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796 
Original Article 

Biosci. J., Uberlândia, v. 32, n. 3, p. 796-804, May/June. 2016 

CONE-BEAM COMPUTED TOMOGRAPHY EVALUATION OF 
DENTOSKELETAL EFFECTS PRODUCED BY THE BONDED EXPANDER 

AND HYRAX: A PILOT STUDY 
 
AVALIAÇÃO POR TOMOGRAFIA COMPUTADORIZADA DE FEIXE CÔNICO DOS 
EFEITOS DENTOESQUELÉTICOS PRODUZIDOS PELO EXPANSOR COLADO E 

HYRAX: UM ESTUDO PILOTO 
 

Guilherme de Araújo ALMEIDA¹; Joana Cristina dos SANTOS MENEZES²;  
Éverton Ribeiro LELIS³; Marina Guimarães ROSCOE4; Isadora Moraes Mundim PRADO5; 

Asbel Rodrigues MACHADO6; Alfredo Júlio FERNANDES NETO7 
1. Professor, Department of Pediatric Dentistry and Orthodontics, Federal University of Uberlandia, Uberlândia, Minas Gerais, Brazil. 

galmeidaorto@prove.ufu.br; 2. Orthodontist, Private Practice; 3. PhD Student, Department of Orthodontics, São Paulo State University, 
Araçatuba, São Paulo, Brazil; 4. PhD Student, Department of Biomaterials and Oral Biology, University of São Paulo, São Paulo, São 
Paulo, Brazil; 5. Post-graduate Student, Department of Occlusion, Fixed Prosthodontics and Dental Materials, Federal University of 
Uberlandia, Uberlândia, Minas Gerais, Brazil; 6. Oral and Maxillofacial Radiologist, Private Practice; 7. Professor, Department of 

Occlusion, Fixed Prosthodontics and Dental Materials, Federal University of Uberlandia, Uberlândia, Minas Gerais, Brazil. 
alfredon@ufu.br 

 
ABSTRACT: The dentoskeletal effects produced by the bonded expander, principally the vertical ones, are 

controversial in the literature when compared with the effects produced by the hyrax, and have also been scarcely studied 
by means of cone-beam computed tomography (CBCT). This study aimed to evaluate the horizontal and vertical 
dentoskeletal effects produced by the bonded expander and by the hyrax using CBCT. The study sample consisted of ten 
patients, divided equally into two groups according to facial and cephalometric features: group 1, vertical facial growth 
pattern (two males, three females; mean age,  7.7 years) and group 2, normal facial growth pattern (three males, two 
females; mean age, 8.3 years), treated by bonded expander and hyrax, respectively. The patients were subjected to a CBCT 
scan before expansion and another scan four months after the end of the activations, when the expander was removed. 
Within each group and between the groups the horizontal and vertical effects were assessed using Student’s t-test. The 
sample size was predetermined, and 5 patients were needed in each group to detect the differences at P < 0.05 with 90% 
power. Among the horizontal changes assessed, the nasal floor width (P = 0.03) and the greater internal width in the 
posterior region (P = 0.00) showed a statistically significant increase only for group 1, and the mandibular molar 
verticality showed a statistically significant increase only for group 2. The vertical changes showed no statistical 
differences within groups (P > 0.05). Comparing the two groups there were no statistical differences for any assessed 
change (P > 0.05). Considering there were no differences of the effects between the appliances, the bonded expander 
produced no greater vertical control compared to the hyrax. Nevertheless, further study is recommended in a larger sample 
size using CBCT. 
 

KEYWORDS: Orthodontic Appliances. Palatal Expansion Technique. Malocclusion.  
 
INTRODUCTION 

 
Over the years, different appliances have 

been developed for performing the rapid maxillary 
expansion (RME) such as the hyrax (BIEDERMAN, 
1968) and the bonded expander (COHEN; 
SILVERMAN, 1973). Several studies have 
addressed the dentoskeletal effects of these 
expander appliances (AKYALCIN et al., 2013; 
ASANZA et al., 1997; BAYSAL et al., 2013; 
FARRONATO et al., 2008; GARIB et al., 2005; 
GARRETT et al., 2008; IWASAKI et al., 2014; 
LAGRAVÈRE et al., 2010; REED et al., 1999; 
RODRIGUES et al., 2012; SARVER; JOHNSTON, 
1989), however, the comparison between them still 
remains controversial, especially regarding to the 
vertical effects. Some authors concluded that the 

bonded expander increases the transverse dimension 
of the maxilla, but limits or even eliminates changes 
in vertical dimension (ASANZA et al., 1997; 
SARVER; JOHNSTON, 1989). This is possible 
because the acrylic on the posterior region works 
like a bite block, inhibiting the eruption of the 
posterior teeth during treatment (SARVER; 
JOHNSTON, 1989). Nevertheless, long terms 
evaluations showed that changes in the vertical and 
anteroposterior dimensions were negligible when 
patients were treated with hyrax without any kind of 
vertical control (LAGRAVÈRE et al., 2010). 

Most evaluations of dentoskeletal effects of 
RME with bonded expander were performed 
through the analysis of dental casts and 
cephalometric radiographs (ASANZA et al., 1997; 
IWASAKI et al., 2014; REED et al., 1999; 

Received: 19/11/15 
Accepted: 20/01/16 



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Biosci. J., Uberlândia, v. 32, n. 3, p. 796-804, May/June. 2016 

SARVER; JOHNSTON, 1989). However, these 
methods are not appropriate for examining the 
changes during and after RME therapy because they 
are based on a two-dimensional representation of a 
three-dimensional object (AKYALCIN et al., 2013). 

Conventional radiographs can cause an overlap of 
the images, which compromises the diagnostic 
accuracy (GARIB et al., 2005). With the advent of 
the cone-beam computed tomography (CBCT), the 
clinician is enabled to acquire images in any plane 
without overlapping structures, and allowed to 
evaluate skeletal and dental changes quantitatively 
and three-dimensionally with minimal distortion 
(AKYALCIN et al., 2013; BAYSAL et al., 2013). 

The purpose of this study was to evaluate 
the horizontal and vertical dentoskeletal effects 
occurred after the RME in patients treated by a 
hyrax or a bonded expander, using the CBCT. The 
hypotheses tested were that the hyrax and the 
bonded expander appliances would present 
significant differences in their dentoskeletal effects 
after the RME; there would also be a greater vertical 
control when using the bonded expander appliance 
compared to the hyrax. 

 
MATERIAL AND METHODS 
 
Study participants and design 

This study was approved by the Ethical 
Research Committee at the Federal University of 
Uberlandia – UFU, Uberlandia, Brazil (approval 
number 359/08). Sample size was predetermined, 
and five patients were required in each group to 
detect differences at P < 0.05 with 90% power. Ten 

patients in need of orthodontic treatment, who 
sought the Brazilian Dental Association - 
Uberlandia Section (ABO, Uberlandia, Brazil), were 
asked to participate in the study. Considering the 
radiation exposure of CBCT compared to 
conventional radiographs, the Ethical Committee 
allowed to plan only a pilot study first. The criteria 
for inclusion in the research were as follows: 
clinical signs of transverse maxillary deficiency 
with bilateral posterior crossbite or unilateral 
functional crossbite; patients should be at the first 
transitional period or the intermediate period of the 
mixed dentition; no previous orthodontic treatment 
or periodontal disease; absence of metallic 
restorations in posterior teeth or craniofacial 
anomalies; presence of upper first permanent molar. 

The ten patients were divided into two 
groups (group 1 and group 2), according to the 
facial and cephalometric features presented. Group 
1 was composed by 3 female and 2 male patients 
(mean age 7 years 9 months), with facial and 
cephalometric features showing vertical patterns 
more pronounced, as mandibular planes inclined, 
growth excessively vertical (SN.GoGn > 32º) 
(RIEDEL, 1952), convex profile and therefore 
requiring a greater vertical control over the 
procedure of the maxillary. Group 2 was composed 
by 2 female and 3 male patients (mean age 8 years 4 
months), with balanced facial and cephalometric 
features. RME was carried out using a bonded 
expansor appliance (Figure 1A) in group 1 and a 
conventional hyrax appliance (Figure 1B) in group 
2. 

 

 
Figure 1. The bonded (A) and hyrax (B) expander appliances. 
 

The activation of the RME appliances was 
made twice a day, one-quarter turn in the morning 
and one-quarter turn in the evening. Maxillary 
expansion was determined by an increase in the 
intermolar width until overcorrection of 
approximately 2 to 3 mm. All patients underwent 
examination with  CBCT; the records were obtained 
immediately pre-treatment T1 and four months after 

the end of the activations T2. In this stage, the 
expander was removed to achieve the second CBCT 
scan T2 and the activation was conferred by 
counting the number of turns, rotating the screw to 
its initial position. 

A NewTom 3G (Quantitative Radiology 
s.r.l., Verona, Italy) was used to obtain the scans. 
During the CT scans the following actions were 



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taken to standardization of the patient head position: 
the Camper Plane was perpendicular to the ground; 
the longitudinal laser beam was positioned through 
the facial midline; and, the transverse laser beam 
was positioned through the lateral corner of the 
eyes. The axial slice thickness was set at 0.5 mm 
and the linear and angular measurements were made 
by the radiologist using another software coupled to 
the NewTom 3G, called "Basic 3G" (Quantitative 
Radiology s.r.l.), which gives measures scale of 1:1. 

Evaluations were performed on axial, 
coronal and sagittal slices. From the axial images it 
was selected one immediately preceding the 
complete separation of the roots of the first right 
upper molar (furcation area). In the image it was 
traced a line connecting the most prominent point of 
the palatal root, in relation to the palatal bone plate, 
of the first upper right molar to the most prominent 

point of the palatal root of the maxillary left first 
molar. The coronal slices were made parallel to that 
line and the sagittal slices were made passing 
through the center of the incisal edge of the 
maxillary right central incisor tooth. The thickness 
was set at 1.0 mm and the width at 80 mm. One of 
the researchers measured the material twice, with at 
least a 1-week interval between the first and second 
recordings. It was used the average value in 
millimeters of the first and second readings. 

The parameters applied are shown in 
Figures 2, 3 and 4. 
 
Axial slice 

Buccal bone plate thickness: distance 
between the buccal bone plate and the most 
prominent point of the mesiobuccal root surface of 
the maxillary right first molar (Figure 2). 

 

 
Figure 2. Axial slice used to evaluate the buccal bone plate thickness. 
 
Coronal slices (horizontal changes) 
The coronal parameters 1 to 4 were measured based 
on a line passing through the points of union of the 

palatal root, of the buccal root, of the right maxillary 
first molar and of the left maxillary first molar 
(Figure 3).  

 

 
Figure 3. Coronal evaluation parameters. 



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1. Distance between the palatal bone of 
ridge surface on the right side and the palatal bone 
of ridge surface on the left. 

2. Distance between the top of the bone 
crest palatal on the right side and the top of the bone 
crest palatal on the left. 

3. Nasal floor width in the posterior region. 
4. Greater internal width in the posterior 

nasal region. 
The coronal parameters 5 and 6 were 

measured based on a line passing through the center 
of the cervical third of the upper canines erupted 
(Figure 3).  

5. Nasal floor width in the anterior region.  
6. Greater internal width in the anterior 

nasal region. 
The coronal parameters 7 and 8 were 

measured based on a line passing through the center 

of the trifurcation of the first upper and lower 
molars, respectively (Figure 3). 

7. Upper molar verticality: the angle of 
intersection of a first line passing parallel to the 
image of the hard palate and of one passing through 
the long axis of the first right upper molar. 

8. Lower molar verticality: the angle of 
intersection of a first line passing through the long 
axis of the mandibular first molar with a second one 
bilaterally tangent the image of the mandibular 
lower edge.  

 
Sagittal slices (vertical changes) 

The sagittal parameters 1 to 4 were 
measured on a sagittal image, with a thickness of 1 
mm, passing through the center of the incisal edge 
of the upper right central incisor (Figure 4). 

 

 
Figure 4. Sagittal evaluation parameters. 
 

1. Distance between the anterior nasal spine 
and the menton point. 

2. Distance between the incisal edge of the 
maxillary right central incisor and a line linking the 
anterior and posterior nasal spine. 

3. Upper right incisor verticality: the angle 
of intersection of a first line connecting the anterior 
nasal spine and posterior nasal spine and of a second 
line on the long axis of the maxillary right central 
incisor, passing through the incisal edge of 
maxillary right central incisor tooth.  

4. Distance between the anterior nasal spine 
and the nasion point. 
 
Statistical analysis 

The data were analyzed with the SPSS 
software for Windows 15.0 (SPSS Inc., Chicago, 
USA). Student’s t-test was performed to analyze and 
compare the dentoskeletal changes of the two 
groups in study. A significance level of α = 0.05 
was considered.  
 
RESULTS 

 
The mean values, standard deviations and 

statistical significance (P value) for the changes 
resulting from the RME in groups 1 and 2 as well as 
for the comparative changes between the two groups 
are shown in Tables 1, 2 and 3, respectively.  

 



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Table 1. Changes in the bonded expander group (unit: mm). 
Parameter T1 - T2 Mean Deviation t statistic P value 

Axial 0.92500 0.74106 2.49643 0.0880 

Coronal 1 -0.900000 1.42127 -1.266476 0.2947 

Coronal 2 -2.350000 0.35119 -13.38313 0.0009* 

Coronal 3 -1.825000 0.94296 -3.870805 0.0305* 

Coronal 4 -2.050000 0.49329 -8.31157 0.0036* 

Coronal 5 -1.100000 1.14601 -1.919708 0.1507 

Coronal 6 -0.850000 0.55076 -3.08666 0.0539 

Coronal 7 -0.600000 1.60208 -0.749025 0.5082 

Coronal 8 -2.750000 1.82117 -3.020034 0.0568 

Sagittal 1 -1.150000 1.90000 -1.210526 0.3127 

Sagittal 2 -1.725000 1.26853 -2.719685 0.0726 

Sagittal 3 1.57500 2.10297 1.49788 0.2311 

Sagittal 4 -0.775000 0.88459 -1.752224 0.1780 

* Statistically significant if P value < 0.05 (Student’s t-test). 
 
Table 2. Changes in the hyrax expander group (unit: mm). 

Parameter T1 - T2 Mean Deviation t statistic P value 

Axial 0.5250000 1.00457 1.04522 0.3727 

Coronal 1 -2.400000 1.14601 -4.188454 0.0248* 

Coronal 2 -3.700000 1.63911 -4.514658 0.0203* 

Coronal 3 -2.050000 1.54164 -2.659498 0.0764 

Coronal 4 -2.650000 2.05345 -2.581019 0.0817 

Coronal 5 -1.100000 0.74386 -2.957531 0.0597 

Coronal 6 -1.625000 1.10868 -2.93142 0.0609 

Coronal 7 -4.250000 4.07635 -2.085196 0.1284 

Coronal 8 -3.825000 1.67008 -4.580619 0.0195* 

Sagittal 1 -1.175000 1.75381 -1.339943 0.2727 

Sagittal 2 -1.125000 0.97425 -2.309464 0.1041 

Sagittal 3 4.55000 3.82317 2.38022 0.0976 

Sagittal 4 -0.675000 0.84212 -1.603096 0.2072 

*Statistically significant if P value < 0.05 (Student’s t-test). 
 



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Table 3. Comparative changes resulted from the RME between the bonded and hyrax expanders (unit: mm). 

Parameter 
Average 
(bonded) 

Deviation 
(bonded) 

Average 
(hyrax) 

Deviation 
(hyrax) 

t test P value 

Axial 0.9250 0.74106 0.5250 1.00457 0.64 0.5453 

Coronal 1 -0.9000 1.42127 -2.4000 1.14601 1.64 0.1515 

Coronal 2 -2.3500 0.35119 -3.7000 1.63911 1.61 0.1584 

Coronal 3 -1.8250 0.94296 -2.6500 2.05345 0.73 0.4928 

Coronal 4 -2.0500 0.49329 -2.0500 1.54164 0.00 1.0000 

Coronal 5 -1.1000 1.14601 -1.6250 1.10868 0.66 0.5347 

Coronal 6 -0.8500 0.55076 -1.1000 0.74386 0.54 0.6085 

Coronal 7 -0.6000 1.60208 -4,2500 4,07635 1.68 0.1474 

Coronal 8 -2.7500 1.82117 -3.8250 1.67008 0.87 0.4177 

Sagittal 1 -1.1500 1.90000 -1.1750 1.75381 0.02 0.9852 

Sagittal 2 -1.7250 1.26853 -1.1250 0.97425 -0.75 0.4815 

Sagittal 3 1.5750 2.10297 4.5500 3.82317 -1.36 0.2216 

Sagittal 4 -0.7750 0.88459 -0.6750 0.84212 -0.16 0.8753 

*Statistically significant if P value < 0.05 (Student’s t-test). 
 
For the bonded expansor group, Student’s t-

test showed that only the coronal parameters 2 (P = 
0.00), 3 (P = 0.03) and 4 (P = 0.00) were significant. 
Numerically, it could be seen rising values for most 
parameters evaluated, except for the axial parameter 
(assessment of the buccal bone plate thickness), 
which showed an average reduction of 0.925 mm; 
and the sagittal parameter 3 (assessment of the 
upper right incisor verticality), which showed a 
reduction of 1.57° on average.  

For the hyrax group, Student’s t-test showed 
that only the coronal parameters 1 (P = 0.02), 2 (P = 
0.02) and 8 (P = 0.01) were significant. Likewise, in 
group 1 it could be numerically seen rising values 
for most parameters evaluated, except for the axial 
parameter (assessment of the buccal bone plate 
thickness), which showed an average reduction of 
0.525 mm; and the sagittal parameter 3 (assessment 
of the upper right incisor verticality), which showed 
a reduction of 4.55° on average.  

Analyzing the two groups, Student’s t-test 
showed no statistically significant differences in the 
parameters evaluated when hyrax and bonded 
expansor appliances (P > 0.05) effects were 
compared. 

 
 

DISCUSSION 
 
Some authors (ASANZA et al., 1997; 

SARVER; JOHNSTON, 1989) attribute to the 
bonded expander, a better vertical control when 
compared to conventional expanders such as haas 
and hyrax expanders. Thus, in this study, subjects 
with a definite tendency to vertical craniofacial 
growth were undergoing expansion using the 
bonded expander. On the other hand, individuals 
with balanced craniofacial growth trend were treated 
with hyrax expander. 

The dentoskeletal effects resulted from the 
RME were quantified and compared among patients 
treated by a bonded expander (COHEN; 
SILVERMAN, 1973) or a hyrax (BIEDERMAN, 
1968), using CBCT. This system has the advantage 
of reducing measurement errors because it is 
possible to visualize the teeth in sagittal, coronal 
and axial planes without image superimpositions 
(AKYALCIN et al., 2013; BAYSAL et al., 2013). 

The axial parameter (buccal bone plate 
thickness) showed numerical decreases in both 
groups. However, there were no statistical 
differences. This find corroborates the recent study 
carried out by Baysal et al. (2013). Although this 
CBCT study (BAYSAL et al., 2013) did not find a 



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statistical difference in the furcation area of the first 
molars, between the periods after retention and 
before expansion, it found differences in other 
regions of the roots and other teeth as well. The 
coronal parameter 1 evaluated the maxillary 
transverse dimension and showed numerical 
increases in both groups. These results corroborate 
other findings in the literature, which also report 
increase in skeletal transverse dimension after the 
RME (HAAS, 1970; RODRIGUES et al., 2012; 
SARVER; JOHNSTON, 1989). Nonetheless, only 
group 2 presented a statistically significant 
difference between the initial and final average. This 
might had occurred due to a lower standard 
deviation and a greater activation of the screw in 
this group (6.5 laps in the hyrax expander and 5.25 
laps in the bonded expander). 

The opening of the mid-palatal suture 
causes downward and backward rotation of the 
mandible and increases lower anterior facial height 
as a direct effect of vertical displacement of the 
maxilla (ASANZA et al., 1997; HAAS, 1970). 
Assessing the lower anterior facial height parameter 
(sagittal parameter 1), although patients treated by 
the bonded expander showed a slightly average 
difference between stages T1 and T2, this difference 
was not statistically significant when compared with 
patients treated by hyrax expander. These finds 
corroborate Reed et al. (1999), that compared the 
treatment outcomes between banded and bonded 
RME appliances, by means of cephalometric 
radiographs and orthodontic study casts, and found 
no statistically significant differences between the 
two appliances. 

Several studies have exposed the effects of 
the RME in the nasal cavity (FARRONATO et al., 
2008; GARIB et al., 2005; IWASAKI et al., 2014). 
Additionally, this study performed measurements of 
nasal cavity in stages T1 and T2 of treatment. The 
nasal floor width in the posterior region (coronal 
parameter 3) showed a numerical increase in both 
groups; however it showed a statistically significant 
increase only in group 1. In the anterior region 
(coronal parameter 5), it was observed increased 
values in both groups, although none statistically 
significant. Evaluating the greater internal width in 
the posterior and anterior nasal region (coronal 
parameters 4 and 6, respectively), only group 1 
showed a statistically significant difference, 
identified in the posterior region. Increases in the 
posterior region corresponded to 39.04% of the 
amount of activation of the screw in group 1 and 
31.53% of the amount of activation of the screw in 
group 2, approaching the values found in the 
literature, as the 37.2% reported by Garret et al. 

(2008). through hyrax screw, and the 33.3% 
reported by Garib et al. (2005). This increase may 
contribute to the decrease of nasal resistance to the 
airflow (FARRONATO et al., 2008; GARIB et al., 
2005; HAAS, 1970). 

The RME also promotes dentoalveolar 
changes. Slight extrusion also occurs in the posterior 
dentoalveolar structures during tipping 
(LAGRAVÈRE et al., 2010). Buccal tipping and 
extrusion of the maxillary posterior dentoalveolar 
structures result in downward and backward rotation 
of the mandible, an increased mandibular plane 
angle, and a reduced bite (SARVER, JOHNSTON, 
1989). The coronal parameter 2 evaluated not only 
the transverse maxillary growth, but also the 
inclination or expansion of the alveolar processes. It 
was noted that these increases were higher than 
those reported by the measurement of coronal 
parameter 1. This effect demonstrates a decrease of 
the magnitude of the maxillary expansion in the 
direction of the occlusion of the maxillary basal 
area, according to the literature (BISHARA; 
STALEY, 1987; SARVER, JOHNSTON, 1989). 

These increases were statistically significant in both 
groups. 

The coronal parameter 8 was calculated in 
order to observe the stabilization of the anchorage 
(first molar). It was detected an increase angle 
value, characterizing a flaring of the molar acting as 
an anchorage. However, these values were not 
statistically significant, probably due to the large 
standard deviations observed in both groups. This 
dental effect, characterized by the flaring of the first 
molar, caused a thickness reduction of the buccal 
bone plate, which was noted by the axial parameter 
measurement. This reduction of the buccal bone 
plate thickness represents the absence of equivalent 
compensatory bone apposition on the buccal 
periosteum, from the beginning of this process to 
the final four months of retention with the 
appliance. These results corroborate previous 
studies that reported a decrease in buccal bone plate 
after the RME (GARIB et al., 2005; GARRETT et 
al., 2008). Nevertheless, this reduction was not 
statistically significant for any of the evaluated 
groups. 

To evaluate the effects of RME in the upper 
incisor, some measurements were made. Among 
them, the one that evaluated the extrusion of the 
upper incisor (sagittal parameter 2) deserves more 
emphasis. Group 1 showed a numerically significant 
increase, demonstrating that a possible dental 
extrusion movement occurred in the upper right 
incisor, which is in accordance with the literature 
(BISHARA; STALEY, 1987; SARVER, 



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JOHNSTON, 1989). However, this was not 
statistically significant. On the other hand, Group 2 
expressed only a small increase in this 
measurement. These differences may have occurred 
due to the bite opening caused by the installation of 
the bonded expander, which facilitates the extrusion.  
 Regarding to the upper right incisor 
verticality (sagittal parameter 3), it was observed a 
decrease in the angle value in both groups, 
indicating a verticality with a relative extrusive 
movement, which is also in accordance with the 
literature (BISHARA; STALEY, 1987; SARVER, 
JOHNSTON, 1989). Nevertheless, the values found 
were not statistically significant. The mandibular 
effects of RME were evaluated to detect the 
existence of a lateral movement of the molars 
(coronal parameter 8). Only  group 2 showed a 
statistically significant increase in this angle, 
proving the verticality suffered by the lower molar 
after the RME, due to the occlusal force changes 
and to the muscular balance reestablishment  
(reduction of buccinator pressure) (BISHARA; 
STALEY, 1987). 

The present study showed no statistically 
significant differences between the groups when 
using the CBCT. Consequently, there was no 

finding of a greater vertical control when the bonded 
expander was used compared to hyrax. 
Nevertheless, the sample size of this study must be 
considered. This research was conducted using a 
small sample due to restrictions made by the ethics 
committee, considering the radiation exposure of the 
cone-beam computed tomography and the mean age 
required. Therefore, it is suggested for future studies 
in which long-term evaluations, covering a larger 
number of patients, should be carried out to 
investigate all these dentoskeletal changes when 
RME is performed. 

 
CONCLUSION 

 
Within the limitations of this study, it was 

not found any statistically significant differences 
between the two appliances. Thus, there was no 
finding of a greater vertical control when using the 
bonded expander appliance compared to the hyrax.  

 
ACKNOWLEDGMENTS 
 

The authors would like to thank the 
Tomoface Tomografia Volumétrica Facial Ltda for 
the volumetric CT support. 

 
 
RESUMO: Os efeitos dentoesqueléticos produzidos pelo expansor colado, principalmente os efeitos verticais, 

são controversos na literatura quando comparados aos efeitos produzidos pelo expansor hyrax, e pouco estudado por meio 
de tomografia computadorizada de feixe cônico (TCFC). O objetivo deste estudo foi avaliar os efeitos dentoesqueléticos 
horizontais e verticais produzidos pelo expansor colado e pelo hyrax, utilizando-se TCFC. A amostra do estudo consistiu 
de cinco pacientes, divididos igualmente em dois grupos de acordo com as características faciais e cefalométricas: grupo 1, 
padrão de crescimento facial vertical (dois do sexo masculino, três do sexo feminino, idade média 7,7 anos), e grupo 2, 
padrão de crescimento facial normal (três do sexo masculino, duas do sexo feminino, idade média 8,3 anos) tratados com 
expasor colado e hyrax, respectivamente. Os pacientes foram submetidos à escaneamento de TCFC antes da expansão e 
após quatro meses da última ativação, quando o expansor foi removido. Nas comparações intra e inter-grupos, os efeitos 
horizontais e verticais foram avaliados por meio do teste t de Student. O tamanho da amostra foi pré-determinado, e cinco 
pacientes foram necessários em cada grupo para detectar diferenças para P < 0,05 e com 90% de poder. Dentre as 
alterações horizontais avaliadas, a largura do assoalho nasal (P = 0,03) e a maior largura nasal interna na região posterior 
(P = 0,00) mostraram aumento estatisticamente significante apenas para o grupo 1, e  a verticalização do molar inferior 
mostrou aumento estatisticamente significante apenas no grupo 2 (P = 0,01). As alterações verticais avaliadas não 
demonstraram diferença estatística intra-grupos. Na comparação inter-grupos não foi encontrada diferença estatística em 
nenhum parâmetro avaliado (P > 0,05). Dado que não houve diferença na comparação inter-grupos, o expansor colado não 
produziu maior controle vertical em relação ao hyrax. No entanto, é recomendada a realização de mais estudos com maior 
amostra utilizando-se TCFC. 

 
PALAVRAS-CHAVE: Aparelhos Ortodônticos. Técnica de Expansão Palatina. Má Oclusão. 

 
 
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