1http://dx.doi.org/10.20396/bjos.v21i00.8666415

Volume 21
2022
e226415

Original Article

1 Clinical Private Office, Juiz de 
Fora, Brazil.

2 Division of Oral and Maxillofacial 
Surgery, University Hospital of 
Federal University, Juiz de Fora, 
Brazil.

3 Department of Orthodontics, 
Federal University of Juiz de Fora, 
Juiz de Fora, Brazil.

Corresponding author:  
Marcio José da Silva Campos 
drmarciocampos@hotmail.com 
R Giuseppe Verdi, 111 – 
Residencial São Lucas 
São Pedro, Juiz de Fora, MG, Brazil 
– 36.036-643 
55 (32) 99128-5974

Editor: Dr Altair A. Del Bel Cury

Received: July 7, 2021

Accepted: October 27, 2021

Comparison of the 
reproducibility of two 
cervical vertebrae 
maturation methods
Paulo Henrique da Rocha Duque1 , Rodrigo César 
Santiago2 , Rogério Lacerda dos Santos3 , 
Fernanda Ramos de Faria3 , Carolina de Sá 
Werneck3 , Robert Willer Farinazzo Vitral3 , Marcio 
José da Silva Campos3

Aim: Facial orthopaedic treatments based on the stimulation 
or restrictions of craniofacial bone growth are more effective 
when carried out during the pubertal growth spurt. The aim of 
this cross-sectional study was to evaluate the reproducibility 
of two cervical vertebrae methods (CVM) with manual 
tracing and direct visual inspection. Methods: A sample 
of 60 lateral cephalometric radiographs (10 of each of the 
6 CVM stages) was randomly selected from 171 records. 
5 orthodontists classified these radiographs according to 
the skeletal maturation stage in 2002 and 2005, and the 
application of both methods was conducted by direct visual 
inspection and evaluation through manual tracing. Results: 
The average reliability of the two methods determination 
and the two forms of evaluation was substantial. The direct 
visual inspection evaluation showed the highest reliability 
and agreement interexaminer values for both methods, 
as well as the intraexaminers evaluation. Conclusion: The 
reproducibility of CVM method was substantial, indicating its 
clinical use to determine the skeletal maturity and the ideal 
moment for treatment execution.

Keywords: Reproducibility of results. Cervical vertebrae. Bone 
development.

http://orcid.org/0000-0002-7100-0556
http://orcid.org/0000-0001-5290-4878
http://orcid.org/0000-0002-6213-9206
http://orcid.org/0000-0002-6834-2862
http://orcid.org/0000-0002-1660-0428
http://orcid.org/0000-0003-0861-7243
http://orcid.org/0000-0003-3217-9001


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Duque et al.

Introduction

Facial orthopaedic treatments based on the stimulation and/or restriction of cranio-
facial bone growth are more effective when carried out during the pubertal growth 
spurt, as during this period, the facial bone structures perform at maximum capac-
ity in response to stimuli offered by applied mechanics1,2. Therefore, the determi-
nation of skeletal maturation is widely used, as the chronological age has been 
considered a parameter of little reliability to assess the craniofacial development 
stage of the subject1,3-5.

The degree of skeletal maturation of craniofacial bones can be determined by the 
hand-wrist x-ray or by the evaluation of the cervical vertebrae maturation6-8. The 
hand-wrist x-ray evaluation is considered the gold standard method, since it allows 
the evaluation in a small area of the development of a great number of ossification 
centres, that present close relation with the whole skeletal bone development6. How-
ever, the evaluation of the cervical vertebrae maturation stage has the advantage of 
reducing costs and the patients’ exposure to X-rays9,10, as the cephalometric radio-
graph is part of the initial orthodontic documentation5,8,10,11.

In 2002, Bacetti et al.12 published a modified version of the method of determining 
skeleton maturity from the analysis of cervical vertebrae. With five stages of CVM, 
this method made determining skeletal maturation possible through the vertebrae 
C2, C3 and C4 using only one cephalometric radiograph. Later, in 200513, the same 
authors presented an improved version of the method to evaluate CVM with six 
stages of MVC, which allowed the physician to identify the ideal moment for dental 
skeletal disharmony treatment.

According to Gabriel et al.7 (2009), the clinical usage of CVM analysis must be con-
ditioned to its accuracy and reproducibility. Although some studies have reported 
reproducibility levels over 90%6,14-16, they show some methodological flaws that inter-
fere directly with these findings7.

Cunha et al.17 (2018) showed that there was no significant difference when compar-
ing the reproducibility of the evaluation of skeletal maturity through hand-wrist to cer-
vical vertebrae x-rays, and both methods were considered useful for clinical planning. 
A systematic review by Santiago et al.18 (2012) showed that the levels of scientific 
evidence related to the reliability of CVM to foresee the pubertal bone growth spurt is 
low due to few amounts of studies on the subject, even though some studies report 
a good correlation between both methods and considerable levels of reproducibility.

The aim of this study was to evaluate the reproducibility of two cervical vertebrae 
methods (CVM) with manual tracing and direct visual inspection. The study hypothe-
sis is that the reproducibility of the two methods is sufficient to determine the skeletal 
maturity of young patients.

Materials and Methods
initially, in this cross-sectional study, pre-treatment records of 171 subjects treated 
on Federal University of Juiz de Fora were selected between the ages of 7 and  



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Duque et al.

18 years old, regardless of sex, and who did not present: 1) history of facial, hand or 
wrist trauma; 2) congenital malformations nor acquired ones affecting the cervical 
vertebrae, hand or wrist; or 3) any syndrome or hormonal alteration associated with 
development alterations. Moreover, subjects would have to present good quality of 
both hand-wrist and lateral cephalometric x-rays that were taken on the same date. 
This study was approved by the Ethics Committee of Federal University of Juiz de 
Fora (comment number: 2.634.344).

In order to guarantee the homogeneity of the sample, the hand-wrist x-rays were 
evaluated (by a single researcher - P.H.R.D.) and the subjects were classified in one 
of the 11 stages according to the Fishman’s method19. Subjects were also classi-
fied in CVM stages based on the correlation between this method with the stages 
established by Fishman19, as suggested by Hassel and Farman14 (1995) (Table 1). 
The sample was composed by 10 randomly selected subjects of each of the 6 CVM 
stages (Table 1), with a total of 60 subjects.

The lateral cephalometric x-rays were evaluated and subjects were classified 
according to skeletal maturation stages using the qualitative methods proposed 
by Baccetti et al.12 in 2002 (method 1) and in 200513 (method 2). They were applied 
through direct visual inspection and manual tracing evaluation of C2, C3 and C4 ver-
tebrae using 0.5mm mechanical pencil (Faber Castel®, Stein, Germany) on acetate 
sheet (Orthometric, Franklin, USA).

The four evaluations (methods 1 and 2, with direct visual inspection and manual 
tracing) were carried out between June and August 2015, by 5 orthodontists without 
previous experience with the methods. Manual tracing was carried out by the ortho-
dontists at each evaluation stage. Immediately before the evaluations, the examiners 
were trained on applying the methods through an expository lesson given by a dental 
surgeon, specialized in Radiology and with methodological experience. All examiners 
were trained together.

In a dark room, the lateral cephalometric x-rays were located on a constant source 
of white light (negatoscope) and covered with a black sheet of paper of 300g/m2 of 

Table 1. Distribution of the 171 subjects preselected accordingly to skeletal maturation stages through 
Fishman19 and Hassel and Farman’s14 methods.

Maturation Stages
(hand-wrist)

Maturation Stages
(CVM)

Subjects

Preselected Sample

1 and 2 1 48 10

3 and 4 2 38 10

5 and 6 3 22 10

7 and 8 4 31 10

9 and 10 5 21 10

11 6 11 10

TOTAL 171 60



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Duque et al.

grammage and with a rectangular clipping in the centre, which only allowed the view 
of the cervical vertebrae. The positioning of the lateral cephalometric radiographs 
was performed by a single researcher (P.H.R.D.). During the evaluations, templates of 
methods 1 and 2 were provided to the examiners, and access to the information of 
the participants was not permitted (age, gender nor dentition images).

The evaluation of the 60 lateral cephalometric radiographs by the 5 examiners was 
done at two different moments (T1 and T2), with a six-week interval, and the order 
of the lateral cephalometric radiographs was randomly modified and the training 
repeated by all examiners. Therefore, 1200 evaluations were carried out at each 
moment, being 600 at each different evaluation moment.

Statistical analysis

The degree of reliability of the methods herein evaluated by direct inspection and 
manual tracing was evaluated by weighted kappa test, determining intra and interex-
aminers coefficients. Reliability was considered moderate when the values of Kappa 
varied between 0.41 and 0.60; substantial, when they varied between 0.61 and 0.80 
and excellent, when they were above 0.8120. Intraexaminers disagreements were 
evaluated in accordance to the amount of CVM stages presented between the eval-
uations at T1 and T2 for each examiner. The analyses were done using the Software 
SPSS Statistics 23 (IBM, Chicago, USA), significance level of 0.05. The sample power 
was determined using the statistical R pwr package.

Results
The power of the sample (n=60) for this study was 73.5% (1-β = 0.735), with a type β 
error of 0.265. A minimum effect of 0.30 and β/α = 1 were considered.

Table 2 shows the intraexaminer reliability between T1 and T2 moments for both 
methods. Reliability values showed small variation when comparing methods 1 
and 2, considering each of the evaluation forms (manual tracing and direct visual 
inspection). Considering each examiner, the method and the evaluation the findings 
are approximately 5% of excellent reliability, 75% of substantial and 20% of moderate 
reliability and all averages were substantial.

Table 2. Intraexaminers reliability between T1 and T2 moments according to weighted kappa coefficient 
and the reliable interval of 95%.

Examiner
Method 1 Method 2

Manual tracing Direct inspection Manual tracing Direct inspection

1 0.67 (0.55-0.79) 0.73 (0.60-0.85) 0.68 (0.56-0.80) 0.73 (0.60-0.86)

2 0.72 (0.60-0.84) 0.79 (0.67-0.91) 0.76 (0.65-0.86) 0.81 (0.71-0.90)

3 0.63 (0.50-0.77) 0.58 (0.44-0.71) 0.69 (0.58-0.80) 0.58 (0.44-0.71)

4 0.54 (0.40-0.67) 0.62 (0.48-0.76) 0.58 (0.45-0.71) 0.61 (0.47-0.74)

5 0.65 (0.52-0.78) 0.63 (0.51-0.76) 0.61 (0.48-0.73) 0.64 (0.52-0.73)

Average 0.64 (0.51-0.77) 0.67 (0.54-0.80) 0.66 (0.54-0.78) 0.67 (0.55-0.79)



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Duque et al.

Intraexaminers disagreements between T1 and T2 moments occurred, in its majority, 
due to a difference of one CVM stage in both evaluation forms of methods 1 and 2 
(Table 3). Almost all cases (above 94%) occurred due to a variation of up to two CVM 
stages. Despite the fact that the manual tracing evaluation of method 1 presented the 
minor average of intraexaminer reliability (Table 2), it showed the highest disagree-
ment occurrence (87.4%) for only 1 CVM stage (Table 3).

The comparison between classifications of CVM by the five examiners resulted in 
substantial reliability, varying between 0.62 and 0.70, as seen in Table 4. The highest 
percentage of interexaminers agreement (67.50%) was observed in method 1 evalua-
tion through direct visual inspection and the minor percentage (51.83%) was obtained 
at method 2 evaluation through manual tracing. The evaluation through direct visual 
inspection showed the highest values of interexaminer reliability and agreement for 
both methods (Table 4), as well as in the intraexaminers evaluation.

Table 3. Distribution of intraexaminers degree of disagreement in accordance to the amount of CVM stages 
in disagreement between T1 and T2 moments.

Degree of 
disagreement*

Method 1 Method 2

Manual tracing Direct inspection Manual tracing Direct inspection

1 stage 87.4% 81.7% 83.2% 77.8%

2 stages 10.9% 15.5% 16.0% 17.1%

1 or 2 stages 98.3% 97.2% 99.2% 94.9%

3 stages 1.7% 1.9% 0.8% 3.4%

4 stages 0% 0.9% 0% 1.7%

5 stages – – 0% 0%

* Amount of CVM stages in disagreement between classifications in T1 and T2.

Table 4. Interexaminers reliability and agreement and distribution of the disagreements in accordance to 
the number of CVM stages in disagreement.

Method 1 Method 2

Manual tracing Visual inspection Manual tracing Visual inspection

T1 T2 T1 T2 T1 T2 T1 T2

Agreement

Number 340 356 405 397 311 328 367 360

Agreement 56.6% 59.3% 67.5% 66.1% 51.83% 54.6% 61.1% 60.0

Reliability* 0.62 0.63 0.70 0.68 0.63 0.64 0.68 0.66

Degree of disagreement**

1 stage 85.0% 88.1% 75.4 87.7% 83.0% 83.4% 76.0% 80.0%

2 stages 13.1% 9.9% 23.1% 10.3% 14.9% 12.9% 19.0% 15.8%

1 or 2 stages 98.1% 98.0% 98.5% 98.0% 97.9% 96.3% 95.0% 95.8%

3 stages 1.9% 2.0% 1.5% 2.0% 2.1% 3.3% 5.0% 3.0%

4 stages 0% 0% 0% 0% 0% 0.4% 0% 1.2%

5 stages -- -- -- -- 0% 0% 0% 0%
* Weighted kappa coefficient
** Amount of CVM stages in disagreement between the examiners.



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Duque et al.

The evaluation through manual tracing showed an increase of the reliability and 
agreement degree from T1 to T2, while the evaluation through visual inspection 
showed a reduction of the degree for methods 1 and 2 (Table 4).

The majority of the disagreements (above of 75%) between examiners occurred due 
to a difference of one CVM stage (Table 4). In all the classification forms, there was 
an increase of one stage in disagreement percentage from T1 to T2. However, apart 
from classification of method 2 through visual inspection, all situations showed a 
reduction of the concentration from T1 to T2 considering the degree of disagreement 
in one or two stages what demonstrates an increase of the occurrence of the most 
discrepant disagreements (three or four CVM stages).

Discussion
The application of the analysis of the cervical vertebrae maturation (CVM) as a method 
to determine the skeletal development stage must be conditioned to its accuracy 
and reproducibility, allowing identification of the period where the craniofacial bones 
respond more effectively to facial orthopaedic treatments1,2. However, low reliability 
of the CVM method in identifying the bone development stages5 and methodological 
flaws in some researches21 raise doubts concerning its clinical applicability.

In order to reduce the possibility of the sample to contain a discrepant number of 
subjects at specific CVM stages and whose identification might have been either eas-
ier or more difficult, in the present research we initially determined the skeletal matu-
rity through Fishman method19 and its correlation with CVM method14, and only then 
select the participants in a random and homogeneous way for each of the stages. 
The segregation of the sample in CVM stages based on the hand-wrist radiograph 
determination of skeletal maturation was considered possible because high levels of 
correlation between the methods were reported15,16,21,22.

In the present research, all examiners made use of templates for consultation during 
evaluations7 and they were presented to all lateral cephalometric radiographs at 
the same moment and immediately after training so as to prevent any possibility of 
examiners to be confused between methods or between stages.

The clinical and scientific validity of the method of determining CVM is directly related 
to its reproducibility among different examiners. As for the clinical application of the 
method, it is necessary for professionals to have a consensus in its determination. 
However, according to Cericato et al.23 (2015) the majority of studies which evaluate 
these methodologies does not address interexaminers tests, therefore compromising 
the level of scientific evidence.

The values of inter (0.62-0.70) and intraexaminers (0.64-0.67) reliability obtained in 
the present research are inferior to other findings in literature, which report reliability 
coefficients between 0.85 and 0.9816,21,22. Nevertheless, most of these studies did not 
use rigorous statistical evaluations specific for association with ordinal data7.

Considering method 2 through direct visual inspection, Gabriel et al.7 (2009) 
reported an average value of intraexaminers agreement of 62.32% and reliability 
of 0.62, which are lower than the values obtained in the present research, while 



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Duque et al.

Sohrabi et al.8 (2016) reported higher values of reliability (average of 0.74). An indi-
vidual analysis of the 20 examiners of the present study and others7,8 showed that 
only four had results with reliability different from moderate or substantial, one had 
poor reliability7 and three with excellent values (obtained in the present research 
and reported by Sohrabi et al.8 (2016). The percentage of disagreement in one CVM 
stage reported by Gabriel et al.7 (2009) is also lower than the values obtained in the 
present research and other studies24,25, indicating that when their examiners dis-
agreed, it was in a more discrepant way.

Gabriel et al.7 (2009) reported that agreement among their 10 examiners was lower 
than 50%, although with values of reliability between 0.72 and 0.76, determined using 
Kendall’s W test. The lower interexaminer agreement presented by Gabriel et al.7 
(2009) can be related to the fact that the authors used a higher number of examin-
ers, hampering conformity of classification among them, whereas the highest values 
of reliability may have occurred due to the reduced number of lateral cephalometric 
radiographs (30 radiographs) in comparison to the 60 used in the present research. 
Moreover, the use of Kendall’s W test to determine the reliability may have embodied 
some inaccuracies to the results, since this test is indicated for comparisons between 
up to 2 examiners8, so the weighted Cohen’s kappa test is more indicated.

Although Gabriel et al.7 (2009) have adopted a reduced interval between evaluations 
(2 weeks) and provided one template of the method to the examiners at the moment 
of the evaluation, which could increase the reproducibility of the method, its point-
ers of inter and intraexaminers agreement and reliability were lower than the ones in 
the present research. This can be associated with the lack of standardization of the 
intensity, clearness and contrast of the radiographic images and the luminosity of 
the environment for evaluating these images, as the images were available in digital 
format and not printed, as in this research, which may have influenced the examiners’ 
perception and interpretation.

As well as in other studies24,25, in the present research the reliability pointer was deter-
mined through the weighted kappa coefficient for intra and interexaminers evaluation 
which takes into account not only the percentage of agreement between the evaluations 
but also the degree of inconsistency among disagreements7, widely characterizing the 
reproducibility degree of the method. This explains the difference between agreement 
percentages and reliability values (coefficient of Kappa) obtained for each method12,13 and 
evaluation (direct visual inspection and manual tracing) used in the present research.

Another factor that may have contributed for the divergence of results obtained by 
the present research and Gabriel et al.7 (2009) was the homogeneous distribution of 
the lateral cephalometric radiographs during the different CVM stages. When ceph-
alometric radiographs of different CVM stages do not have equal chances of being 
selected for the sample or they are not homogeneously enclosed, a selection bias can 
be incorporated when the occurrence of a higher number of CVM stages with easier 
or more difficult identification is allowed.

Other studies described higher values of agreement among examiners using method 
2. However, they used questionable means to evaluate the classification reproducibil-
ity. Wiwatworakul et al.25 (2015) reported an average percentage of 96.6% of interex-



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Duque et al.

aminers agreement although they used only two examiners, facilitating the equality 
of classification among them. Perinetti et al.24 (2014) found interexaminers reliability 
between 0.81 and 0.82, although previously to CVM classification. Their examiners 
had been trained in the method until reaching 75% of correct identification of cases, 
which calibrated them in advance.

The results show that the analysis through direct visual inspection, even though pre-
senting higher values of agreement and reliability, had greater prevalence of disagree-
ment in two or more CVM stages in relation to manual tracing, possibly due to the fact 
that once the tracing is finished, the definition of the form of the vertebra is facilitated 
because its tracing is based on a defined contour and new mental delimitations of 
vertebrae limits based on radiographic image are no longer necessary.

In accordance with the present research findings, method 1 performed better in terms 
of interexaminer agreement and reliability in direct visual inspection evaluation. This 
may have occurred due to the additional stage of method 2, which was identified by 
the presence of the concavity in the inferior edge of C2. This characteristic gener-
ated a great doubt during classification according to the examiners of the present 
research. On the contrary, Sohrabi et al.8 (2016) and Nestman et al.26 (2011) reported 
higher values of reproducibility when determining the concavity of the inferior edge 
of C2, C3 and C4 vertebrae than their general form.  However, despite the evaluated 
characteristic of the cervical vertebrae, the fact is that a lower number of stages 
adopted by method 1 in comparison with method 2 reduces the possibility of dis-
agreement among evaluations.

We acknowledge a limitation of clinical application of the results in the present study 
regarding the training received by Orthodontists prior to CVM definition. The training 
was needed for the results not to be affected by the levels of knowledge of the exam-
iners, although we understand the difficulties regarding the access to specific training 
of CVM by Orthodontists.

In conclusion, the methods of determining CVM published by Baccetti, Franchi and 
McNamara in 2002 and 2005 presented substantial reproducibility both for direct 
visual inspection and for manual tracing of the cervical vertebrae. The analysis 
through direct visual inspection presented higher values of reliability and agreement 
when compared with the manual tracing.

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