|Year : 2018 | Volume
| Issue : 3 | Page : 47-50
Changes in the mandibular arch after rapid maxillary expansion in children: A three-dimensional analysis using digital models
Ariel Adriano Reyes Pacheco1, Ademir Franco2, Oscar Mario Antelo3, Matheus Melo Pithon4, Orlando Motohiro Tanaka5
1 Pontifícia Universidad Católica Madre and Maestra; Pontifícia Universidade Católica do Paraná, School of Life Sciences, Curitiba, Brazil
2 Department of Stomatology, Federal University of Paraná (UFPR), Curitiba, Brazil
3 Pontifícia Universidade Católica do Paraná, School of Life Sciences, Curitiba, Brazil; Master in Orthodontics, Universidad Intercontinental, Cidade de Mexico, Mexico
4 Southwest Bahia State University – UESB; Diplomate of Brazilian Board of Orthodontics and Dentofacial Orthopedics, Vitória da Conquista, Bahia, Brazil
5 Pontifícia Universidade Católica do Paraná, School of Life Sciences, Curitiba; Diplomate of Brazilian Board of Orthodontics and Dentofacial Orthopedics, Vitória da Conquista, Bahia, Brazil
|Date of Web Publication||19-Sep-2018|
Dr. Orlando Motohiro Tanaka
Pontifícia Universidade Católica Do Paraná, R. Imaculada Conceição, 1155, Curitiba, PR
Source of Support: None, Conflict of Interest: None
Objective: This retrospective study quantitatively evaluated and compared the change in distance between mandibular first molars before and after rapid maxillary expansion (RME) using digital models. Materials and Methods: Twenty-seven (n = 27) plaster models (16 females and 11 males, between 6 and 9 years old) from patients treated at the Interceptive Orthodontic Clinic of the Pontifical Catholic University of Paraná (PUCPR, Curitiba, Brazil) were used. The initial (T1) and final (1 year after, T2) dental casts were scanned. The distances between the mandibular first molars were measured and compared using Geomagic Foundation software (Rock Hill, SC, USA). The central fossa of each mandibular molar was used as the reference point. The mandibular arch perimeter was measured using Orthoviewer (3Shape, Copenhagen, Denmark). Results: The intermolar width increased by 0.23 mm and by 0.75 mm in the arch perimeter. In two patients the intermolar width increased more than 2 mm, and in five patients the values from the initial measurements decreased. Conclusions: RME does not increase mandibular intermolar width distance or the mandibular arch perimeter in growing patients treated with Haas-type palatal expanders when evaluated using digital models.
Keywords: Digital model, posterior crossbite, rapid maxillary expansion
|How to cite this article:|
Pacheco AA, Franco A, Antelo OM, Pithon MM, Tanaka OM. Changes in the mandibular arch after rapid maxillary expansion in children: A three-dimensional analysis using digital models. Eur J Gen Dent 2018;7:47-50
|How to cite this URL:|
Pacheco AA, Franco A, Antelo OM, Pithon MM, Tanaka OM. Changes in the mandibular arch after rapid maxillary expansion in children: A three-dimensional analysis using digital models. Eur J Gen Dent [serial online] 2018 [cited 2021 May 6];7:47-50. Available from: https://www.ejgd.org/text.asp?2018/7/3/47/241555
| Introduction|| |
Maxillary posterior crossbite is detectable in the deciduous dentition of nearly 20.81% of the child population., This transverse discrepancy does not self-correct, whether it is functional or skeletal, unilateral, or bilateral.,,
Rapid maxillary expansion (RME) is indicated in patients with posterior crossbite to correct the transversal discrepancy between arches by opening the midpalatal suture and expanding the maxillary molars. The effects of this procedure on the mandibular arch are not well understood. Some researchers believe that the intermolar width and arch perimeter increase due to better positioning of the tongue over the mandibular arch, leading to a physiological expansion as a result of the RME. Others contend that no association exists between the procedures.
Measurements performed on digital casts have been described as reliable for orthodontic purposes, with the advantages of consuming less storage space and being easy to manipulate for the study., The advantages of digital casts include the possibility of more precise analysis, the reduced need for storage, and the ease of handling, sharing, and forwarding them.
The objective of this retrospective study was to evaluate and compare the changes in distance between mandibular first molars and mandibular arch perimeters, before and after RME, using digital models.
| Materials and Methods|| |
Fifty-four (n = 54) dental casts of initial (T1) and 1 year later (T2) representations from 27 (n = 27) patients (16 females and 11 males, between the ages of 6 and 9 years) who received RME treatment were digitized with a 3shape R700 model scanner (3shape A/S, Copenhagen, Denmark).
All the patients presented mixed dentition, with permanent maxillary and mandibular first molars and central incisors erupted before the start of treatment. All cases were treated with banded Haas-type expanders on the maxillary first molars to correct the maxillary posterior crossbite. Treatment took place at the Interceptive Orthodontic Clinic of the Pontifical Catholic University of Paraná (PUCPR, Curitiba, Brazil). The activation protocol comprised two turns at the installation appointment and later, the patient's parents were instructed to activate the appliance twice a day, with 1/4 turn in the morning (0.25 mm) and 1/4 turn (0.25 mm) in the evening, until correction of the posterior crossbite was achieved, that is, when the palatal cusps of the maxillary first molars occluded buccally of the mandibular first molars, as stated in previous studies., An occlusal X-ray was used to assess suture opening and bone formation in the retention period.
The appliance was left in place for 6 months for retention, and T2 documentation was performed 1 year after the initial record, T1.
The distances between the first mandibular molars were measured and compared using Geomagic Foundation (3D Systems, Rock Hill, SC, USA). The central fossa of each mandibular molar was used as the reference point. The mandibular arch perimeter was measured using Orthoviewer (3Shape, Copenhagen, Denmark) [Figure 1], [Figure 2], [Figure 3]. The entire sample was remeasured 4 weeks later, to perform the intraclass correlation of the two variables.
The Shapiro-Wilks test was performed to evaluate the normal distribution of the data. The mean and standard deviations were calculated as descriptive statistics. Paired Student's t-tests of the means were performed to evaluate the intermolar width and arch perimeter changes, before and after RME treatment (T1–T2). The significance level was set at 5% (P < 0.05).
| Results|| |
In this study, 16 females and 11 males (aged 6–9 years ) were treated with RME. After treatment, the intermolar width and mandibular arch perimeters of T1 and T2 presented a strong correlation, as shown in [Table 1]. The intermolar width predominantly increased by 0.23 mm (±0.02 mm), with two patients presenting an increase of more than 2 mm and five presenting decreased values compared to the initial measurements. The mandibular arch perimeter predominantly increased by 0.38 mm (±0.48 mm) in 11 patients, remained the same in eight, and decreased in eight. We found no statistically significant difference in the mean changes of the variables [Table 2]. [Figure 4] and [Figure 5] show the similarity between the before and after RME measurements of the samples.
|Table 2: Comparison of changes in mandibular intermolar width and mandibular arch perimeter after rapid maxillary expansion|
Click here to view
|Figure 4: Changes in initial (T1) and 1 year later (T2) mandibular intermolar width|
Click here to view
|Figure 5: Changes in initial (T1) and 1 year later (T2) mandibular arch perimeter|
Click here to view
| Discussion|| |
In recent years, digital casts have been widely used for studying the outcomes of RME. The average differences in measurements performed on plaster models versus digital images have been reported as 0.27 mm, ranging between 0.16 and 0.38 mm. This can be explained by operator error during both manual measurement or when placing the point of the measuring tool used in the software. Consequently, casts can be used effectively as research specimens for orthodontic purposes.
McNamara et al. found greater orthopedic results in growing patients treated with Haas appliances before the growth spurt, rather than in those treated a short time after. In the present study, all of the patients were growing patients treated with Haas expanders, which could have led to a more pronounced orthopedic result in the maxillary arch, with a greater amount of expansion of the mandibular arch, but this was not observed, at least not 1 year after the initial record, and after RME treatment.
McNamara et al. evaluated the effects of treatment using RME on growing patients who were subsequently treated with fixed appliances and compared them to a control group. They found an increase of 1–2 mm in the arch width. In the present study, the patients did not receive any active expansion appliances on the mandibular arch during the study, which is different to McNamara et al. study, where their treated patients were submitted to fixed orthodontic treatments after RME, after which comparisons were made. They found an overall increase in the mandibular arch perimeter of 1.5 mm after RME. In our sample, the mandibular arch perimeter increased by only 0.75 mm after RME treatment, half of what had previously been reported, probably because our sample did not receive fixed appliance treatment after RME, during the follow-up.
A previous study used the centroid and mesial buccal cusps as references in photographs of cast models to evaluate changes in mandibular arch width in patients treated with bonded and banded appliances. The centroid-centroid distance increased by 1.35 mm in the banded group. The present study also used the centroid as the reference in the digitized models; we found an increase of only 0.23 mm, which was not statistically significant (according to the paired t-test), and in contrast to the results from the photographic study.
The buccal and lingual alveolar surfaces, near the dentition, seem to be inappropriate as reference areas for superimposing three-dimensional mandibular digital models of patients without a mandibular torus.
In this study, intermolar width did not significantly increase, although this was expected to occur because the support of a more vestibular force vector should have produced a vertical position of the mandibular molars, as has been described in other studies.,, The present study did not find such an increase; however, our retention period was 6 months, and the T2 documentation was performed 1 year after the initial record-sufficient time for the maxillary arch to expand the lower teeth. The same conclusion was reached by Wertz,, who found that, after measuring the intermolar distance in frontal radiographs in a 60-patient sample, the measurements of 35 patients remained stable, 12 increased between 0.5 and 2 mm, and 1 decreased. Gryson also found no association between maxillary molar expansion and mandibular intermolar distance.
Nowadays, by incorporating the use of intraoral scanners and digital dental models in surface measurements along curved lines, and in three dimensions, and applying these in clinical practice, the time and cost of making impressions and sending them to the laboratory are minimized. The limitation of this study is, however, that a correlation between the amount of maxillary expansion and the intermolar distance was not performed. This procedure was performed by Gryson on plaster models; the results showed no differences between T1 and T2, and this variable did not correlate with maxillary expansion.
| Conclusions|| |
Observations from the present study suggest that RME does not increase the mandibular intermolar width distance, or the mandibular arch perimeter, in growing patients treated with Haas-type appliances, as evaluated using digital models.
Financial support and sponsorship
Conflicts of interest
There are no conflicts of interest.
| References|| |
Silva Filho Od, Silva P, Rego M, Capelozza Filho L. Epidemiology of the posterior crossbite in the primary dentition. J Bras Odontopediatr Odontol Baby 2003;6:61-8.
da Silva Filho OG, Santamaria M Jr., Capelozza Filho L. Epidemiology of posterior crossbite in the primary dentition. J Clin Pediatr Dent 2007;32:73-8.
Godoy F, Godoy-Bezerra J, Rosenblatt A. Treatment of posterior crossbite comparing 2 appliances: A community-based trial. Am J Orthod Dentofacial Orthop 2011;139:e45-52.
Pinto AS, Buschang PH, Throckmorton GS, Chen P. Morphological and positional asymmetries of young children with functional unilateral posterior crossbite. Am J Orthod Dentofacial Orthop 2001;120:513-20.
Tanaka O, Orellana B, Ribeiro G. Singular aspects to operate rapid palatal expansion procedures. Rev Dent Press Ortodon Ortop Facial 2004;9:98-107.
Bishara SE, Staley RN. Maxillary expansion: Clinical implications. Am J Orthod Dentofacial Orthop 1987;91:3-14.
Oliveira D, Ruellas A, Drummond M, Pantuzo M, Lanna A. Reliability of three-dimensional digital casts as a diagnostic tool for orthodontic treatment planning: A pilot study. Rev Dent Press Ortodon Ortop Facial 2007;12:84-93.
Bell A, Ayoub AF, Siebert P. Assessment of the accuracy of a three-dimensional imaging system for archiving dental study models. J Orthod 2003;30:219-23.
Rossini G, Parrini S, Castroflorio T, Deregibus A, Debernardi CL. Diagnostic accuracy and measurement sensitivity of digital models for orthodontic purposes: A systematic review. Am J Orthod Dentofacial Orthop 2016;149:161-70.
Haas A. Rapid expansion of the maxillary dental arch and nasal cavity by opening the midpalatal suture. Angle Orthod 1961;3:73-90.
Melgaço CA, Columbano Neto J, Jurach EM, Nojima Mda C, Sant'Anna EF, Nojima LI, et al
. Rapid maxillary expansion effects: An alternative assessment method by means of cone-beam tomography. Dental Press J Orthod 2014;19:88-96.
McNamara JA Jr., Baccetti T, Franchi L, Herberger TA. Rapid maxillary expansion followed by fixed appliances: A long-term evaluation of changes in arch dimensions. Angle Orthod 2003;73:344-53.
Catherine L, Miller C, Araújo E, Behrents R, Oliver D, Tanaka O. Mandibular arch dimensions following bonded and banded rapid maxillary expansion. J World Fed Orthod 2014;3:119-23.
An K, Jang I, Choi DS, Jost-Brinkmann PG, Cha BK. Identification of a stable reference area for superimposing mandibular digital models. J Orofac Orthop 2015;76:508-19.
Ugolini A, Cerruto C, Di Vece L, Ghislanzoni LH, Sforza C, Doldo T, et al
. Dental arch response to haas-type rapid maxillary expansion anchored to deciduous vs permanent molars: A multicentric randomized controlled trial. Angle Orthod 2015;85:570-6.
Wertz RA. Skeletal and dental changes accompanying rapid midpalatal suture opening. Am J Orthod 1970;58:41-66.
Gryson JA. Changes in mandibular interdental distance concurrent with rapid maxillary expansion. Angle Orthod 1977;47:186-92.
Mack S, Bonilla T, English JD, Cozad B, Akyalcin S. Accuracy of 3-dimensional curvilinear measurements on digital models with intraoral scanners. Am J Orthod Dentofacial Orthop 2017;152:420-5.
[Figure 1], [Figure 2], [Figure 3], [Figure 4], [Figure 5]
[Table 1], [Table 2]