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1http://dx.doi.org/10.20396/bjos.v16i0.8651062

Volume 16
2017
e17040

Original Article

1 MSc Student, Department of 
Orthodontics, School of Dentistry, 
Universidade Federal Fluminense, 
Niterói, Rio de Janeiro, Brazil.

2 Adjunct professor, Department of 
Orthodontics, School of Dentistry, 
Federal Fluminense University, 
Niterói, Rio de Janeiro, Brazil.

3 Professor and chair, Department 
of Orthodontics, School of Dentistry, 
Universidade Federal Fluminense, 
Niterói, Rio de Janeiro, Brazil.

Corresponding author:  
Taísa Figueiredo Chagas.  
Disciplina de Ortodontia. Faculdade 
de Odontologia. Rua Mário Santos 
Braga, 30, 2º andar, sala 214- CEP 
24.020-140. Niterói/RJ- Brazil. Tel: 
(21) 2622-1621 / (21) 2629-9812. 
chagastaisa@hotmail.com

Received: April 21, 2017 

Accepted: September 14, 2017

The facial profile in 
brazilian adults
Taísa Figueiredo Chagas1, Mariana Martins e 
Martins2, José Nelson Mucha3

Aim: To investigate if there is agreement between 
measurement values obtained for Brazilian adults and the 
values recommended by Holdaway, Merrifield, Burstone, 
Steiner and Ricketts, for facial profile soft tissue analysis. 
Methods: A sample of 30 cephalometric radiographs was 
used, consisting of 15 women and 15 men, aged 18 to 
31 years, all exhibiting excellent occlusion and balanced facial 
profile. Comparisons were made with the measurement 
values proposed by the aforementioned authors using 
Student’s t-test and to determine the correlation between the 
ANB and Â-H measurement values described by Holdaway, 
using Pearson’s correlation coefficient. Results: Among 
the measures evaluated, 4 showed statistically significant 
differences: Â.Z (Merrifield), S-LS and S-LI (Steiner), and E-LI 
(Ricketts) relative to the standards recommended by the 
authors. The measurement values advocated by Merrifield, 
Steiner and Ricketts showed statistical differences, and as for 
the Z-angle, Brazilians feature a slightly more convex profile, 
which appeared slightly concave according to Steiner, and 
according to the E-Plane (Ricketts), it meant an increased 
protrusion of the lower lip. Conclusion: It could be asserted 
that adult Brazilians have a slightly more convex facial profile 
than US standards, but these differences should be viewed 
with caution, as they are clinically unimportant.

Keywords: Cephalometry; Diagnostic Imaging, Radiography

https://www.ncbi.nlm.nih.gov/mesh/68011859


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Chagas et al.

Introduction

Variables such as gender and ethnic origin have different characteristics of skeletal, 
dental and soft tissue normality, which require knowledge of what is considered nor-
mal or standard in each ethnic group1-4. In addition, patients expect results to be in 
accordance with social and cultural standards of beauty prevalent in their reference 
group, the Zeitgeist, as well as in society in general5.

The standards for hard and soft tissues should be considered in establishing a bal-
anced facial aesthetics and an ideal functional occlusion. However, the most widely 
accepted normative values are based on studies of untreated subjects of European6,7, 
or North American stock8.

Thus, white Brazilian adults with excellent occlusion might display the position of the 
lips in the contour of the facial profile in a different relationship from those advo-
cated by various authors for a population of North American or European origin, which 
would necessarily entail different clinical decisions when planning the orthodontic 
treatment. 

Although the issue has been addressed in the literature, no single work has hitherto 
evaluated the major facial profile measurements for white Brazilian adults with a bal-
anced facial profile and established an ideal occlusion.

The aim of this study was to investigate if there is agreement between the measure-
ment values obtained for white Brazilian adults and the values recommended by 
Steiner6, Ricketts8, Holdaway9,  Burstone10, e Merrifield11  for an analysis of facial profile 
soft tissues. The tested null hypothesis was that there would be no statistically sig-
nificant difference between the measurement values obtained and the values recom-
mended by these authors.

Material and methods
Cephalometric measurements of facial profile soft tissues were obtained from 30 
cephalometric radiographs from the archives of the Department of Orthodontics, Fed-
eral Fluminense University, composed of white Brazilian adults aged 18 to 31 years 
old with all teeth, in established normal or excellent occlusion and balanced facial 
profile. The sample comprised 15 women (mean age = 22.67 ± 3.48) and 15 men 
(mean age = 23.93 ± 3.47).

Inclusion criteria were: subjects with all teeth in normal or excellent occlusion and 
balanced facial profile. Controversial occlusion cases were examined by three ortho-
dontists and removed from the sample, as were patients with a history of trauma and 
previous orthodontic treatment. 

Cephalometric radiographs were taking in natural head position and the cephalo-
grams were traced manually by a single calibrated operator. The anatomical details, 
points, lines and planes that make up the analysis of soft tissue described by Steiner6, 

Ricketts8, Holdaway9,  Burstone10, e Merrifield11  and were marked (Figure 1). 



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Chagas et al.

In order to assess intraexaminer method error measurements from 10 radiographs 
were evaluated in two stages, with a minimum interval of one week. After the ini-
tial evaluation, new tracings were carried out, determining the new points, lines and 
planes that make up the analysis of the soft tissues proposed for the study. Moreover, 
intraclass correlation coefficient (ICC) was applied.

The means and variations around the means were obtained and comparisons with 
the measurement values advanced by the aforementioned authors were made6,8-11.

A pilot study was done for the accomplish of sample calculation in which we selected 
10 participants randomly, indicating the need to include 30 individuals.

The differences between genders and between ages were compared, and the Shap-
iro-Wilk test was used to analyze data normality. Student’s t-test was applied to those 
variables whose data distribution was normal in order to compare the means for gen-
der characteristics. The purpose was to determine whether or not sexual dimorphism 
was present. Furthermore, the Mann-Whitney test was applied to those variables 
whose data distribution was abnormal. 

The mean measurement values found in this study were compared to the values 
proposed by the authors6,8-11 using t-test. The correlation between ANB and Â-H 
measurement values as described by Holdaway9 was tested using Pearson’s cor-
relation coefficient. 

Figure 1. Measures used (1) H-Angle9; (2) ANB angle9; (3) Z-Angle11; (4) Linear measurement from the most 
anterior point of the upper lip to the line joining the subnasal and Pogonion points10; (5) Linear measurement 
from the most anterior point of the lower lip to the line joining the subnasal and Pogonion points10; 
(6) Linear measurement from the most anterior point of the upper lip to the line joining the midpoints of 
the base of the nose to the Pogonion6; (7) Linear measurement from the most anterior point of the lower 
lip to the line joining the midpoints of the base of the nose to the Pogonion6; (8) Linear measurement from 
the most anterior point of the upper lip to the line connecting the tip of the nose and Pogonion points8; 
(9) Linear measurement from the most anterior point of the lower lip to the line joining the tip of the nose 
and Pogonion points8

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Chagas et al.

Biostat 5.3 (Belém, Pará, Brazil) software was employed for statistical analysis and 
significance level of 5% was adopted for all tests (p<0.05).

Results
In evaluating ICC, excellent reproducibility was found in most measures (Â.H, ANB, 
Â-Z LB-LS and LB-LI), as well as an average to good reproducibility in 4 other mea-
sures (S-LS, S-LI, E-LS and E-LI).

Age in the total sample ranged from 18 to 31 years, with a mean value of 23.30 
(SD ± 3.48). In males, the mean value was 23.93 (SD ± 3.47), and in females, 22.67 
(SD ± 3.48), with no statistically significant difference between the groups as a result 
of the Mann-Whitney test (p-value = 0.2998).

All individuals included have a balanced facial profile. Twenty eight were skeletal Class 
I (ANB between 0 and 4.5) and only one take ANB=-1 and another take ANB=5. 

Each of the nine measures was evaluated to elicit differences between genders. 
Distribution was tested by the Shapiro-Wilk test. The five measurements showed 
abnormal distribution (A-H, LB, LS, LI S-E-E-LS, LI). The Mann-Whitney test was 
applied to these measurements and independent t test was used for other mea-
surements with normal distribution.

Given that no significant differences were found between the genders, the subgroups 
were gathered in a single sample group (n = 30) and statistical analysis was per-
formed with independent t test (Table 1).

No statistically significant differences were found between the means of the ANB 
and Â.H measurement values using the parameters provided by Holdaway9. The 
same proved true for the LB-LS and LB-LI mean values using the parameters pro-
vided by Burstone10.

Table 1. Statistical results for measurement values obtained for white Brazilian adults and the values 
recommended by authors for an analysis of facial profile soft tissues

Measure Mean (SD)
Standard 

error
Range

Author’s 
mean

Diferences 
between mean 

and author’s mean
P

Holdaway
Â.H (0) 8.11 (2.42) 0.44 1.5/13.9 8 0.11 0.7939

ANB (0) 1.68 (1.17) 0.21 -1/5 2 0.32 0.1491

Merrifield ÂZ (0) 77.93 (4.85) 0.89 66/89 80 2.07 0.0267*

Burstone
LB-LS mm 3.41(1.75) 0.32 -2.5/6 3.5 0.09 0.7963

LB-LI mm 2.28 (1.56) 0.29 -1/5 2.2 0,08 0.7761

Steiner
S-LS mm -1.48(1.6) 0.29 -5/2 0 -1.48 <0.0001*

S-LI mm -1.01(1.6) 0.29 -4/1.5 0 -1.01 0.0016*

Ricketts
E-LS mm -4.85 (2.58) 0.48 -9/5 _ - _

E-LI mm -2.78 (2.71) 0.50 -6/5 -4 -1.22 0.0203*

*Significant difference (p < 0.05) based on Independent t test



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Chagas et al.

Holdaway9 described a correlation between ANB and Â-H. Thus, this correlation 
was tested in this sample using the Pearson correlation coefficient, and a positive 
(r=0.4419) and significant (p=0.0144) correlation was found. Due to the dependence 
among these measures a simple linear regression was performed and found the 
equation:  y=6.5766x + 0.9149x, where y=A.H and x=ANB.

A statistically significant difference was found between mean Â.Z values in the 
sample and those provided by Merrifield11. Differences were also found between 
the means of the S-LS and S-LI measurement values compared to the standards 
provided by Steiner6; and between the mean values for E-LI relative to the norms 
provided by Ricketts8.

Only a descriptive analysis of the E-LS was performed since Ricketts8 failed to provide 
a reference value for this measure.

Discussion
Regarding Holdaway’s9 analysis, given that statistically significant differences were 
not observed among the measures of this sample and the above measures, one can 
consider that the standards and correlations of this analysis can be applied to white 
Brazilian adults.

For the Z-Angle a mean of 77.93 degrees was found, 2.07 degrees less than the value 
recommended by Merrifield11, suggesting a slightly larger convexity in the profile of 
white Brazilian adults. Although it is a small difference it proved statistically signifi-
cant. But clinically, this difference cannot be considered relevant. Leichsenring et al.12 
found a mean of 71.75 degrees and  Yu et al.13 found a mean of 68.33 for the Z-Angle 
in a study conducted with Chinese patients with normal occlusion and balanced pro-
files, values lower than the 77.93 degrees found in this study. This is probably due to 
age differences between the samples and can be attributed to the early maturation of 
girls14. It is to be expected that due to mandibular growth there should be an increase 
in this angle.

In measuring the Subnasal-Pogonion line in the soft tissues relative to the lips10 the 
values for LB-LS=3,41mm and LB-LI=2,28mm, appeared very close to the standards. 
However, this applied only to adolescents with normal occlusion (LB-LS=3.50 and 
LB-LI=2.20). One can therefore consider that the measurement values for American 
teenagers resemble those of Brazilian adults. 

The S-LS (-1,48mm) and S-LI (-1.01 mm) measures in this study showed slightly more 
retruded upper and lower lips compared to the standard established by Steiner6. These 
differences were significant. Moreover, the lower lip protruded more than the upper lip. 
The differences found in this study can be attributed to the growth of the nose and 
chin regions, causing the lips to take on a more retruded position relative to this line15.

These differences may be explained by ethnic differences in each group. Erbay, 
Caniklioğlu, Erbay et al.16 evaluated 96 Turkish adults aged between 21.63 and 
22.45 years, with normal occlusion, and also found lips that were more retruded than 
the values recommended by Steiner6 (women: S-LS=2.7mm and S-LI=-2.0mm, and 
men S-LS=3.3mm and S-LI=-2.7mm). Isiekwe et al.17  in evaluating 100 adult Nige-



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Chagas et al.

rian individuals (ages 18 to 25 years) with normal occlusion found the values of 
S-LS=5.89 mm and S-LI=8.19 mm, indicating lips that were much more protruded 
than the values established by Steiner.6 Sharma18 also found upper and lower lips that 
were more protruded than Steiner’s standards6 in assessing 121 Nepalis with normal 
occlusion and well balanced faces (S-LS=2.1mm and S-LI=2.2mm).

Regarding the measurement values found for Ricketts’ aesthetic plane8, the E-LS aver-
aged -4.85 mm and could not be compared quantitatively owing to the lack of a ref-
erence value. The difference was attributed to the early maturation of girls and their 
increased nose growth compared to boys. Freitas et al.19 also found different results 
in white Brazilians with normal occlusion (E-LS = -4.23mm), and although a sample of 
adolescents was used, the results were similar to those found in this study.

In measuring E-LI, the mean was -2.78mm, with the lower lip positioned 1.22mm more 
anteriorly in relation to the standards established by Ricketts8, suggesting that the 
lower lip in white Brazilian adults is more protruded than advocated by the author, and 
with a significant difference. Nobuyasu et al.20 in evaluating Brazilian individuals aged 
between 12 and 15 years with normal occlusion also found more protruded lower 
lips (-0.95mm ± 2,37mm). Freitas et al.19 found -1.96mm for E-LI in white Brazilian 
adolescents with normal occlusion. However, the nose and chin positions were not 
evaluated separately, and those with a more developed nose and chin can provide a 
good aesthetic appearance due to their greater labial protrusion21. Lahlou et al.22 also 
found more retruded upper and lower lips (E-LS=-1.23mm and E-LI=-0.05mm) after 
evaluating 102 Moroccan adults with normal occlusion and mean age of 21 years and 
6 months.

Cephalometric measurements should not be used strictly for face evaluation and/or 
clinical examination. Furthermore, extraoral photographic analysis is also extremely 
important. However, it is still through measurements that we can quantify patient 
changes and guide our treatment plans.

Neglecting soft tissue analysis and evaluating dental and skeletal relationships sepa-
rately can produce misleading results since the soft tissues of the face vary in thick-
ness, length and postural tonus in different individuals6.

It is important to consider the specific variations in different populations and establish 
standards for each group, which should be treated according to their own characteristics23.

In the present study, a sample group with ages ranging from 18 to 31 years was 
selected because we wanted to establish an excellent occlusion involving no changes, 
or at most minimal growth–driven changes in the facial profile so as to allow com-
parisons to be made. But caution should be exercised in growing patients, and the 
changes in nose, chin and lip growth should be considered. Nose growth is greater 
in boys than in girls, and the convexity of the profile soft tissue increases with age, 
influenced by the position of the nose24.

Holdaway’s9 was the best analysis for relating the position of the lips with the other 
structures of the facial profile. Besides, it yielded similar results to this sample. Bur-
stone’s10 analysis uses an area of stable growth, i.e., the subnasal point, and also 
showed results that were similar to this sample.



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Chagas et al.

Although this study was concerned with establishing standards for white Brazilian adults, 
one should take into account the fact that Brazil is a huge country with an interbred popu-
lation, making it difficult to establish a single diagnosis and planning standard. One must 
also take into account each individual’s ascendency19,25, as there are differences in dento-
facial relationship depending on the ethnic variability of each racial group19.

This study was concerned with setting standards for white Brazilian adults, and by 
including only whites, one should take into account the fact that Brazil is a huge coun-
try with an interbred population, making it difficult to establish a single diagnosis and 
planning standard. The authors consider a limitation of this study the fact that the 
ancenstry of each individual included in the sample was not determined and evalu-
ated as there are differences in the dentofacial relationship depending on the ethnic 
variability of each racial group19,25.

Contemporary orthodontics recognizes the ethnic diversity of human facial contours. 
However, we still use cephalometric measurements that were designed for specific 
populations. Thus, the present work contributes to clinical practice as it establishes 
which cephalometric measures of soft tissue evaluation can be used for white Bra-
zilian adults and which should be evaluated with caution. Even though some of the 
measurement values presented statistically significant differences compared to the 
standards or means recommended by different authors one can consider, from a clin-
ical point of view, that the differences were of approximately 1 to 1.5mm, and that 
these values are therefore very close to the standards, enabling us to use these mea-
surements as a parameter for white Brazilian adults.

It should also be emphasized that there is a wide variety of facial and ethnic types 
among individuals seeking treatment to improve the aesthetic appearance of their 
facial profile, thereby rendering these small differences of little clinical significance.

In conclusion, no statistically significant differences were found between the mean 
values obtained in this sample and the mean values recommended by Holdaway and 
Burstone. The measurement values advocated by Merrifield, Steiner and Ricketts 
showed statistical differences. Nevertheless, regarding the Z-angle, Brazilians feature 
a more convex profile, which was slightly more concave compared to Steiner’s, and 
showed an increased protrusion of the lower lip compared to the E-Plane (Ricketts). 
It could be asserted that white Brazilian adults have a slightly more convex facial pro-
file than US standards, but these differences should be viewed with caution, as they 
are clinically unimportant.

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