 x 512 cubic matrix of isotropic voxel (size: 0,58 x 0,58 x 0,87 mm) that prevents distortion of the image in the different views. The CT images were reconstructed with a B26f homogenous medium filter. All the patients were positioned with head restriction, to avoid movement artifacts and to permit the image fusion with SPECT images. The set of DICOM images was processed in a computer workstation using the Osirix software (Pixmeo, Bernex, Switzerland) v. 7.5.1. Linear measurements in sagittal, axial and coronal directions were obtained. The variables and detailed methodology are described in Table 1. All variables were compared between the affected side (producing the asymmetry) and the contralateral side (side with mandibular deviation).

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Table 1
Description of variables measured from CT images and 3D reconstruction.

Figure 1
Sagittal TMJ view. A) Measurement of condylar length and mandibular ramus length. B) Intra-articular anterior, upper and posterior spaces.

Figure 2
A) Measurement of glenoid fossa posterior wall position. B) Axial view, condylar medial and lateral pole length.

Figure 3
Frontal view: measurement of articular eminence height.

Figure 4
3-D reconstruction of bone tissues, used to measure the distance from the midpoint of mandibular symphysis to sagittal midplane (magnitude of deviation).

METHODS ERROR

The variables were obtained and processed by one expert operator. The measurements were made twice at more than 1-week intervals, without any knowledge of the previous measurements, with the objective of measuring the intraobserver reliability, and it was estimated using the intraclass correlation coefficient (ICC) (Table 2).

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Table 2
Intraobserver reliability.

STATISTICAL ANALYSIS

All analysis were conducted using Stata 13^® (StataCorp, College Station, TX, USA). Data were explored for normality using Shapiro-Wilk test. The difference between sides was expressed in mm, respecting the contralateral side (Δ= [Affected-Contralateral]). To compare if the differences were statistically different than 0, the paired t-test or Wilcoxon test was used according to the normality assumption. The correlation between variables was calculated using Spearman Coefficient; p< 0.05 was considered statistically significant.

RESULTS

A total of 19 cases with right side deviation and 24 with left side deviation were analyzed. The average mandibular deviation was higher in cases with left side deviation (left deviation: 6.2 ± 3.8 mm, right deviation: 4.5 ± 2.9 mm), however, this difference was not statistically significant (p = 0.131).

The condylar and articular morphologic differences between the affected side and the contralateral side are described in Table 3. No statistically significant differences were found between the sides regarding the anteroposterior pole, mandibular ramus length, intra-articular medial and posterior spaces, and posterior wall of the glenoid fossa (p> 0.05).

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Table 3
Comparison of morphologic measurements by side (affected / contralateral) and deviation side, in millimeters.

Condylar length (p< 0.001) and lateral pole length (p< 0.05) were greater on the affected side. The distance from the upper edge of the eminence to the reference line had lower values on the affected side, suggesting a higher superior projection of the joint eminence on the affected side (p< 0.05). Approximately 84% of the patients presented greater condylar length on the affected side and 79%, greater condylar size according to the sum of maximum values. In 61% of the cases, a higher length of the lateral pole and a greater eminence height on the affected side were observed. Although, the differences in mm of the position of the posterior wall of the glenoid fossa between the sides were not statistically significant, 67% of the cases had a greater posterior projection of the glenoid cavity on the affected side (Table 3). A positive Spearman correlation coefficient was obtained between the position of the posterior wall of the glenoid cavity and the height of the articular eminence (r = 0.442, p= 0.003).

DISCUSSION

The morphology of TMJ structures as well as the spatial disposition, remodeling during growth and adaptability to occlusal functional demands has been a constant challenge in the diagnostic and multidisciplinary treatment of malocclusions and asymmetries that compromise the middle and lower facial thirds¹⁷17 Rodrigues AF, Fraga MR, Vitral RWF. Computed tomography evaluation of the temporomandibular joint in Class I malocclusion patients: condylar symmetry and condyle-fossa relationship. Am J Orthod Dentofacial Orthop. 2009 Aug;136(2):192-8.. The principal outcome of this study suggests that there are changes in size and anatomic configuration of the mandibular condyle as well as structural adaptations in the glenoid fossa when it is affected by a process of hyperplasia that causes facial asymmetry. The diagnostic implications of these morphological changes demand from both clinicians in the areas of orthodontics and maxillofacial surgery. The knowledge and understanding of the craniofacial characteristics that distinguish the UCH from other entities that also produce facial asymmetry are relevant for an adequate diagnosis and therapeutic approach.

Previous data indicate that most cases associated with UCH are detected in young adults, but the range is initiated in preadolescence, in agreement with the reports of Wolford et al.¹²12 Wolford LM, Movahed R, Perez DE. A classification system for conditions causing condylar hyperplasia. J Oral Maxillofac Surg. 2014;72(3):567-95. UCH is usually diagnosed in its active form between 11 and 25 years of age, therefore patients with growth and development or with residual growth are always involved in the diagnostic process. Although there may be active cases in the third and fourth decade of life, the most usual is to find in this stage the disease sequel (anatomical, occlusal, functional and aesthetic alterations).¹¹11 López DF, Corral S CM. Condylar hyperplasia: characteristics, manifestations, diagnosis and treatment. A topic review. Rev Fac Odontol Univ Antioquia. 2015;26(2):425-46.

In patients with facial asymmetry, previous studies have described that the predisposition to develop TMJ internal derangements could be attributed to an adaptation process of skeletal and dentofacial structures to the mandibular displacement and the functional demands placed by the occlusal configuration.¹⁸18 Ishizaki K, Suzuki K, Mito T, Tanaka EM, Sato S. Morphologic, functional, and occlusal characterization of mandibular lateral displacement malocclusion. Am J Orthod Dentofacial Orthop. 2010;137(4):454.e1-9; discussion 454-5. The articular disorders have also been related to a reduced length of the mandibular ramus and body, reduced length in anterior and posterior cranial base and articular disk compression.¹⁹19 Flores-Mir C, Nebbe B, Heo G, Major PW. Longitudinal study of temporomandibular joint disc status and craniofacial growth. Am J Orthod Dentofacial Orthop. 2006;130(3):324-30. Additionally, the difference in height of the condyles could be a compensatory response to an abnormal remodeling of the glenoid fossa due to a pathological condition.

Disorders such as unilateral anterior displacement of the articular disk during growth and development are also likely to reduce the condylar length of the affected side, triggering asymmetry.²⁰20 Xie Q, Yang C, He D, Cai X, Ma Z, Shen Y, et al. Will unilateral temporomandibular joint anterior disc displacement in teenagers lead to asymmetry of condyle and mandible? A longitudinal study. J Craniomaxillofac Surg. 2016;44(5):590-6. Habib et al.²¹21 Habib H, Hatta T, Udagawa J, Zhang L, Yoshimura Y, Otani H. Fetal jaw movement affects condylar cartilage development. J Dent Res. 2005;84(5):474-9. and Kurita et al.²²22 Kurita H, Ohtsuka A, Kobayashi H, Kurashina K. Alteration of the horizontal mandibular condyle size associated with temporomandibular joint internal derangement in adult females. Dentomaxillofac Radiol. 2002;31(6):373-8. showed that changes in TMJ function alter the volume of the condylar head. Changes in the volume of soft tissues are related to other disorders, such as metabolic bone pathologies, including CH that may involve changes in condylar anatomy.¹¹11 López DF, Corral S CM. Condylar hyperplasia: characteristics, manifestations, diagnosis and treatment. A topic review. Rev Fac Odontol Univ Antioquia. 2015;26(2):425-46.^,¹²12 Wolford LM, Movahed R, Perez DE. A classification system for conditions causing condylar hyperplasia. J Oral Maxillofac Surg. 2014;72(3):567-95.^,²³23 Obwegeser HL, Makek MS. Hemimandibular hyperplasia--hemimandibular elongation. J Maxillofac Surg. 1986;14(4):183-208.

Goulart et al.²⁴ evaluated the condylar volume in patients with UCH compared to Class III malocclusion patients. They concluded that in UCH patients the affected condyle presented a higher volume than the contralateral condyle, while in the Class III group the condylar volume was equal for both sides. These results are similar to this study, with a higher sum of maximum values identified in the hyperplasic side.

In this study, condylar length and condylar lateral pole length were higher in the affected side. These findings are similar to those reported by Goto and Langenbach,²⁵25 Goto TK, Langenbach GEJ. Condylar process contributes to mandibular asymmetry: In vivo 3D MRI study. Clin Anat. 2014;27(4):585-91. who evaluated 40 asymmetric patients finding that the condylar size in the deviated side was significantly larger, compared with a control group. Velasquez et al.²⁶ analyzed 40 cone-beam CT images from patients with mandibular lateral deviation, evaluating craniofacial morphology. They found that mandibular body length and condylar size were larger in the deviation side, compared to the contralateral side.

On the other hand, Ishizaki et al.¹⁸ analyzed 116 bi-dimensional diagnostic images from patients with mandibular lateral deviation, relating their occlusal, functional and morphologic characteristics. They reported that the mandible presented rotation, together with condylar displacement towards the contralateral side. The condyle affected by the mandibular displacement compressed the disk against the glenoid fossa during masticatory function or parafunctional activities. Their results are contrary to the present study, as it was not found intra-articular space reduction, suggesting condylar compression in the contralateral side.

Regarding differences due to malocclusions, Katsavrias and Halazonetis²⁷27 Katsavrias EG, Halazonetis DJ. Condyle and fossa shape in Class II and Class III skeletal patterns: a morphometric tomographic study. Am J Orthod Dentofacial Orthop. 2005;128(3):337-46. studied the articular structures in Class II and Class III patients, concluding that in Class III cases the condylar sagittal position was intermediate, while in Class II division 2 cases, the vertical position of the condyle was more posterior to the glenoid fossa. They stated that condylar anatomic characteristics may be changed by continuous structural remodeling of the TMJ and symmetric condyles may be found in different kinds of malocclusion. In the present study the malocclusion class was not a variable considered.

According to the results of the present study, when the articular eminence height is increased in the affected side, there is also an increment in the posterior position of the glenoid fossa. If this is correlated to the increment in the sum of maximum values in the affected side, it may be interpreted as expression of the glenoid fossa remodeling to increase the space, when the condylar size increased in UCH situations. The same findings are reported by Huang et al.,²⁸28 Huang M, Hu Y, Yu J, Sun J, Ming Y, Zheng L. Cone-beam computed tomographic evaluation of the temporomandibular joint and dental characteristics of patients with Class II subdivision malocclusion and asymmetry. Korean J Orthod. 2017;47(5):277-88. correlating depth of the glenoid fossa with articular eminence height. The results suggest that changes in the position of glenoid fossa occur during normal growth or in pathologic conditions such as UCH, and they may have an influence on the development of a malocclusion and facial asymmetry, as morphologic and functional expressions of the alteration. On the other hand, the occlusion and dental position may modulate or adapt to the continuous remodeling of the articular morphology.⁸8 Kantomaa T. The shape of the glenoid fossa affects the growth of the mandible. Eur J Orthod. 1988 Aug;10(3):249-54.

9 Poikela A, Pirttiniemi P, Kantomaa T. Location of the glenoid fossa after a period of unilateral masticatory function in young rabbits. Eur J Orthod. 2000 Apr;22(2):105-12.^-¹⁰10 Sun L, Wang M, He J, Liu L, Chen S, Widmalm SE. Experimentally created nonbalanced occlusion effects on the thickness of the temporomandibular joint disc in rats. Angle Orthod. 2009 Jan;79(1):51-3.

A limitation of this study is that it was not possible to correlate the anatomic changes in TMJ structures with signs and symptoms of temporomandibular disfunction. Therefore, it is not known if morphologic changes in UCH patients may increase the actual risk of temporomandibular disorders either in the affected side or in its contralateral side, or if TMD may facilitate the degree of hyperplastic expression. It is suggested to perform in future studies an analysis between transversal changes in the three facial thirds and metabolic activity of condyles evaluated by SPECT, as well as histopathologic findings in patients after high condylectomyis used to treat active hyperplasia.

CONCLUSIONS

In patients with suspected UCH, evaluated through CT, craniofacial measurements showed significantly larger condylar length and the condylar sum of maximum values in the affected side. A positive correlation was found between the increased dimensions of the articular eminence and the more posterior position of the glenoid fossa in the affected side. No significant differences were detected for articular spaces or mandibular ramus height in the affected side, compared to the normal side.

Acknowledgments

The authors would like to thank the research institute Centro Médico Imbanaco, for its support during the development of this project.

REFERENCES

¹
Merigue LF, Conti ACCF, Oltramari-Navarro PVP, Navarro RL, Almeida MR. Tomographic evaluation of the temporomandibular joint in malocclusion subjects: condylar morphology and position. Braz Oral Res. 2016;30. pii: S1806-83242016000100222.
²
Valladares JV, Estrela C, Bueno MR, Guedes OA, Porto OCL, Pécora JD. Mandibular condyle dimensional changes in subjects from 3 to 20 years of age using Cone-Beam Computed Tomography: A preliminary study. Dental Press J Orthod. 2010;15(5):172-81.
³
Bayram M, Kayipmaz S, Sezgin OS, Kucuk M. Volumetric analysis of the mandibular condyle using cone beam computed tomography. Eur J Radiol. 2012 Aug;81(8):1812-6.
⁴
Severt TR, Proffit WR. The prevalence of facial asymmetry in the dentofacial deformities population at the University of North Carolina. Int J Adult Orthodon Orthognath Surg. 1997;12(3):171-6.
⁵
Kim S-J, Lee K-J, Lee S-H, Baik H-S. Morphologic relationship between the cranial base and the mandible in patients with facial asymmetry and mandibular prognathism. Am J Orthod Dentofacial Orthop. 2013;144(3):330-40.
⁶
Bjoerk A, Bjoerk L. Artificial deformation and cranio-facial asymmetry in ancient Peruvians. J Dent Res. 1964 May-June;43:353-62.
⁷
Pirttiniemi PM. Associations of mandibular and facial asymmetries--a review. Am J Orthod Dentofacial Orthop. 1994;106(2):191-200.
⁸
Kantomaa T. The shape of the glenoid fossa affects the growth of the mandible. Eur J Orthod. 1988 Aug;10(3):249-54.
⁹
Poikela A, Pirttiniemi P, Kantomaa T. Location of the glenoid fossa after a period of unilateral masticatory function in young rabbits. Eur J Orthod. 2000 Apr;22(2):105-12.
¹⁰
Sun L, Wang M, He J, Liu L, Chen S, Widmalm SE. Experimentally created nonbalanced occlusion effects on the thickness of the temporomandibular joint disc in rats. Angle Orthod. 2009 Jan;79(1):51-3.
¹¹
López DF, Corral S CM. Condylar hyperplasia: characteristics, manifestations, diagnosis and treatment. A topic review. Rev Fac Odontol Univ Antioquia. 2015;26(2):425-46.
¹²
Wolford LM, Movahed R, Perez DE. A classification system for conditions causing condylar hyperplasia. J Oral Maxillofac Surg. 2014;72(3):567-95.
¹³
Norman JE, Painter DM. Hyperplasia of the mandibular condyle. A historical review of important early cases with a presentation and analysis of twelve patients. J Maxillofac Surg. 1980 Aug;8(3):161-75.
¹⁴
Cohen MMJ. Perspectives on craniofacial asymmetry. III. Common and/or well-known causes of asymmetry. Int J Oral Maxillofac Surg. 1995 Apr;24(2):127-33.
¹⁵
Nitzan DW, Katsnelson A, Bermanis I, Brin I, Casap N. The clinical characteristics of condylar hyperplasia: experience with 61 patients. J Oral Maxillofac Surg. 2008;66(2):312-8.
¹⁶
Berco M, Rigali PHJ, Miner RM, DeLuca S, Anderson NK, Will LA. Accuracy and reliability of linear cephalometric measurements from cone-beam computed tomography scans of a dry human skull. Am J Orthod Dentofacial Orthop. 2009;136(1):17.e1-9; discussion 17-8.
¹⁷
Rodrigues AF, Fraga MR, Vitral RWF. Computed tomography evaluation of the temporomandibular joint in Class I malocclusion patients: condylar symmetry and condyle-fossa relationship. Am J Orthod Dentofacial Orthop. 2009 Aug;136(2):192-8.
¹⁸
Ishizaki K, Suzuki K, Mito T, Tanaka EM, Sato S. Morphologic, functional, and occlusal characterization of mandibular lateral displacement malocclusion. Am J Orthod Dentofacial Orthop. 2010;137(4):454.e1-9; discussion 454-5.
¹⁹
Flores-Mir C, Nebbe B, Heo G, Major PW. Longitudinal study of temporomandibular joint disc status and craniofacial growth. Am J Orthod Dentofacial Orthop. 2006;130(3):324-30.
²⁰
Xie Q, Yang C, He D, Cai X, Ma Z, Shen Y, et al. Will unilateral temporomandibular joint anterior disc displacement in teenagers lead to asymmetry of condyle and mandible? A longitudinal study. J Craniomaxillofac Surg. 2016;44(5):590-6.
²¹
Habib H, Hatta T, Udagawa J, Zhang L, Yoshimura Y, Otani H. Fetal jaw movement affects condylar cartilage development. J Dent Res. 2005;84(5):474-9.
²²
Kurita H, Ohtsuka A, Kobayashi H, Kurashina K. Alteration of the horizontal mandibular condyle size associated with temporomandibular joint internal derangement in adult females. Dentomaxillofac Radiol. 2002;31(6):373-8.
²³
Obwegeser HL, Makek MS. Hemimandibular hyperplasia--hemimandibular elongation. J Maxillofac Surg. 1986;14(4):183-208.
²⁴
Goulart DR, Munoz P, Cantin Lopez MG, de Moraes M, Olate S. Comparative Evaluation of condylar volume between patients with unilateral condylar hyperplasia and Class III dentofacial deformity. J Oral Maxillofac Surg. 2017;75(1):180-8.
²⁵
Goto TK, Langenbach GEJ. Condylar process contributes to mandibular asymmetry: In vivo 3D MRI study. Clin Anat. 2014;27(4):585-91.
²⁶
Velasquez RL, Coro JC, Londono A, McGorray SP, Wheeler TT, Sato S. Three-dimensional morphological characterization of malocclusions with mandibular lateral displacement using cone-beam computed tomography. Cranio. 2018 May;36(3):143-55.
²⁷
Katsavrias EG, Halazonetis DJ. Condyle and fossa shape in Class II and Class III skeletal patterns: a morphometric tomographic study. Am J Orthod Dentofacial Orthop. 2005;128(3):337-46.
²⁸
Huang M, Hu Y, Yu J, Sun J, Ming Y, Zheng L. Cone-beam computed tomographic evaluation of the temporomandibular joint and dental characteristics of patients with Class II subdivision malocclusion and asymmetry. Korean J Orthod. 2017;47(5):277-88.

»
Patients displayed in this article previously approved the use of their facial and intraoral photographs.

Publication Dates

Publication in this collection
29 May 2020
Date of issue
Mar-Apr 2020

History

Received
26 Feb 2019
Accepted
12 June 2019

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ¹
Merigue LF, Conti ACCF, Oltramari-Navarro PVP, Navarro RL, Almeida MR. Tomographic evaluation of the temporomandibular joint in malocclusion subjects: condylar morphology and position. Braz Oral Res. 2016;30. pii: S1806-83242016000100222.

[2] ²
Valladares JV, Estrela C, Bueno MR, Guedes OA, Porto OCL, Pécora JD. Mandibular condyle dimensional changes in subjects from 3 to 20 years of age using Cone-Beam Computed Tomography: A preliminary study. Dental Press J Orthod. 2010;15(5):172-81.

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Variable	Description
Condylar length	In the sagittal view, it was traced a line parallel to the tangent to the posterior edge of the mandibular ramus, extended from the most superior point of the condyle to a perpendicular line passing through the most inferior point of the mandibular notch (Fig. 1A). This length was obtained from a corrected plane image over the long axis of the mandibular ramus
Mandibular ramus length	In the sagittal view, it was traced a line, parallel to the tangent to the posterior edge of the mandibular ramus, extended from the most inferior point of the mandibular notch to a perpendicular line extended from the internal mandibular angle (Fig. 1A)
Intra-articular anterior space	In sagittal view, on the TMJ (center of the condyle, set in the coronal plane - orthogonal plane), it was traced a line from the most anterior edge of the condyle to the anterior wall of the glenoid fossa (Fig. 1B)
Intra-articular upper space	In sagittal view, on the TMJ (center of the condyle, set in the coronal plane - orthogonal plane), it was traced a line from the most superior edge of the condyle to the most superior point of glenoid fossa (Fig. 1B)
Intra-articular posterior space	In sagittal view, on the TMJ (center of the condyle, set in the coronal plane - orthogonal plane), it was traced a line from the most posterior edge of the condyle to the posterior wall of glenoid fossa (Fig. 1B)
Glenoid fossa posterior wall position	Taking as a reference the center of sella turcica in sagittal and axial views, on the axial plane, a perpendicular line was draw over the facial midline. The distance between this line and the posterior wall of the glenoid fossa was measure (Fig. 2A). A greater value indicates a more posterior position and a lower value, an anterior position
Condylar anteroposterior pole length	In the axial view, it was traced a line from the most anterior edge of cortical bone to the most posterior edge of condylar cortical bone (Fig. 2B). This image was obtained in an orthogonal plane
Condylar mediolateral pole length	In the axial view, it was traced a line from the most anterior edge of condyle proximal cortical to the most anterior edge of condylar distal cortical (Fig. 2B). This image was obtained in an orthogonal plane
Sum of maximum values	Obtained by adding the values of the condylar length with the condylar anteroposterior pole length and the condylar lateral pole length, representing the condylar size in its maximum values
Articular eminence height	In the frontal view, taking as reference a line crossing the anatomic point sella turcica (parallel), it was traced a perpendicular from the most superior medial cortical edge of the articular eminence to the reference line (Fig. 3). A lower value represents a more superior position of the articular eminence height and a higher value, the opposite
Deviation from the symphysis midpoint	Distance from menton point to a line extended to the lower third, projected from the middle part of crista galli apophysis, perpendicular to bizygomatic line in the reconstruction 3-D image of bone tissues (Fig. 4)
Laterognathia (side of mandibular deviation)	Visual qualitative variable indicating direction of the mandibular deviation (right/left). Observed in the reconstruction 3D image of bone tissues (Fig. 4)

Variable	ICC	ICC
Variable	Right side	Left side
Condylar length	0.963	0.985
Ramus length	0.966	0.982
Anteroposterior pole length	0.976	0.944
Mediolateral pole length	0.955	0.962
Glenoid fossa posterior wall	0.997	0.998
Eminence medial height	0.989	0.991
Intra-articular antero-superior space	0.762	0.623
Intra-articular medial space	0.904	0.899
Intra-articular upper posterior space	0.905	0.870

Variables	Affected side	Contralateral side	Difference	P value	Δ>0 n (%)
Condylar length
Mean ± SD	22.8±3.1	20.1±2.9	2.7±2.4	0.000***	36 (83.7%)
(Range)	(16.5; 30.6)	(14.9; 26.5)	(-1.4; 8.5)	0.000***	36 (83.7%)
Anteroposterior pole
Mean ± SD	7.9±1.2	7.6±1.3	0.3±1.1	0.097*	-
(Range)	(5.9;11.1)	(5.3;10.6)	(-2.0;2.9)	0.097*	-
Mediolateral pole
Mean ± SD	17.3±2.3	16.7±2.6	0.6±1.9	0.039**	26 (60.5%)
(Range)	(12.8;22.0)	(11.5;23.3)	(-3.7; 5.5)	0.039**	26 (60.5%)
Sum of maximum values
Mean ± SD	48.1±4.3	44.4±4.7	3.7±3.8	0.000***	34 (79.1%)
(Range)	(38.9; 57.3)	(35.5;54.8)	(-4.0; 12.0)	0.000***	34 (79.1%)
Mandibular ramus
Mean ± SD	34.4±4.1	34.21±4.4	0.2±3.0	0.668	-
(Range)	(24.3;42.1)	(24;43.4)	(-5.6;6.6)	0.668	-
Eminence height
Mean ± SD	14.0±4.2	14.5±4.1	-0.5±1.6	0.029**	26 (60.5%)
(Range)	(4.7; 24.4)	(5.0; 23.9)	(-3.6; 2.8)	0.029**	26 (60.5%)
Glenoid fossa posterior wall
Mean ± SD	19.9±5.9	19.3±6.3	0.6±3.9	0.308	28 (66.7%)
(Range)	(10.5; 31.6)	(7.2; 31.5)	(-8.7; 9.5)	0.308	28 (66.7%)
Intra-articular anterior space
Mean ± SD	2.3±0.8	2.4±0.8	-0.1±1.0	0.551	-
(Range)	(1.0; 4.2)	(1.2; 4.7)	(-2.5; 1.4)	0.551	-
Intra-articular medial space
Mean ± SD	1.8±0.7	2.0±0.8	-0.2±0.7	0.104	-
(Range)	(0.6; 3.5)	(0.6; 4.0)	(-2.0; 1.6)	0.104	-
Intra-articular posterior space
Mean ± SD	2.8±1.1	2.8±1.0	-0.0±1.0	0.642	-
(Range)	(1.2; 5.5)	(0.9; 5.6)	(-2.1; 1.8)	0.642	-

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Mandibular and temporomandibular morphologic characteristics of patients with suspected unilateral condylar hyperplasia: a CT study

ABSTRACT

Introduction:

Objective:

Methods:

Results:

Conclusions:

RESUMO

Introdução:

Objetivo:

Métodos:

Resultados:

Conclusão:

INTRODUCTION

MATERIAL AND METHODS

METHODS ERROR

STATISTICAL ANALYSIS

RESULTS

DISCUSSION

CONCLUSIONS

Acknowledgments

REFERENCES

Publication Dates

History