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805 
Original Article 

Biosci. J., Uberlândia, v. 32, n. 3, p. 805-812, May/June. 2016 

AGE ESTIMATION BASED ON THE STAGE OF MINERALIZATION OF 

THIRD MOLARS ON ORTHOPANTOMOGRAMS 
 

ESTIMATIVA DE IDADE BASEADO NO ESTAGIO DE MINERALIZAÇÃO DE 
TERCEIROS MOLARES EM RADIOGRAFIAS PANORÂMICAS 

 
Leticia de Oliveira TONIN

1
; Noemia Luisa Pittelli LEITE

2
; Rodrigo GALO

3
; 

 Ricardo Henrique Alves da SILVA
4 

1. Bolsista de Iniciação Científica (FAPESP), USP - Faculdade de Odontologia de Ribeirão Preto, Ribeirão Preto, SP, Brasil. 2. 
Especialista em Odontologia Legal, USP - Faculdade de Odontologia de Ribeirão Preto, Ribeirão Preto, SP, Brasil; 3. Professor Doutor, 
UFVJM - Universidade Federal dos Vales do Jequitinhonha e Mucuri, Diamantina, MG, Brasil; 4. Professor Doutor, USP - Faculdade 

de Odontologia de Ribeirão Preto, Ribeirão Preto, SP, Brasil. ricardohenrique@usp.br. 
 

ABSTRACT: The aim of this study was to evaluate the correlation among chronological age, sex and stages 
of mineralization of third molars using orthopantomograms in a Brazilian population. For such purpose, 1,200 
orthopantomograms of 9-20-year-old individuals (654 females and 546 males) were examined using as reference the 
Nicodemo’s table of mineralization chronology of permanent teeth among Brazilians. Estimated mean ages, standard 
deviations, standard errors and percent age distribution in each mineralization stage were established. Mann-Whitney and 
Kruskal-Wallis (p≤0.05) nonparametric tests were used to verify the influence of sex in the stages of mineralization of the 
third molars. The development of maxillary and mandibular and right and left third molars was similar in all stages. 
Females presented a more advanced stage of mineralization of third molars than males. Statistically significant difference 
in third molar development between males and females was found in stage 4 in teeth 18 (p=0.008), 28 (p=0.029), 38 
(p=0.010) and 48 (p=0.046). The results suggest that the development of third molars is similar in both sexes, regardless of 
the quadrant of dental arch and the tooth mineralization stage table employed in this study was applicable for using third 
molars as parameters for age estimation in the studied population. 
 

KEYWORDS: Forensic anthropology. Forensic dentistry. Radiology. 
 
INTRODUCTION 

 
Forensic age estimation of skeletons and 

corpses for identification purposes has been a 
conventional feature of Forensic Sciences, with 
great relevance from ethical and legal perspectives 
(KARAARSLAN et al., 2010). Age determination 
of living or dead individuals is a major issue and is 
frequently the first step in the whole identification 
process (SCHEMELING et al., 2007). The forensic 
dentist may contribute for determination of people’s 
age by using direct methods based on clinical 
examination, which involve the observation of the 
number of erupted teeth, chronology of eruption and 
general conditions of the teeth; or indirect methods 
based on the analysis of intraoral and extraoral 
radiographs, mainly for observation of the stages of 
mineralization of the teeth (ARAÚJO et al., 2010), 
which is one of the most commonly used methods 
for age estimation (BRKIC; MILICEVIC; 
PETROVECKI, 2006).  

Despite the scientific evidence supporting 
the use of dental age for estimation of chronological 
age, it should be considered that there is variation 
from one individual to another. The difficulties in 
the study of third molar development and in its 
clinical or forensic application are especially related 

to the variability in the formation of these teeth 
because the specific composition and shape of teeth 
are conditioned by their functions (ARAÚJO et al., 
2010). In addition, age estimation becomes more 
difficult after the age of 14 because the 
mineralization of most teeth is completed around 
this age (HERAS; FORTEA; ORTEGA, 1987). 
Therefore, the third molar has a substantial 
importance because it is the only tooth that 
continues developing after this age (HERAS; 
FORTEA; ORTEGA, 1987). The shape of third 
molars varies greatly and, because of the late 
eruption, they have well preserved characteristics 
and are mainly used for identification of individuals 
around 18 years of age (AMARITI et al., 1999). 
However, some divergence is observed when 
studies with different populations are compared, 
which reinforces the importance of further research 
to evaluate the actual applicability of the method 
(KULLMAN et al., 1996).  

There are numerous studies conducted in 
this subject on different populations of the world. 
The majority of the study results are from the 
European continents. In view of the variations 
which occur worldwide, the European study results 
may not give accurate chronological age of an 
individual when used in the South American 

Received: 10/09/15 
Accepted: 20/01/16 



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Age estimation based…  TONIN, L.O. et al. 

Biosci. J., Uberlândia, v. 32, n. 3, p. 805-812, May/June. 2016 

continent. Then, the aim of this study was to 
evaluate the correlation among chronological age, 
sex and stages of mineralization of third molars 
using orthopantomograms and create a database for 
the Brazilian population.  
 

MATERIAL AND METHODS 
 
In order to comply with the Brazilian 

Ethical Standards in research on humans, the study 
protocol was submitted to the Ethics Committee of 
Ribeirao Preto School of Dentistry, University of 
São Paulo, and was approved under the protocol 
#2010.1.399.58.4. 

A total of 1,200 orthopantomograms of 
individuals aged between 9 and 20 years old (654 
females and 546 males) obtained from radiographic 
archives were analyzed for this study. The 
orthopantomograms were randomly chosen from the 
Department of Oral Radiology, School of Dentistry 
of Ribeirão Preto, University of São Paulo. The 
orthopantomograms were produced from April 2010 
to March 2011. The chronological age of each 
subject was calculated based on reported date of 
birth and date of the radiographic examination 
contained on the orthopantomograms. The 
chronological ages were not revealed at the moment 
of the analysis. The criteria for inclusion in the 
individuals were the availability in their clinical 
records of an orthopantomography of appropriate 
quality, and no history of medical or surgical 
disease that could affect the presence and 
development of third molars. From the initial 
sample, we excluded cases with any missing image, 
due to poor visualization or due the extraction of 
any third molars. 

The stage of mineralization of the third 
molars was analyzed on the orthopantomograms 
according to the table of mineralization chronology 
of permanent teeth among Brazilians conceived by 
Nicodemo (NICODEMO, 1969) in order to estimate 
the chronological age and compare age estimation 
between sexes. In each radiograph, the third molars 
were classified as belonging to one of the 8 
Nicodemo’s stages of mineralization. Then, the 
estimated age was compared with the chronological 
age. The existence of statistically significant 
difference in age estimation between sexes in each 
one of the mineralization stages was also verified. 

Impacted wisdom teeth were excluded from 
the analysis. Mesially and distally angulated third 
molars were classified as impacted. Wisdom teeth 
with an unclear direction of emergence also were 
not included in the analysis. Image deformity 
affecting third molar visualization, hypodontia, or 

orthopantomograms showing obvious dental 
pathology also consisted of as exclusion criteria.  

All digital radiographs were taken with the 
Veraviewepocs 2D® (J. Morita, Kyoto, Japan). The 
Veraviewepocs 2D® orthopantomograms images 
were taken with a high-resolution CCD sensor (32-
bit microprocessor) (J. Morita, Kyoto, Japan) with 
exposure parameters 7.4 s, 64 kV, and 8.9 mA.  One 
well-trained examiner observed the radiographs 
after a period of calibration without the knowledge 
of age and gender. To test intra-examiner 
reliabilities, different staged the development of 
teeth were checked on 100 orthopantomograms. The 
examiner repeated the process after 1 month (intra-
examiner), and Cohen's kappa test was performed to 
calculate the intra-examiner agreements. 

The homogeneity of the collected data was 
assessed and a non-normal distribution was 
observed. Mann-Whitney and Kruskal-Wallis (5%) 
nonparametric tests were used to verify the 
influence of sex in the stages of mineralization of 
the third molars. Statistical analysis was performed 
using the SPSS software for Windows, version 12.0 
(SPSS, Inc, Chicago, IL, USA). 

 
RESULTS 

 
Intra-observer differences were not found in 

the repeated observing of a subsample of 100 
radiographs (P > 0.05). Intra-observer consistency 
was rated at 94%. Age distribution by stage of 
mineralization of third molars, sex and tooth number 
is presented in Table 1. Orthopantomogram 
distribution according to age and sex is shown in 
Table 2. Distribution of female and male subjects 
according to the stage of mineralization of third 
molars is shown in Table 3. Table 4 presents the 
mean age, standard deviation, standard error of the 
mean, and minimal and maximal age (in years) 
according to sex and stage of mineralization of third 
molars. 

Overall, there were statistically significant 
differences between males and females in age 
estimation in all mineralization stages of third 
molars, regardless of the quadrant of dental arch [18 
(P=0.008); 28 (P=0.029); 38 (P=0.010) and; 48 
(P=0.046)]. However, considering each stage 
separately, it was found that sexual dimorphism did 
not occur in all cases, and significant differences 
referred only to stage 4 for all four third molar tooth 
numbers (Table 4). No statistically significant 
differences (P>0.05) were observed in the 
mineralization stage between the maxillary and 
mandibular or between left and right third molars. 

 



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Table 1. Age distribution by stage of mineralization of third molars, sex and tooth number, Ribeirão Preto, 
Brazil. 

Stage  Sex 
Age (years) 

Tooth 18 Tooth 28 Tooth 38 Tooth 48 

S1 
Male 9.71 (0.89) 9.48 (0.65) 9.64 (0.85) 9.61 (0.82) 

Female 9.56 (0.88) 9.46 (0.75) 9.63 (0.85) 9.46 (0.84) 

S2 
Male 10.08 (0.75) 10.21 (0.87) 9.90 (0.76) 9.88 (0.84) 

Female 10.15(1.05) 10.32 (1.06) 10.17 (1.31) 10.45 (1.28) 

S3 
Male 11.06 (1.22) 11.00 (1.01) 10.94 (1.13) 10.91 (1.12) 

Female 11.17 (1.36) 11.16 (1.25) 10.95 (1.67) 11.07 (1.19) 

S4 
Male 12.7 (1.56) 12.81 (1.48) 12.64 (1.67) 12.53 (1.41) 

Female 13.38 (1.96) 13.43 (2.00) 13.26 (1.86) 12.97 (1.62) 

S5 
Male 15.23 (1.58) 15.21 (1.67) 15.06 (1.70) 14.94 (1.60) 

Female 15.22 (1.91) 15.22 (1.71) 15.06 (2.02) 15.08 (2.04) 

S6 
Male 16.58 (1.52) 16.61 (1.54) 16.19 (1.55) 16.25 (1.54) 

Female 16,71 (1.88) 16.60 (1.89) 16.59 (1.89) 16.47 (1.87) 

S7 
Male 19.24 (1.03) 18.40 (1.14) 18.16 (1.07) 18.14 (1.02) 

Female 18.28 (1.54) 18.25 (1.51) 18.24 (1.45) 18.17 (1.48) 

S8 
Male 19.31 (0.91) 19.14 (1.02) 19.02 (0.93) 19.35 (0.83) 

Female 19.21 (1.13) 19.12 (1.12) 19.21 (1.12) 19.21 (1.12) 
Data are expressed as mean (standard deviation). 

 
Table 2. Distribution of orthopantomograms according to age and sex (n=1,200), Ribeirão Preto, Brazil, 2011. 

Age (years) Female Male Total 

9  60 40 100 
10 51 49 100 
11 54 46 100 
12 52 48 100 
13 48 52 100 
14 64 36 100 
15 49 51 100 
16 61 39 100 
17 55 45 100 
18 49 51 100 
19 52 48 100 
20 59 41 100 

Total  654 546 1,200 
 
Table 3. Distribution of female (F) and male (M) subjects according to the stage of mineralization of third 
molars, Ribeirão Preto, Brazil. 

Age 
(yrs) 

Stage of mineralization of third molars 

S1  S2  S3  S4  S5  S6  S7  S8 

F M  F M  F M  F M  F M  F M  F M  F M 

9  41 29  12 7  7 4  0 0  0 0  0 0  0 0  0 0 

10  13 17  12 9  22 17  4 6  0 0  0 0  0 0  0 0 

11  6 4  5 5  16 21  23 16  4 0  0 0  0 0  0 0 



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Biosci. J., Uberlândia, v. 32, n. 3, p. 805-812, May/June. 2016 

12  3 3  4 0  17 12  22 31  6 2  0 0  0 0  0 0 

13 0 0  0 0  5 3  25 21  11 28  7 0  0 0  0 0 

14  0 0  0 0  2 0  21 17  28 11  11 8  2 0  0 0 

15  0 0  1 0  0 1  13 3  19 29  15 26  2 1  0 0 

16  0 0  0 0  0 0  13 1  14 15  29 23  3 3  2 0 

17  0 0  0 0  0 0  7 0  12 18  19 4  12 10  4 3 

18  0 0  0 0  0 0  0 4  8 7  18 13  14 17  9 10 

19 0 0  0 0  0 0  0 0  6 2  13 8  23 22  10 16 

20  0 0  0 0  0 0  0 0  1 0  9 1  13 3  36 37 

 
Table 4. Mean age, standard deviation (SD), standard error of mean (SE), maximum and minimum age 

according to sex and stage of mineralization of third molars, Ribeirão Preto, Brazil, 2011. 
Sex Stage  S1 S2 S3 S4 S5 S6 S7 S8 

Female 

Mean 9.54 10.18 10.95 13.26 15.06 16.59 18.25 19.21 
SD 0.858 1.313 1.242 1.868 2.029 1.895 1.459 1.127 
SE 0.108 0.225 0.149 0.165 0.194 0.172 0.176 0.144 
Maximum 12 15 14 17 20 20 20 20 
Minimum 9 9 9 10 11 13 14 16 

Male 

Mean 9.64 9.90 10.95 12.65 15.06 16.19 18.16 19.02 
SD 0.118 0.768 1.13 1.674 1.704 1.557 1.075 0.931 
SE 0.117 0.168 0.149 0.168 0.161 0.171 0.144 0.137 
Maximum 12 11 15 18 19 20 20 20 
Minimum 9 9 9 10 12 14 15 17 

Kruskal-Wallis 
test (p≤ 0.05) 

p 0.357 0.708 0.998 0.010 0.948 0.066 0.370 0.110 

 
DISCUSSION 

 
The use of orthopantomograms for this type 

of analysis has advantages over other methods, as 
more information can be collected from the same 
source; the panoramic x-ray permits the 
visualization of the teeth since the beginning of 
crown formation up to root apex closure, offering a 
more reliable examination (CORNÉLIO-NETO; 
CONÉLIO; CONCEIÇÃO, 2006); the presence of 
the individual is not necessary for the analysis, 
which provides more agility to the processes 
(ARAÚJO et al., 2010). 

The age range established in the present 
study is of paramount importance because the 
options for age determination become more and 
more restrict over time, which tends to increase the 
intervals of age estimations (ARAÚJO et al., 2010; 
AMARITI et al., 1999). Dental age can be used to 
estimate the chronological age, serving as an 
important instrument for Forensic Dentistry 
(ANDRADE; FERREIRA, 2011). However, 
forensic age estimation can be challenging due to 
the different methods available (ORHAN et al., 
2007). 

At the established age range, third molar 
represents one of the main criteria for age 
determination (CANTEKIN et al., 2012). Regarding 
the difference between sexes, studies have pointed 
to a premature mineralization in females, indicating 
precocity in dental development (MOORREES; 
FANNING; HUNT, 1963; OLZE et al., 2007). 
However, a study performed with 2,218 subjects in 
Japan, South Africa and Germany showed an 
advanced stage of mineralization in males of 
approximately 1½ year compared with females 
(OLZE et al., 2007). This result was compared with 
those of Japanese, South-African and Germany 
populations and led to the conclusion that the 
precocity of mineralization varies among people 
from different countries and regions, showing the 
need of collecting data specific for each population 
(OLZE et al., 2007). 

Chronological age not always represents the 
actual degree of development, as children of the 
same age may present different degrees of tooth 
mineralization and maturity (ANDRADE; 
FERREIRA, 2011). In the present study, the 
comparative analysis revealed that the obtained 
means are very similar to the intervals used by 



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Biosci. J., Uberlândia, v. 32, n. 3, p. 805-812, May/June. 2016 

Nicodemo (NICODEMO, 1969) to characterize 
each one of the 8 stages of tooth mineralization, 
being therefore applicable to the studied population. 

It has been reported that the mean and 
maximum ages in most stages of mineralization are 
slightly superior in the female gender, which 
suggest a faster development among females 
(CANTEKIN et a., 2012). A confirmatory result 
was found in a study with children from the state of 
Maranhão, Brazil, in which the girls presented a 
more accelerated formation of permanent teeth and 
higher mean dental ages than those of boys 
(KURITA et al., 2007). In another study with 
Caucasian Brazilians of both sexes, the teeth of 
females presented an earlier degree of 
mineralization than those of males, without 
significant differences between maxillary and 
mandibular teeth (KVAAL et al., 1995).  

Additionally, it was observed in the present 
study that the mean ages estimated from the 
mineralization stages of maxillary, mandibular, right 
and left third molars was similar, indicating a high 
correlation and the possibility of using any third 
molar for estimation of chronological age with high 
success rate. A similar result was found in a study 
with Spanish children and young people 
(BOLAÑOS et al., 2003). The mean ages estimated 
in the present study are consistent with those of 
different stages of mineralization of third molars 
obtained in others studies (DHANJAL; 
BHARDWAJ; LIVERSIDGE, 2006), also using the 
mineralization chronology of permanent teeth. 

Bolaños (BOLAÑOS et al., 2003) verified 
that sex presents similar age distribution and 
development of third molars without statistically 
significant differences. In another study, the 
radiographs of 928 female Japanese and 686 male 
Japanese were examined and no statistically 
significant difference was found in the 
mineralization stage based on sex or tooth position 
(OLZE et al., 2004).  

Nicodemo (NICODEMO, 1969) suggests 
that the first radiographic evidence of third molar 
can be seen between 7 years and 6 months and 11 
years, that is, in the 90-132-month-old age range. Its 
appearance, however, normally occurs around 9-10 
years old, although the crypt of the germ of tooth 38 
has been detected around the age of 5, which is 
close to the age of 6 verified by other authors 
(BOLAÑOS et al., 2003). In the present study, in 
the 9-year-old age group, the mandibular third 
molars were at least in stage 1 of mineralization, as 
proposed by Nicodemo (NICODEMO, 1969). In the 
maxilla, the initial stages of mineralization are more 
hardly detected due to the more complex anatomy of 

the middle third of the face, which could lead to 
misdiagnosis of agenesis (BOLAÑOS et al., 2003). 
However, part of the 12-year-old sample was also in 
stage 1, which indicates a slight delay. In these 
cases, attention should be given to the fact that if the 
presence of the third molar is not detected up the 
age of 10, there is a 50% chance of agenesis of this 
tooth and this probability is confirmed in most cases 
after the age of 12 (BOLAÑOS et al., 2003). 

Apical closure is observed in stage 8. In the 
present study, this feature was observed at minimal 
age of 16 and maximal age of 20. According to 
Nicodemo (NICODEMO, 1969), apical closure 
occurs between 18 and 20 years, that is, in the 216-
246-month-old age range. Despite the evidence of 
early mineralization, the importance of including the 
age of 18 in this interval should be reaffirmed for 
cases of forensic studies to verify a person’s full 
legal age (PRIETO et al., 2005). It should also be 
reinforced that in this age range as well as in others 
a larger number of maxillary third molars are in 
earlier stages of mineralization than the mandibular 
third molars. 

The third molar is reported to assume a very 
important role at the age of 18. However, a study in 
which third molars of 140 North-American 
individuals were used for age estimation did not find 
correlation between dental age and skeletal age, 
which was justified by the non-homogeneous 
mineralization of the teeth (GARN; LEWIS; 
BONNÉ, 1962). Other authors, on the other hand, 
found a strong correlation between dental age and 
skeletal maturation, showing that regardless of the 
type of tooth, a dental age is closely related to the 
chronological age (LIVERSIDGE, 2008). Engstrom 
et al., (ENGSTROM, C.; ENGSTROM, H.; 
SAGNE, 1983) analyzed the development of third 
molars with respect to chronological and skeletal 
age, and observed correlation between chronological 
age and third molar development in both sexes; 
between chronological age and skeletal maturation; 
and between third molar development and skeletal 
maturation. Those authors suggested that a smaller 
number of mineralization stages associated with a 
longer mineralization of third molars permits a more 
accurate comparisons with the skeletal maturation 
events. 

In this way, it is possible to affirm that the 
evaluation of the stages of mineralization of 
permanent teeth provides the most substantiate base 
for calculation of dental age, which can be 
correlated with the chronological age because the 
mineralization of teeth is less susceptible to the 
influence of external factors than other elements of 
the individual (KARAARSLAN et al., 2010; 



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Biosci. J., Uberlândia, v. 32, n. 3, p. 805-812, May/June. 2016 

ANDRADE; FERREIRA, 2011; KURITA et al., 
2007). Estimation of dental age can thus be a 
valuable instrument for forensic estimation of 
chronological age (ANDRADE; FERREIRA, 2011). 

 
CONCLUSIONS 

 
The Nicodemo’s scores are applicable for 

estimation of age based on the stage of 
mineralization of third molars on 
orthopantomograms, regardless of the quadrant of 
dental arch; the analysis of the calcification stage of 
third molars can be an auxiliary tool to determine 
chronological age; and the tooth mineralization 
stage figure employed in this study was applicable 

for using third molars as parameters for age 
estimation in the studied population.  

The data described in this study may 
provide a reference for forensic application, but 
additional studies with a larger population sample 
should be conducted to meet provisions of more 
accurate data concerning Brazilian subjects. 
 
ACKNOWLEDGEMENTS 
 

The authors would like to thank to Prof. Dr. 
Plauto Christopher Aranha Watanabe from Ribeirão 
Preto Dental School, University of São Paulo, for 
the inestimable assistance to this study and FAPESP 
for the financial support. 

 
 

RESUMO: A identidade de uma pessoa é importante do ponto de vista ético, legal e criminal, assim, a 
determinação de idade é, muitas vezes, o início do processo de identificação. O objetivo do trabalho foi verificar a 
aplicabilidade da utilização de estágios de mineralização de terceiros molares na estimativa de idade. Para isso, foram 
examinadas 1200 radiografias panorâmicas de indivíduos com idade entre 9 e 20 anos, por meio da utilização dos estágios 
de mineralização dos terceiros molares da Tabela de Nicodemo. Foi constatada diferença estatisticamente significante no 
desenvolvimento do terceiro molar entre o gênero masculino e feminino no estágio 4 de mineralização dos dentes 18 
(p=0,008), 28 (p=0,029), 38 (p=0,010) e 48 (p=0,046). Conclui-se que a tabela utilizada com os estágios de mineralização 
é aplicável no que se refere à utilização do terceiro molar enquanto parâmetro para estimativa de idade, na população 
estudada. 
 

PALAVRAS-CHAVES: Antropologia forense. Odontologia Legal. Radiologia. 
 
 
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