Vol 50 No 4 Desember 2017.indd


211211

Dental Journal
(Majalah Kedokteran Gigi)
2017 December; 50(4): 211–215

Research Report

Dentoalveolar changes in post-twin block appliance orthodontic 
treatment class II dentoskeletal malocclusion 

Y. Yoana, Eka Chemiawan and Arlette Suzy Setiawan
Department of Paediatric Dentistry
Faculty of Dentistry, Universitas Padjadjaran
Bandung – Indonesia

ABSTRACT

Background: The analysis of cephalometric radiographs provides information about facial skeletal structures, jaw bone-base 
relationships, incisive-axial inclination relationships, soft tissue morphology, growth direction and pattern, malocclusion classification 
and the limitations of orthodontic treatments. In class II malocclusion, the mesiobuccal cusp of the permanent maxillary first molar rests 
between the first mandibular molar and the second premolar. A twin block appliance is recommended to treat Class II dentoskeletal 
malocclusion with retrognathic mandible characteristics. Purpose: The aim of this study was to analyze the dentoalveolar alterations 
in class II dentoskeletal malocclusion with retrognathic mandible characteristics after orthodontic treatment with twin block appliance 
based on a Steiner analysis. Methods: This research constitutes a retrospective study using secondary data derived from the lateral 
cephalometric radiographs of patients with Class II malocclusion treated with twin block appliance at the Pediatric Dentistry Department 
of the Oral and Dental Hospital, Universitas Padjajaran, Bandung. The data was analyzed using a T-test for normally distributed 
paired data. In cases where data was not normally distributed, a Wilcoxon test was employed. Results: The average measurements 
showed statistically significant dentoalveolar changes among class II malocclusion patients after twin block appliance treatment when 
analyzed using the paired t-test based on Steiner method cephalometric radiograph analysis (p < 0.05). Conclusion: It is concluded that 
a twin block appliance is effective in treating class II dentoskeletal malocclusion with a retrognathic mandible based on dentoalveolar 
changes resulting from Steiner analysis

Keywords: cephalometric; dentoalveolar alterations; dentoskeletal malocclusion; retrognathic mandible; twin block 

Correspondence: Arlette Suzy Setiawan, Department of Paediatric Dentistry, Faculty of Dentistry, Universitas Padjadjaran. Jl. Sekeloa 
Selatan 1 Bandung 40132, Indonesia. E-mail: arlettesuzy@yahoo.com; arlette.puspa@fkg.unpad.ac.id

INTRODUCTION

Numerous clinical studies have been conducted to 
reveal the skeletal and dentoalveolar changes related 
to the treatment of class II malocclusion. However, 
the implications of the resulting scientific data are still 
debatable.1 Several studies have argued that the skeletal 
effects induced by the functional appliances significantly 
influenced mandibular growth, while others indicated that 
they might have little effect on skeletal changes. Major 
modifications identified following orthodontic treatment 
with functional appliances include those dentoalveolar in 
nature, i.e. distalization of the buccal part and retroclination 

of maxillary anterior teeth, along with mesial changes in 
the buccal section of mandibular teeth and proclination of 
their labial sections. 

The availability of a diagnostic report supported 
by study models, radiographs and images showing the 
pre-treatment conditions necessary to select the form of 
malocclusion treatment and to assess its effectiveness 
was essential.2 The analysis of cephalometric radiographs 
provided information regarding facial skeletal structures, 
jaw bone-base relationships, incisive-axial inclination 
relationships, soft tissue morphology, growth direction 
and pattern, malocclusion classification, and limitations 
on orthodontic treatments.3 The purpose of cephalometric 

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v50.i4.p211-215

http://dx.doi.org/10.20473/j.djmkg.v50.i4.p211-215
mailto:arlettesuzy@yahoo.com
mailto:arlette.puspa@fkg.unpad.ac.id


212 Yoana, et al./Dent. J. (Majalah Kedokteran Gigi) 2017 December; 50(4): 211–215

radiograph examination is to evaluate the face type, jaw-
cranial base relationship, growth pattern, dentoalveolar 
relationship, the position of malocclusion, soft tissues and 
their relationship with regard to etiology and prognostics, 
functional relationship, and therapeutic possibilities.4 

The method frequently used to analyze cephalometric 
radiographs as part of dentofacial relationship evaluation is 
that of a Steiner analysis. This form of analysis is the most 
widely employed because it is simple, easy to understand 
and produces maximum clinical information with minimal 
methods that include calculation of the position and 
inclination of the teeth in relation to the jaw and the position 
of the jaw vis-a-vis the cranium base.4 The outcome of 
incompatible treatment may be due to incorrect line points 
in pre- and post-treatment cephalometric radiograph 
analysis. This creates difficulties in assessing the real 
involvement of the skeletal and dentoalveolar components 
in the changes evident in the treatment outcome.5 

Cephalometric radiographs are frequently used to 
identify and evaluate changes during malocclusion 
treatment.4 The World Health Organization stated that 
malocclusion is a dentofacial abnormality leading to defects 
in both appearance and function which affect a person 
both physically and mentally. Malocclusion is a deviation 
from the ideal occlusion that may cause discomfort and, 
specifically, poor esthetics. This is due to the imbalance 
in size and position of teeth, facial bones and soft tissues 
(lips, cheeks, and tongue).6,7

Edward Angle stated that class II dental malocclusion is 
defined as a condition where the first mandibular molar is 
more distal than under normal occlusion in relation to the 
first maxillary molar. The British Dental Institute defined 
class II malocclusion as a condition where the mandibular 
incisor edge is in a posterior position in relation to the 
palatal cingulum of the maxillary incisor in a proclined 
inclination with increased overjet.8 An epidemiological 
study at an elementary school in Jakarta confirmed the 
prevalence of the class II malocclusion as one of 31.6%.9

Several mandibular proclination methods applied 
to correct class II malocclusion include: functional and 
extraoral appliances, camouflage treatment and surgical 
jaw repositioning.5,10 The functional appliances comprise: 
bionators, FR-2 or Frankel, fixed and removable Herbst 
functional appliances and the twin block appliance 
introduced by William J. Clark.11 The twin block appliance 
consists of maxillary and mandibular acrylic plates with bite 
blocks that guide the mandible to a forward position during 
closure of the mouth.10 The indication of the twin block 
appliance is to correct class II dentoskeletal malocclusion 
with mandibular retrognathy.10–13

A comparative study between patients treated with 
twin block appliances and a control group showed a 
significant increase in mandible length, but with the 
frequent occurrence of overjet correction as a result of 
dentoalveolar compensation.12 Meanwhile, a comparative 
study of twin blocks and other functional appliances 
confirmed the former to be the best functional appliance 

for producing sagittal modification; including: mandibular 
skeletal changes, dentoalveolar changes and normal growth 
pattern changes.13 

This study aimed to analyze post-orthodontic treatment 
dentoalveolar modifications using twin block appliances 
in class II dentoskeletal malocclusion with retrognathic 
mandibles based on a Steiner analysis. 

MATERIALS AND METHODS

The study reported here was retrospective analytical in 
nature incorporating a purposive sampling method based 
on the secondary data derived from a lateral cephalometric 
radiograph of class II dentoskeletal malocclusion with 
retrognathic mandible patients. During the period 
2010–2017, these individuals were treated using twin 
block appliances at the Pediatric Dentistry Installation of 
the Oral and Dental Hospital, Universitas Padjadjaran, 
Bandung. Dentoalveolar alterations were assessed using 
Steiner cephalometric radiograph analysis (I-NA angle, 
I-NA distance, I-NB angle, I-NB distance, and interincisal 
angle).

Steiner analysis was also used to recognize the 
relationship between the position of the jaw and cranial base, 
the position of the mandible against the maxilla, in addition 
to that of teeth in the arch. The dentoalveolar alteration 
indicators employed in the Steiner analysis include: the 
maxillary first incisor inclination angle (I-NA angle), the 
anteroposterior position of the maxillary first incisor against 
the maxilla (I-NA distance), the mandibular first incisor 
inclination angle (I–NB angle), the anteroposterior position 
of the mandibular first incisor against the mandible (I–NB 
distance), the axial inclination angle between the maxillary 
and mandibular first incisors (interincisal angle). These 
measurements were taken pre- and post-treatment by means 
of a twin block appliance. 

Data was evaluated using a Shapiro-Wilk test on a small 
sample (≤50) before analysis. Normally distributed paired 
data was analyzed using a T-test. If data was not normally 
distributed, a Wilcoxon test would be used. 

RESULTS

This study was performed during the period March-
April 2017. Twenty-one lateral cephalometric radiographs 
taken pre- and post-treatment using a twin block appliance 
were collected. The age of the samples ranged from 8 to 
16 years, with and the majority being 11 years old. The 
number of male and female samples was almost equal, at 
10 and 11 respectively.

Measurement of pre- and post-treatment dentoalveolar 
modification with the twin block conducted using a Steiner 
analysis are listed in Table 1. It was apparent that the I-NA 
angle, I-NA distance and interincisal angle demonstrated 
very significant statistical (p < 0.01) variation. The 

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v50.i4.p211–215

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213213Yoana, et al./Dent. J. (Majalah Kedokteran Gigi) 2017 December; 50(4): 211–215

I-NB distance also demonstrated a significant variation 
(p < 0.05). The I-NB angle did not show any significant 
change (p≥0.05).

The percentage reduction in dentoalveolar changes are 
listed in Table 2. The (–) mark on the interincisal angles in 
the table represents an increase in angle percentage which is 
inversely proportional to that of other angles. The greatest 
decrease occurred in I-NA distance (32.1%).

DISCUSSION

A dentoalveolar relationship is one between the 
maxillary and mandibulary dentoalveolar processes (apical 
base) and respective skeletal base and the craniofacial bone.1 
This dentoalveolar relationship may experience changes. A 
distal step dentoalveolar relationship in primary teeth will 
become a class II molar relationship in permanent ones.14 

The terminal planes during primary and mixed dentition 
may develop into an unpleasant relationship (class II molar 
relation) in permanent teeth. In this case, observation should 
be undertaken carefully to ensure that orthodontic treatment 
can be performed as early as possible. Several factors are 
involved in the development of the molar dentoalveolar 
relationship, including flush terminal plane relationship, 
leeway space, mandibular growth and environmental 
factors affecting the dental arch pattern. 

In class II malocclusion, the mesiodistal cusp of the 
maxillary first permanent molar occludes mesially to the 
buccal groove of the mandibular first permanent molar. 
This creates a disharmony between the incisor teeth and 
the facial profile.4,15–17 The main objective of orthodontic 
treatment using a twin block functional appliance is to 
stimulate mandibular lengthening by stimulating the growth 
of cartilage and condylar cartilage, as well as inhibiting the 
growth of the maxilla.

Growth modification treatment for class II malocclusion 
is recommended at an early age to prevent unfavorable 
growth patterns. Treatment performed during the primary 
and mixed dentition periods produces better results 
compared to that started on conclusion of the mixed 
dentition period.17,18 Early treatment produced superior 
results, evidenced by greater efficiency in moving the 
mandibulla forward and inhibiting maxillar growth, while 
simultaneously correcting the occlusal relation.19

The samples analyzed were lateral cephalometric 
radiographs from class II dentoskeletal malocclusion 
with retrognathic mandible patients taken before and after 
orthodontic treatment using a twin block appliance. This 
study consisted of 21 samples taken from patients aged 
8 to 16 years due to the fact that functional appliances 

Table 1. Average comparative testing on dentoalveolar change measurement before and after treatment with the twin block

Steiner Analysis

Variable
Measurement Before 

Treatment
After Treatment Nilai p*

I-NA (0) < 0.01*

Mean (SD) 31.21 (7.38) 26.59 (8.31)

Range 14 – 44.5 6.5 – 40.5

I- NA (mm) < 0.01**

Mean (SD) 7.61 (2.13) 4.98 (1.38)

Range 3.5 – 11,0 1.5 – 7.5

I-NB (0) 0.931

Mean (SD) 32,46 (6,66) 32.36 (6.51)

Range 20 – 43.5 17.5 – 43

I-NB (mm) 0.011*

Mean (SD) 6.86 (2,32) 5.69 (2.20)

Range 3.5 – 11.5 1.2 – 11.5

Interincisal Angle (0) < 0.01**

Mean (SD) 108.09 (8.66) 115.60 (8.09)

Range 94.5 – 127.0 100.0 – 129.5

Description: Data was analyzed using paired t-test with a significance score of p < 0.05 (significant) (*) and p < 0,01 (very significant) (**) 

Table 2. The percentages of reduction in dentoalveolar 
changes based on cephalometric radiographs in class 
II dentoskeletal malocclusion retrognathic mandible 
treatment using twin block in the Oral and Dental 
Hospital, Universitas Padjadjaran

No. Variable % Decrease
1 I-NA angle 15.0
2 I-NA distance 32.1
3. I-NB angle 3.2*
4 I-NB distance 14.1
5 Interincisal angle -7.3

Description:  *data used the median score due to not being normally 
distributed.

 (–) increase

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v50.i4.p211–215

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214 Yoana, et al./Dent. J. (Majalah Kedokteran Gigi) 2017 December; 50(4): 211–215

appliance reduces overjet through the combination of 
dentoalveolar and skeletal changes. The anterior teeth are 
significantly tipped on the upper arch, but insignificantly 
so on the lower arch. The construction of the twin block 
explains the tipping result of the upper incisors.

Functional appliances used in class II malocclusion 
treatment are designed to alter the mandible position 
both sagittally and vertically.2 Therefore, the functional 
appliance is used in sagittal and vertical malocclusion 
treatment for patients in a growth and developmental 
period. The functional appliance works through back and 
forth mandibular movements, culminating in a stretching 
of soft orofacial and muscle tissues and myotatic reflexes 
resulting from muscle extension.22

The myotatic reflexes combined with the viscoelastic 
characteristics of the muscle exert stresses on both teeth and 
bone structure during the treatment. This muscle action is an 
important factor in generating of anticipated orthodontic and 
orthopedic forces. These forces are transmitted both directly 
and indirectly to the dentoskeletal tissues in order to correct 
malocclusion by increasing the sagittal intermaxillary 
relationship, i.e. changes in the molar relationship and 
decreased overjet.21 This condition can also be seen in 
the results of this study. The correction of malocclusion 
is achieved through dentoalveolar modifications reflected 
in the cephalometric radiographs of class II dentoskeletal 
malocclusion with the retrognathic mandible treated by 
twin block appliances.

Treatment involving the use of functional appliances 
is intended to improve the functional relationship of 
dentofacial structures by eliminating poor growth factors 
and improving the muscle condition around the developing 
occlusion area. The amended dental position and supporting 
tissue will achieve the new functional pattern and be able 
to support the new position equally.2,22

The success of orthodontic treatment in class II 
dentoskeletal malocclusion patients depends on the 
growth and development of each individual and sufficient 
treatment time. The success of treatment with twin block 
appliances also depends on these factors, as well as being 
profoundly affected by patient cooperation, meaning that 
the outcome of the treatment will vary. Other factors 
include the age and maturity of the patient, growth pattern, 
etiology and initial severity of the malocclusion, duration of 
treatment, soft tissue characteristics and the force applied 
by the appliances. There are several factors affecting the 
stability of the treatment, i.e. mandibular growth rotation 
direction, respiratory tract obstruction, effective appliance 
manipulation, duration of treatment and sufficient retention 
period.2 Twin block appliances may also prove able to 
correct transversal discrepancy in class II malocclusion 
by activating the screw in the palatal section. However, 
the twin block appliance usage can also cause a posterior 
open bite, resulting in the need for further fixed orthodontic 
treatment to correct the open bite.22 It is concluded that 
a twin block appliance is effective in treating class II 
dentoskeletal malocclusion with retrognathic mandible 

were indicated for patients with a relatively good arch, 
mild or moderate class II skeletal pattern and who were 
experiencing a period of growth.15

Within a Steiner analysis, several angles are used as 
the reference for measuring the relationships between the 
maxillary first incisor and the maxilla, the mandibular first 
incisor and the mandible, and the maxillary and mandibular 
teeth.20 According to the Steiner analysis, the results of 
measuring the average change in the dentoalveolar before 
and after treatment by means of a Twin Block appliance 
showed that there was a statistically significant change in 
I-NA angle, I-NA distance, I-NB distance, and interincisal 
angle. The greatest reduction was seen in I-NA distance.

Within this study, the primary change observable in 
functional treatment consisted of dentoalveolar changes 
comprising buccal distalization and maxillary anterior 
teeth retroclination as well as mesial-shifting of the buccal 
part of mandibular teeth and proclination of their labial 
section. Such findings are in line with a study performed by 
Sharma et al.20 that indicated a significant increase in the 
interincisal angle in cases of orthodontic treatment utilising 
twin block appliances. 

Within this study, a contrasting result was observed in 
the I-NB angle which confirmed there to be no statistically 
significant difference in this variable. This finding is similar 
to that of a study conducted by Tarvade et al.21 that showed 
no proclination of the lower anterior teeth, while another 
piece of research revealed lower incisor proclination of 
3.20.2 

After treatment with twin block appliances, the reduction 
of proclination in the upper incisors was statistically 
significant. The contact between the labial bow in upper 
incisors and labial muscles produced a palatal retroclination 
of incisors. This result is to be expected from a treatment 
involving the use of a functional appliance due to the class 
II traction effect.21

Within this study, the lowest reduction was found in the 
I-NA distance and in the degree of upper incisor protrusion. 
This indicates that the anterior inclination of the upper 
incisor was reduced, due to palatal tipping movement of the 
upper incisor and forward movement of the pogonion. 

The position of the lower mandibular incisor in class 
II is important in orthodontic treatment with functional 
appliances. Excessive labial tipping must be restricted 
to reduce the posibility of orthopedic alteration. After 
orthodontic treatment with twin block appliances, a 
proclination of the mandibular incisor in relation to the 
mandibular plane (IMPA) can be observed, even though 
it is statistically insignificant. Several studies reported 
significant proclination of mandibular incisors after 
treatment with twin block appliances, while the mandibular 
incisors remain stable in their position.20

This result may be explained by the design of the twin 
block appliance. The use of an acrylic cover on mandibular 
incisors and the eyelet clasps produce rigid retention on 
the labial lower jaw, as well as the use of sounthend clasps 
by Tarvade.21 This study indicates that the twin block 

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v50.i4.p211–215

http://dx.doi.org/10.20473/j.djmkg.v50.i4.p211-215


215215Yoana, et al./Dent. J. (Majalah Kedokteran Gigi) 2017 December; 50(4): 211–215

based on dentoalveolar alterations resulting from a 
Steiner analysis. 

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Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v50.i4.p211–215

http://dx.doi.org/10.20473/j.djmkg.v50.i4.p211-215