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International Journal of
eISSN: 2574-8084

Radiology & Radiation Therapy

Research Article Volume 5 Issue 1

Incidental findings in pretreatment and post-treatment orthodontic panoramic radiographs

Wilson Gustavo Cral, Mariana Quirino Silveira, Izabel Regina Fischer Rubira-Bullen, Ana Lúcia Alvares Capelozza

Department of Stomatology, University of São Paulo, Bauru, Brazil

Correspondence: Wilson Gustavo Cral, Department of Stomatology, Bauru School of Dentistry, University of São Paulo, Al. Octávio Pinheiro Brisola, Cidade Universitária, 9-75, Zip Code- 17012-90, Bauru- São Paulo, Brazil, Tel +55(14)3235-8000

Received: January 22, 2018 | Published: February 12, 2018

Citation: Cral WG, Silveira MQ, Rubira-Bullen IR, et al. Incidental findings in pretreatment and post-treatment orthodontic panoramic radiographss. Int J Radiol Radiat Ther. 2018;5(1):46-50. DOI: 10.15406/ijrrt.2018.05.00132

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Abstract

Panoramic radiographs are the most requested imaging exams in dentistry and an essential part of the documentation used by orthodontists in treatment planning. Alterations that modify bone density and the trabecular bone pattern can be finding in panoramic radiographs before and after the orthodontic treatment. Furthermore, the transition between the mixed to the permanent dentition is a complex process that can incur in fails and odontogenic anomalies. The identification of incidental findings that may demand specific dental or medical treatment is important to provide satisfactory dental care. Material and methods: The aim of this study was to evaluate panoramic radiographs obtained before and after the orthodontic treatment in order to identify the most prevalent incidental findings. Five hundred panoramic radiographs (250 pretreatment and 250 post-treatment) from patients between eleven and eighteen-years-old obtained between 2005 and 2015 were selected from the archives of the Department of Orthodontics, Bauru School of Dentistry, and University of São Paulo. The image analysis was performed by one single examiner. Results: The incidence of impacted teeth and supernumerary teeth was significant higher in the pretreatment group (p<0.05). The incidence of root dilacerations, osteosclerosis and the presence of orthodontic retainers was significant higher in the post-treatment group (p<0.05). Apical remodeling in the incisors was observed in 180 patients in the post-treatment group. Conclusion: In conclusion, clinical relevant incidental findings were observed in both groups. Special care should be taken while evaluating post-treatment radiographs to diagnosis alterations that may require intervention or interfere in other dental treatments.

Keywords: dental radiology, incidental findings, orthodontics

Introduction

Panoramic radiographs provide proper information for most oral surgery procedures panning, for the evaluation of orthodontic treatments progress, for growth and development of children follow up and for oral health surveys in specific populations. Furthermore, the panoramic imaging allows the complete visualization of dental and bone anatomic landmarks and structure in the maxilla and mandible.1 Panoramic radiographs associated with clinical examination are used in orthodontic diagnosis and treatment plan. These radiographs are essential to evaluate teeth eruption, and are an instrument for the detection of pathologies in the jaws.2

During the panoramic radiography imaging interpretation, there is the possibility for the dentist to identify radiographic findings unrelated to the main reason of the imaging examination or to the patient’s complaint. The incidental findings on panoramic radiographs for orthodontic purposes are of special interest to the clinician. In many cases these findings may indicate pathologies that require other dental or medical interventions or can modify the initial treatment plan.2

Eight per cent of the orthodontic patients are at age of transition between the mixed to the permanent dentition, a period in which dental anomalies findings are frequent. Bondemark, (2006) analyzed 496 pretreatment panoramic radiographs from orthodontic patients. Incidental findings were reported in 43 patients. Osteosclerosis, apical endodontic lesion, dentigerous cyst, odontoma, tooth morphologic alterations and alveolar bone reabsorption were observed.2 The data regarding the prevalence of incidental findings in post-treatment follow up radiographs is scarce.

The aim of this study was to investigate the type and frequency of incidental findings in the maxillofacial region of panoramic radiographs obtained for orthodontic treatment purposes. Images obtained before and after orthodontic treatment were evaluated and the incidence of the findings in both groups was compared.

Materials and methods

This study was approved by the Ethics Committee of the Bauru School of Dentistry (protocol n. 970,779). Panoramic radiographs from patients treated with fixed orthodontic appliances from 2005 to 2015 were selected from the archives of the Department of Orthodontics, Bauru School of Dentistry, University of São Paulo. The samples were selected giving priority to the most recent records in order to obtain panoramic radiographs of higher quality. Two hundred and fifty dental records of patients with complete orthodontic documentation, pre- and post-orthodontic treatment were selected. A total of five hundred panoramic radiographs were analyzed.

Inclusion criteria for selection were complete radiographic documentation; patients aged 11-18years that underwent treatment with fixed orthodontic appliances; exams that have good quality in the image. Cases with incomplete radiographic documentation, presence of artifacts in the region to be examined were excluded.

After selection, the panoramic radiographs were divided in two groups with 250 images: Group A: pretreatment; Group B: post-treatment. When necessary radiographic images taken between the beginning and end of treatment (panoramic or periapical) were used to confirm or exclude a diagnostic hypothesis. Previous to the radiograph analysis, a group of images randomly selected were interpreted both for the examiner and one experienced radiologist in order to have agreement in the diagnosis. For the main image analysis was performed by one single examiner.

Dental Agenesis was considered only when the primary tooth was present and the germ/permanent tooth was absent in the panoramic radiograph; Enamel Pearls were identified using the panoramic radiograph and, when available, periapicals. The criteria for diagnosis of impacted tooth were: lack of space in the dental arch, abnormal position of the tooth germ, presence of obstacles in the eruption path. The external root resorption finding was considered for posterior teeth. Orthodontic containments, plates and screws were classified as present (1) or absent (0). Orthodontic apical root remodeling: Diagnosed as the roundness of the root apex specially in the anterior teeth and classified as present (1) or absent (0).

After one month, 10% of the total sample was randomly selected and analyzed again to perform the intra-examiner agreement text. The images were interpreted with the aid of a light box in a room with proper lighting. The Kapa test was performed to evaluate the intra-observer agreement. The Kappa test showed an agreement of 0.97. The Wilcoxon test was performed to compare the findings pre and post-treatment, adopting the significance level α=0.05. Continuous variables are reported as means±standard deviation (SD).

Results and discussion

From the patients selected, 141 were females and 109 males. The mean age was 14.5±2.29. In group A 169 patients were between 11 and 13years-old and 80 between 14 and 17years-old. In group B 26 patients were between 11 and 13year-old, 129 between 14 and 17years-old and 95 patients were older than 17years-old.

Some of the incidental findings were present in group A but not B, while others were present in both groups or just in group B. The findings distributions are described in Table 1 & 2.

 

Group A

Group B

 

Incidental Finding

Total Number of Findings

Panoramic Radiographs

Total Number of Findings

Panoramic Radiographs

p

 

 

n

%

 

n

%

 

Dental Agenesis

24

10

4.0

22

9

3.6

0.414

Impacted tooth

11

11

4.4

0

0

0

0.001

Supernumerary tooth

8

5

2.0

0

0

0

0.039

Dilacerated root

54

39

15.6

73

48

19.2

0.049

Hypercementosis

1

1

0.4

6

5

2.0

0.059

Microdontia

1

1

0.4

6

3

1.2

0.102

Enamel pearls

2

2

0.8

8

6

2.4

0.063

Table 1 Presence of dental anomalies incidental findings in group A and B. Bold values= p<0.05

 

Group A

Group B

 

Incidental Finding

Total Number of Findings

Panoramic Radiographs

Total Number of Findings

Panoramic Radiographs

p

 

 

n

%

 

n

%

 

Supernumerary root

0

0

0

1

1

0.4

0.317

Apical endodontic lesion

1

1

0.4

4

4

1.6

0.180

Dental pulp stones

4

4

1.6

9

7

2.8

0.096

Root reabsorption (internal/external)

4

3

1.2

9

6

2.4

0.187

Orthodontic containments

0

0

0

211

211

84.4

0.000

Dental implant

0

0

0

3

2

0.8

0.180

Plates and screws

1

1

0.4

2

2

0.8

0.317

Orthodontic apical root remodeling

0

0

0

180

180

72.0

0.000

Osteosclerosis

20

19

7.6

31

30

12.0

0.048

Dentigerous cyst

1

1

0.4

0

0

0

0.317

Composite odontoma

1

1

0.4

0

0

0

0.317

Table 2 Presence of endodontic findings, metallic materials, orthodontic apical root remodeling, osteosclerosis and odontogenic pathologies in group A and B. Bold values= p<0.05

Panoramic radiography allows evaluating lesions in the jaws, the relationship of the teeth to each other, the number and location of intraosseous teeth, among other alterations. Easy access to the examination and the radiation doses four to six times lower, when compared with full-mouth series of periapical projections, are advantages of this method. The aim of this study was to evaluate the presence of radiographic findings, with clinical implications in panoramic radiographs performed at the beginning and end of orthodontic treatment. Several of the alterations observed were possibly found only in view of this opportunity to obtain a panoramic radiograph, which may be considered as incidental findings. The highest prevalence of the findings occurred in the post-orthodontic treatment radiographs, highlighting the clinical importance that the orthodontic apical remodeling plays during the evolution of orthodontic treatment, even representing an indication of clinical success.3

The increase of osteosclerosis lesions was observed in the post-treatment group, rising the questioning regarding its relation with the orthodontic movement. It is known that the cause of osteosclerosis is idiopathic. The information regarding the role of the orthodontic movement on its etiology is still controversial and scarce in the literature. The bone that composes these areas of osteosclerosis has normal structure and functioning, and the difference lies in its greater trabecular density. Therefore, it is possible to move teeth, apply mini-implants and osseointegrated implants in these areas, as long as these radiopaque images are not related to teeth without pulp vitality. The idea is to use forces of lesser intensity than those conventionally applied. The decrease in force corresponds to a compensation, since, due to the higher local bone density, bone deflection does not occur. Thus, there will be a normal movement, even in the densest area.4,5 However, bone remodeling may take longer because bone trabeculae are thicker and the medullary spaces are reduced.5

Pretreatment radiographic examination allows the identification of possible alterations that may influence the orthodontic treatment planning. Among these alterations one can mention conditions with need for restorative, endodontic, periodontal or surgical treatments; diagnosis of dental agenesis; supernumerary teeth; root resorption, which may definitively require previous intervention. Additionally, the evaluation after the orthodontic treatment allows a comparison with the initial condition and the identification of the alterations that arose as a result of the orthodontic interference and its respective clinical implication. Thus, in this study we evaluated radiographs taken before and after treatment.

In this study, 56.4% of the patients were female and 43.6% were male. Most patients start orthodontic treatment between 11 and 13years (67.9%), and they finish between 14 and 16years (51.6%). Granlund (2012) investigated a similar population. The authors evaluated 1278 panoramic radiographs from young patients (530 males and 757 females) with mean age of 14years-old. The presence of incidental findings in the patients with mixed dentition (i.e. supernumerary teeth) was reported.6

In this research there was a significant reduction of supernumerary teeth and impacted teeth in the post-treatment radiographs. If the supernumerary teeth are partially or totally erupted, they may cause retention of dental biofilm, influence periodontal health and dental alignment. Supernumerary teeth may also interfere in the occlusion and should be extracted whenever they could impair the development of adjacent teeth.7,8 Impacted teeth also have an indication of extraction for the prevention of dental ankyloses and root resorption due to the proximity between the roots. The possibility of cystic or neoplastic transformation of the remaining dental follicle should also be considered.8

Other dental anomalies, such as enamel pearl, root laceration, supernumerary root, microdontia and hypercementose were more numerous after orthodontic treatment. However, studies that related their occurrence with orthodontic treatment are not available. The supernumerary root does not require treatment, however, its identification is important for the planning of dental procedures.9 Regarding the higher number of root dilacerations in the post-treatment radiographs, it is possible that this result is related to the complete formation of the roots, which can be observed in higher numbers at the end of orthodontic treatment. The presence of hypercementosis may hamper orthodontic movement and cause clinical and technical peculiarities, such as the need to apply maneuvers for bracket angulation. The presence of hypercementosis does not appear to be strictly aggravating during orthodontics, but requires that the clinician be aware of the evolution of each specific case.10

In this study, 4 images compatible with external radicular resorption were observed in 3 patients (1.2%) in the pre-treatment group and 9 images in 6 patients (2.4%) in the post treatment group. External root resorption and its progression may be related to orthodontic treatment. The main related factors to be considered are: duration, intensity, application method and direction of the force movement; As well as genetics; Systemic diseases; Root morphology and local traumas. During induced tooth movement, the applied force can compress the periodontal ligament and, consequently, cause the death of cementoblasts, causing the osteoblasts to occupy the root surface, thus initiating the dental resorption associated with orthodontic movement.11 Han (2005) stated that tooth intrusion causes four times more root resorption than extrusion. Levander (1998) stated that root resorption is significantly higher in patients submitted to continuous orthodontic movement compared to the ones whose orthodontics is performed with pauses, which allows cement recovering. The treatment of external root resorptions in patients undergoing orthodontic treatment it is based on the principle that removal of the cause interrupts the process. The inflammatory dental resorption ceases after a week of disruption of the forces applied to the tooth.12 However, chronic lesions are able to promote erosions in the cementum and the root apex region, causing a necrotic material retention preventing the reparative process. In such cases endodontic treatment is suitable.13,14

Unless not statistical significantly, in the post-treatment group a higher incidence of dental pulp stones was observed. Over time, the dental pulp undergoes physiological changes due to its aging. With the influence of other factors such as caries, periodontal disease and traumatisms, the deposition of mineralized tissue in the form of nodules in the interior of the pulp cavity may occur. The relation between the presence of pulp nodules and orthodontic movement was reported, however, most authors believe that its occurrence is associated with the predisposition of factors resulting from the pulp physiological aging process.15‒17

One image that suggests a dentigerous cyst and one odontoma were observed in the sample investigated. Carvalho (2010) reported that 42.2% of the dentigerous cysts were present in images of patients between 11 and 20years-old. This age ranges close to the age of the patients included in this study.18 The dentigerous cyst can inhibit the eruption of the tooth involved.19 In the case observed in the sample, the involved tooth was extracted and the lesion treated before orthodontic treatment began. Among the benign tumors of the mouth, odontoma is the most common. It develops in patients younger than 20years-old, during the odontogenesis process.20,21 Composite odontoma has lower growth potential than the complex. Usually, odontoma is associated with permanent non-erupted teeth and is the most common odontogenic tumors associated with delays in tooth eruption. In such cases of treatment with surgical removal is important.20,22 Is important to highlight that these lesions should be submitted for histopathological examination for diagnosis.

Metalic devices, such as dental implants and orthodontic containments, were observed in the post-treatment group. Orthodontic restraint is part of post-treatment in order to prevent crowding recurrence, especially in lower incisors. Dental implants can be part of rehabilitating treatments, however treatment costs, cultural differences, comfort, age and service accessibility need to be considered.23 The use of plates and screws in orthognathic surgery respects a treatment sequence, since orthodontic diagnosis and planning are fundamental for the isolated or joint correction of the skeletal discrepancies of the jaws.24,25

The orthodontic apical remodeling was observed in 180 charts in the posttreatment images, which is clinical relevant information. The forces of tooth movement provoke the activation of osteoclasts through the modulation pathway of inflammation that, after exceeding a certain threshold, cause the replacement of cells of the periodontal ligament by osteoblasts, initiating a process of root resorption, also called orthodontic apical remodeling,3 in this study observed mainly in the anterior region. There are studies that investigate which genetic factors play an important role in their occurrence. In particular, if there is an increase in interleukin-1 (IL-1) alpha and beta, a chemical mediator involved in the processes of bone and tooth resorption found in periodontal tissues.26 Al-Qawasmi26 reported that the polymorphism in the IL-1 beta gene was responsible for 15% of the total variation of the orthodontic apical remodeling in the upper central incisors, and the other dental groups did not present a statistically significant association.

This article reports a retrospective investigation performed only with the information obtained in the radiographic examinations. Other information that could improve the diagnosis has not been investigated. In addition, panoramic x-ray may show 15-25% image distortion. Although aware of these limitations, this research obtained an important epidemiological data, which may alert the professionals to the clinical and radiographic control of patients during and after orthodontic treatment. Future studies that could accompany all stages of orthodontic treatment, from clinical examination, radiographic imaging, treatments, and could explore the relationship between clinical and radiographic diagnosis, should be encouraged.

Conclusion

In this study it was possible to observe in the pre-treatment radiographs the presence of important findings for the diagnosis and planning of orthodontic treatment. Some of them requiring specific treatments, such as: dentigerous cyst and composite odontoma, in addition to retained and supernumerary teeth. The greatest number of incidental findings was present in the radiographs taken after orthodontic treatment. The apical orthodontic remodeling was present in the majority of the patients and requires clinical and radiographic follow-up. The comparison between these two moments is extremely important because certain alterations may have their etiologies related or not to orthodontic therapy. The clinician should pay special attention to incidental findings while following-up of each patient.

Acknowledgements

None.

Conflict of interest

I declare that there are no conflicts of interest between the authors of the article entitled "Incidental findings on pre-treatment and post-treatment orthodontic panoramic radiographs".

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