Evaluation of Facial Beauty Using Anthropometric Proportions


Research Article
Evaluation of Facial Beauty Using Anthropometric Proportions

Jovana Milutinovic,1 Ksenija Zelic,2 and Nenad Nedeljkovic1

1 Jovana Milutinovic, Nenad Nedeljkovic, Clinic of Orthodontics, University of Belgrade, 11000 Belgrade, Serbia
2 Ksenija Zelic, Laboratory for Anthropology, Department of Anatomy, School of Medicine, University of Belgrade,
11000 Belgrade, Serbia

Correspondence should be addressed to Nenad Nedeljkovic; nenad.nedeljkovic70@gmail.com

Received 27 November 2013; Accepted 19 December 2013; Published 20 February 2014

Academic Editors: R. G. Palma-Dibb and K. H. Zawawi

Copyright © 2014 Jovana Milutinovic et al. This is an open access article distributed under the Creative Commons Attribution
License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly
cited.

The improvement of a patient’s facial appearance is one of the main goals of contemporary orthodontic treatment. The aim of this
investigation was to evaluate the difference in facial proportions between attractive and anonymous females in order to establish
objective facial features which are widely considered as beautiful. The study included two groups: first group consisted of 83
Caucasian female subjects between 22 and 28 years of age who were selected from the population of students at the University
of Belgrade, and the second group included 24 attractive celebrity Caucasian females. The en face facial photographs were taken in
natural head position (NHP). Numerous parameters were recorded on these photographs, in order to establish facial symmetry and
correlation with the ideal set of proportions. This study showed significant difference between anonymous and attractive females.
Attractive females showed smaller face in general and uniformity of the facial thirds and fifths, and most of the facial parameters
meet the criteria of the ideal proportions.

1. Introduction

Specialists in charge of the facial region are noticing a growing
demand for the treatment mainly based on aesthetic prin-
ciples. As a result, orthodontists and maxillofacial surgeons
should have a great understanding for quantitative, objective
facial features, which are widely considered as attractive and
beautiful [1, 2].

Recently, many linear and angular measures of soft tissue
profile and variety of cephalometric analyses were developed
to determine ideal proportions [1–4].

When it comes to making a positive first impression,
having an aesthetically pleasing face, including an attractive
smile, ranks first among all factors.

Today’s society is overwhelmed with the importance
of being attractive through a variety of media. That fact
brings facial standards together with the perception of beauty
associated with a sense of social acceptance [5–9]. It was
shown in the results of many studies that confidence is closely
related to physical appearance [10–12].

Today’s most common reason for seeking orthodon-
tic treatment is enhancement of facial beauty through

orthodontic and orthognathic procedures. Unlike the 1980,
when 25% of patients required orthodontic treatment for
aesthetic reasons, today this percentage has risen to over 75%,
which means that 3 out of 4 patients specifically request an
improvement of facial appearance [13].

Beauty is not an exact science but according to some
plastic surgeons there is a specific proportion system that
includes facial height, width, and symmetry. However, the
definition of an attractive and beautiful face is subjective, with
many included factors—social, cultural, ethnic, and age [10].

The beauty of the person’s face is determined by the har-
mony of proportions and symmetry [12]. Ideal proportions
are directly related to the so-called divine proportions and
the most important value in relation to these proportions is
1 : 1.618 [11–18].

The knowledge of divine proportion exists since ancient
Greek sculptor Phidias, and it was firstly scientifically
described by Filius Bonacci, discoverer of the numerical value
of the divine proportions [19]. More relevant to the dental
profession as well as the medical profession (such as plastic
surgeons) are the divine proportions of the human face.

Hindawi Publishing Corporation
e Scientific World Journal
Volume 2014, Article ID 428250, 8 pages
http://dx.doi.org/10.1155/2014/428250

http://dx.doi.org/10.1155/2014/428250


2 The Scientific World Journal

Tr

Ln

Me

LC

sto

Me

1.618

1.618

1.0

1.0

(a)

1.618

1.0

2/3

1/3

(b)

Figure 1: Lengths of the face and set of ideal proportions.

This particularly applies to the orthodontic treatment
given that the objectives to be achieved at the end of the
treatment are not only functional stability, but also facial
esthetic improvement [20].

The aim of our paper was to try to establish objective facial
features which are widely considered as beautiful. Therefore,
specific aims of this paper were the following:

(1) to compare the facial proportions of two groups
of females (anonymous and attractive) in order to
establish the difference between them,

(2) to determine the deviation from the values of ideal
proportions (ratio 1 : 1.618) in both groups,

(3) to compare the difference between facial parameters
representing facial height and width in both groups.

2. Methods

The study comprised two groups. First group consisted of
83 female subjects between 22 and 28 years of age who
were selected from the population of medical and dental
students at the University of Belgrade, and the second group
included 24 attractive celebrity females (popular models
and actresses). Celebrities whose photos were used in this
study were mostly models and actresses whose facial beauty
was studied closely by the experts in the field of plastic
surgery, and among them are those who were named as

most beautiful and most proportional faces by the beauty
and fashion magazines (such as Vogue, Cosmopolitan, and
New Woman). The en face facial photographs were taken in
natural head position (NHP), using camera Canon Power
Shot G6, 7.1 MP, with the same distance of 1.2 m. After
training and calibration, all measurements on photographs
were performed by the first author (Jovana Milutinovic).
In order to test the feasibility and reproducibility of the
measurements, 12 photographs (10% from each group) were
selected and reassessed by the same author, two months after
the initial assessment. Therefore, to evaluate intra-observer
agreement, Cohen’s Kappa test was applied following the
instructions by Landis and Koch [21].

The soft tissue points used for obtaining linear distances
which were measured are shown in Table 1.

In the photographs, the following parameters were mea-
sured:

(1) lengths of the face (Figures 1(a) and 1(b)):

(i) (Tr-Me): height of the face,
(ii) (lchk r-lchk l): width of the face,
(iii) (Me-sto): the lowest point on the chin and the

point where the upper and lower lip merge,
(iv) (sto-LC): the point where the upper and lower

lip merge and corner of the eye,



The Scientific World Journal 3

Table 1: Soft tissue points.

Point Clarification
Trichion (Tr) The beginning of the forehead when one lifts the eyebrow
Glabella (Gl) The most prominent point of the forehead at the superior aspect of the eyebrows
Subnasale (subN) Point in the midsagittal plane where the nasal septum merges into the upper lip
Menton (Me) The most inferior point on the soft tissue chin
Stomion (sto) Midpoint of the intralabial fissure
Postaurale (pa) The most posterior point on the helix (outer rim of the ear)
Exocanthion (ex) Most lateral point of the palpebral fissure at the outer canthus of the eye
Endocanthion (en) Most medial point of the palpebral fissure at the inner canthus of the eye
Cheilion (ch) Corner of the mouth
Lateral canthus (LC) Lateral canthus of the eye
Lateral nose (Ln) Lateral side of the nose
Lateral cheek (lchk) Lateral border of the cheeks

(v) (Me-Ln): the lowest point on the chin and the
outer edge of the nostril,

(vi) (Ln-Tr): the outer edge of the nostril and highest
point of the forehead;

(2) division of the face:

(a) the horizontal thirds of the face (Figure 2):

(1) upper third: Tr-Gl,
(2) middle third: Gl-subN,
(3) lower third: subN-Me;

(b) vertical fifths of the face (Figure 3)

(1) pa r-ex r,
(2) ex r-en r,
(3) en r-en l,
(4) en l-ex l,
(5) ex l-pa l;

(3) the ideal proportions: after marking and connecting
points needed to obtain adequate lengths, measured
parameters were compared with the ideal set of
proportions (1 : 1.618):

(i) the ratio lchk r-lchk l : Tr-Me is expected to be
1 : 1.618 (Figure 1(b)),

(ii) the ratio sto-Me : sto-LC is expected to be
1 : 1.618 (Figure 1(a)),

(iii) the ratio Me-Ln : Ln-Tr is expected to be 1 : 1.618
(Figure 1(a)),

(iv) the ratio subN-sto : subN-Me should be 1 : 3
[19], lower facial third index, that could also
be shown in percentage (30 : 70%) [22] (Fig-
ure 1(b)).

For each and every parameter the ratio between them was
used, so that the actual length of the measured parameters
was of no importance.

Tr

Gl

SubN

Me

Upper 
floor

Middle 
floor

Lower 
floor

Figure 2: Division of the face into horizontal thirds.

3. Statistical Analysis

Statistical analyses were performed using SPSS for Windows,
version 15.

The Kolmogorov-Smirnov test was applied in order to
test whether the data distribution fits probability density
function also known as Gaussian function or bell curve.
Subsequently, if test had not rejected the assumed normal
distribution, the parametric tests would have been used.
For testing the differences in all parameter values between
groups, independent sample 𝑡-test was used. For analyzing
the similarity of vertical thirds and horizontal fifths of
the face, in each group one-way ANOVA test was applied
and in cases where ANOVA showed statistically significant



4 The Scientific World Journal

Table 2: Length parameters of the face for attractive and anonymous females.

Group Mean (mm) Std. dev. Std. error mean 𝑡-test

Trichion-glabella Anonymous females 47.4759 6.90568 0.75800 0.144
Attractive females 43.7500 11.57302 2.36233

Glabella-subnasale Anonymous females 44.6506 6.77366 0.74351 0.010
Attractive females 38.1458 10.97772 2.24082

Subnasale-menton Anonymous females 49.6084 6.59039 0.72339 0.001
Attractive females 42.5625 8.78402 1.79303

Subnasale-stomion Anonymous females 17.2169 2.47573 0.27175 0.001
Attractive females 14.2708 3.69776 0.75480

Menton-stomion Anonymous females 32.4398 4.58816 0.50362 0.002
Attractive females 28.3333 5.43472 1.10936

Stomion-lateral canthus Anonymous females 50.8735 7.18393 0.78854 0.071
Attractive females 45.9375 12.26635 2.50386

Menton-lateral nose Anonymous females 57.3675 7.92229 0.86958 0.001
Attractive females 48.6250 10.33067 2.10874

Lateral nose-trichion Anonymous females 84.3554 11.91293 1.30761 0.056
Attractive females 75.7500 20.16292 4.11574

Lateral nose-lateral nose Anonymous females 28.2048 3.79830 0.41692 0.006
Attractive females 23.9792 6.68789 1.36516

Cheilion-cheilion Anonymous females 38.5241 4.89145 0.53691 0.174
Attractive females 35.8125 9.14237 1.86618

Lateral canthus-lateral canthus Anonymous females 72.7952 9.30547 1.02141 0.065
Attractive females 66.1250 16.25894 3.31884

Lateral cheek-lateral cheek Anonymous females 97.0120 11.25209 1.23508 0.132
Attractive females 90.2083 20.56533 4.19788

Trichion-menton Anonymous females 141.7229 18.82530 2.06634 0.013
Attractive females 124.4583 30.17086 6.15860

pa r ex r en r en l ex l pa l

Figure 3: Division of the face into vertical fifths.

difference between parameters post hoc Bonferroni test for
multiple comparison was applied. To compare differences
between ideal proportions and obtained proportions of the
facial parameters, the authors applied paired samples 𝑡-test
which analyzed the both values in each subject according to
the concept where every particular value has its own paired
“control” value. In all analyses, the significance level was set
at 0.05.

4. Results

The Kolmogorov-Smirnov test showed normality of distri-
bution of the obtained data in both groups. The Kappa
coefficient ranged from 0.715 to 0.899 which is considered to
be substantial to almost perfect agreement [21].

The mean measurement values representing length
parameters of the face for both groups are shown in Table 2
as well as the differences between two groups. Almost
all parameters were significantly smaller in the group of
attractive females.

Tables 3(a) and 3(b) show the divisions of the face into
horizontal thirds and vertical fifths for both groups. One-way
ANOVA showed difference between horizontal thirds and
between vertical fifths in the group of anonymous females,



The Scientific World Journal 5

Table 3: (a) Division of the face into horizontal thirds. (b) Division of the face into vertical fifths.

(a)

Horizontal thirds
Mean Std. dev. ANOVA Post hoc multiple comparison Bonferroni test Sig.

Anonymous females
1 47.4759 6.90568 1 versus 2 5.60417 0.162
2 44.6506 6.77366 0.000 1 versus 3 1.18750 0.919
3 49.6084 6.59039 2 versus 1 5.60417 0.162

2 versus 3 4.41667 0.319
Attractive females

1 43.75 11.57302
2 38.1458 10.97772 0.158
3 42.5625 8.78402

1: trichion-glabella, 2: glabella-subnasale, and 3: subnasale-menton.

(b)

Vertical fifths
Mean (mm) Std. dev. ANOVA Post hoc multiple comparison Bonferroni test Sig.

Anonymous females

1 16.9096 2.58884

1 versus 2 7.21687∗ 0.000
1 versus 3 7.07229∗ 0.000
1 versus 4 7.36145∗ 0.000
1 versus 5 −1.21084 0.114

2 24.1265 3.37841

2 versus 1 7.21687∗ 0.000
2 versus 3 0.14458 0.998
2 versus 4 −0.14458 0.998
2 versus 5 6.00602∗ 0.000

3 23.9819 3.52296 0.000

3 versus 1 7.07229∗ 0.000
3 versus 2 −0.14458 0.998
3 versus 4 −0.28916 0.978
3 versus 5 5.86145∗ 0.000

4 24.2711 3.38243

4 versus 1 7.36145∗ 0.000
4 versus 2 0.14458 0.998
4 versus 3 0.28916 0.978
4 versus 5 6.15060∗ 0.000

5 18.1205 3.20403

5 versus 1 −1.21084 0.114
5 versus 2 6.00602∗ 0.000
5 versus 3 5.86145∗ 0.000
5 versus 4 6.15060∗ 0.000

Attractive females
1 21.7083 4.94737
2 22.5833 5.66965
3 21.3125 5.43302 0.947
4 22.1208 5.63938
5 22.0833 5.58271

1: postaurale right-exocanthion right, 2: exocanthion right-endocanthion right, 3: endocanthion right-endocanthion left, 4: endocanthion left-exocanthion
left, and 5: exocanthion left-postaurale left.
∗Statistical significance.



6 The Scientific World Journal

Table 4: The differences between ideal proportions and obtained proportions of the facial parameters.

Paired differences between measured and ideal values Paired samples 𝑡-test
Group Mean (mm) Std. dev. Sig.

Subnasale-stomion Attractive females 0.087 1.332 0.751
Anonymous females 0.685 1.253 0.000

Stomion-lateral canthus Attractive females 0.100 6.549 0.941
Anonymous females −1.597 4.655 0.003

Lateral nose-trichion Attractive females −2.929 9.031 0.126
Anonymous females −8.466 7.995 0.000

Lateral canthus-lateral canthus Attractive females 3.358 3.953 0.000
Anonymous females −1.041 4.390 0.034

Cheilion-cheilion Attractive females −2.983 3.353 0.000
Anonymous females −7.112 3.192 0.000

Trichion-menton Attractive females −21.500 7.251 0.000
Anonymous females −15.237 6.669 0.000

while in the attractive females group facial thirds and fifths
were equal, with no statistical difference.

Using multiple comparison test in the group of anony-
mous females (Tables 3(a) and 3(b)), distance postaurale-
exocanthion (pa-ex), or the most lateral fifth of the face
presented by the earlobe section of the face, was found to
be significantly smaller than medial three vertical fifths of
the face. However, 1st and 5th vertical fifths were not signif-
icantly different one from another. Likewise, the significant
difference for the middle third in comparison with the 1st and
3rd thirds of the face was found in the group of anonymous
females as it was also significantly smaller. There was no
significant difference between 1st and 3rd thirds.

Parameters representing division of the lower third of
the face into two lengths, upper distance from the point
subnasale to stomion, or the thickness of the upper lip, and
lower distance from the point stomion and menton, which
are supposed to be in relation 1/3 : 2/3, satisfied this criterion
in the group of attractive females but not in the group of
anonymous females.

Table 4 refers to the comparison of the differences
between ideal proportions and obtained proportions of the
facial parameters. To compare these values, the authors
applied paired samples 𝑡-test. All analyzed parameters were
found to be statistically different from the ratio 1 : 1.618 in
the group of anonymous females. However, in the group of
attractive females, three out of six parameters (subN-sto, sto-
LC, and Ln-Tr) correspond to ideal ratio.

5. Discussion

The aim of this investigation was to evaluate the difference
in facial proportions between attractive and anonymous
Caucasian females.

Comprehension and analysis of facial parameters are
necessary in different fields of medicine and dentistry, espe-
cially among specialists like plastic surgeons, maxillofacial
surgeons, orthodontists, and prosthodontists [23, 24].

Keeping that in mind, there is a need for clinicians who
work in a maxillofacial region to understand and become
familiar with guidelines for esthetic standards and parameters
of the soft tissue [22, 25, 26].

Bashour [10] found that there are four most impor-
tant cues determining attractiveness: averageness, sexual
dimorphism, youthfulness, and symmetry. He pointed out
that a surgeon who is planning facial cosmetic, plastic, or
reconstructive surgery can potentially gain both profound
comprehension and better quality surgical results by appre-
ciating these findings.

Division of the face into thirds and fifths is commonly
used photogrammetric method for assessing facial symmetry.
In our study, all of these measures were uniform in the
group of attractive females. In 2009, Sforza et al. examined
the difference between two groups of women, 24 attractive
ones with 71 “normal” (healthy reference women), and
obtained similar results [6]. Attractive females had several
“neonatal” characteristics, such as relatively large forehead
and a rounded and smaller face in general; they stated that
“babyness” is the characteristic that separates them from the
normal group. In our research, attractive females also had a
smaller face, considering majority of parameters of the face.

Mack [27] was the first to demonstrate the practical appli-
cation of ideal proportions for improving facial aesthetics.
He discussed the importance of treating the dentition to the
face based on the divine proportion. According to him, the
lower 1/3 of the face significantly influences facial appearance.
As proof, he stresses the public’s preoccupation with fullness
of the lips and the importance of a pleasing smile. These
so-called Vitruvian thirds [22] in the lower face have to be
adjusted to a 30% upper lip, 70% lower lip-chin proportion.
In our study, attractive group showed harmonized lower
third of the face, with lower facial index (subnasale-stomion,
stomion-menton) in accordance with this beauty cannon
(30% : 70%). Therefore, this ideal ratio should be suitable in
planning concept for treatment in facial region [22]. These
distances and divisions in the lower third of the face are one
of the most important in the evaluation of facial beauty, given



The Scientific World Journal 7

the fact that the lips and the chin highly determinate female
beauty [12, 28].

Women lips are very impressionable feature of the face
and have a strong influence on facial beauty perception.
Various studies (Bisson and Grobbelaar, 2004, Ward, 1989,
Torsello et al., 2010, Mommaerts and Moerenhout, 2010, and
Anic-Milosevic, 2010), in which authors analyzed the lower
third of the face and the lips, stated that these are one of the
five important characteristics in female facial aesthetics [29–
32].

Ferrario et al. (1995) reported that attractive women share
several similar characteristics, such as increased upper facial
third (forehead), smaller face, and more voluminous (thicker)
lips than nonattractive ones. In addition, it was stressed that
the length of the nose was therefore smaller in attractive
group. In their research, they compared 10 attractive and
40 normal women and stated that facial characteristics of
attractive females showed uniformity, while facial parameters
in a normal group differed from ideal proportions [24]. In the
study of Hall et al. [33] it was shown that thickness of the
lips was one of the main features in the beauty perception
based on a poll among orthodontists and lay public. Perseo
[34] stated that, in some cases, standard camera distortions
in cinema images made certain female faces appear more
beautiful because they are overall “shortened.”

The studies of several authors have obtained the same
results [35–37].

In the present investigation, the values for vertical length
parameters, such as distance between points Me-ch and
ch-LC as well as Me-Ln and Ln-Tr, which should be in
relation determined by ideal proportions, differed in the
group of anonymous female group. Therefore, faces of famous
attractive females who represent contemporary canons of
beauty are closer to the ideal proportions [5].

The question that always seems to intrigue scientists deal-
ing with facial beauty is timelessness of the beauty principles
established centuries ago. Torsello et al. (2010) found that
some of the neoclassical canons can be considered still valid,
while others seem to be changed over centuries. According
to their research, it seems that reductions in facial medium
third, in distance between eyes, and in nose dimensions have
occurred as well as relative enlargement of eyes and mouth
width [31].

Mommaerts and Moerenhout (2010) showed in their
research that some of the ancient and neoclassical canons of
beauty are still unchanged, despite the fact that some of these
canons were established 2500 years ago.

These guidelines considering facial beauty can be used
for improving patient’s facial appearance. Clinicians must
be aware that each and every person has their own beauty
perception, so these results should be viewed with caution.

6. Conclusions

Facial beauty and its determiners are one of the most arguable
topics among surgeons, dentists, and orthodontists. They
can all agree about some objective guidelines concerning
facial proportions, symmetry, and ratio between specific

facial parameters. However, more subjective understanding
of beauty is still immeasurable and lies in the eye of beholder.

This study showed significant difference between anony-
mous and attractive females. Attractive females showed
smaller face in general and uniformity of the facial thirds and
fifths, and most of the facial parameters meet the criteria of
the ideal proportions.

Conflict of Interests

The authors declare that there is no conflict of interests
regarding the publication of this paper.

Acknowledgment

This study is supported by the Ministry of Science and
Education of the Republic of Serbia, Grant no. 45005.

References

[1] S. A. Milošević, M. L. Varga, M. Šlaj et al., “Analysis of the soft
tissue facial profile of croatians using of linear measurements,”
Journal of Craniofacial Surgery, vol. 19, no. 1, pp. 251–258, 2008.

[2] S. A. Milošević, M. L. Varga, M. Šlaj et al., “Analysis of the soft
tissue facial profile by means of angular measurements,” Euro-
pean Journal of Orthodontics, vol. 30, no. 2, pp. 135–140, 2008.

[3] N. Powell and B. Humphries, Proportions of the Aesthetic Face,
C.M. Thieme-Stratton, New York, NY, USA, 1984.

[4] A. Hockley, M. Weinstein, A. J. Borislow, and L. E. Braitman,
“Photos vs silhouettes for evaluation of African American pro-
file esthetics,” American Journal of Orthodontics and Dentofacial
Orthopedics, vol. 141, no. 2, pp. 161–168, 2012.

[5] F. B. Naini, J. P. Moss, and D. S. Gill, “The enigma of facial
beauty: esthetics, proportions, deformity, and controversy,”
American Journal of Orthodontics and Dentofacial Orthopedics,
vol. 130, no. 3, pp. 277–282, 2006.

[6] C. Sforza, A. Laino, R. D’Alessio, G. Grandi, M. Binelli, and V.
F. Ferrario, “Soft-tissue facial characteristics of attractive Italian
women as compared to normal women,” Angle Orthodontist,
vol. 79, no. 1, pp. 17–23, 2009.

[7] S. Matoula and H. Pancherz, “Skeletofacial morphology of
attractive and nonattractive faces,” Angle Orthodontist, vol. 76,
no. 2, pp. 204–210, 2006.

[8] F. Meneghini, Clinical Facial Analysis. Elements, Principles and
Techniques, Springer, Heidelberg, Germany, 2005.

[9] P. Van Der Geld, P. Oosterveld, G. Van Heck, and A. M. Kuij-
pers-Jagtman, “Smile attractiveness: self-perception and influ-
ence on personality,” Angle Orthodontist, vol. 77, no. 5, pp. 759–
765, 2007.

[10] M. Bashour, “History and current concepts in the analysis of
facial attractiveness,” Plastic and Reconstructive Surgery, vol. 118,
no. 3, pp. 741–756, 2006.

[11] A. M. Şahin Saǧlam, “Holdaway measurement norms in Turkish
adults,” Quintessence International, vol. 33, no. 10, pp. 757–762,
2002.

[12] C. Borelli and M. Berneburg, “‘Beauty lies in the eye of the
beholder’? Aspects of beauty and attractiveness,” Journal of the
German Society of Dermatology, vol. 8, no. 5, pp. 326–331, 2010.

[13] R. Edler, P. Agarwal, D. Wertheim, and D. Greenhill, “The use
of anthropometric proportion indices in the measurement of



8 The Scientific World Journal

facial attractiveness,” European Journal of Orthodontics, vol. 28,
no. 3, pp. 274–281, 2006.

[14] R. M. A. Kiekens, J. C. Maltha, M. A. van’t Hof, and A. M. Kuij-
pers-Jagtman, “Objective measures as indicators for facial
esthetics in white adolescents,” Angle Orthodontist, vol. 76, no.
4, pp. 551–556, 2006.

[15] H. Pancherz, V. Knapp, C. Erbe et al., “Divine proportions in
attractive and nonattractive faces,” World Journal of Orthodon-
tics, vol. 11, no. 1, pp. 27–36, 2010.

[16] O. F. Husein, A. Sepehr, R. Garg et al., “Anthropometric and
aesthetic analysis of the Indian American woman’s face,” Journal
of Plastic, Reconstructive and Aesthetic Surgery, vol. 63, no. 11, pp.
1825–1831, 2010.

[17] Y. Mizumoto, T. Deguchi Sr., and K. W. C. Fong, “Assessment
of facial golden proportions among young Japanese women,”
American Journal of Orthodontics and Dentofacial Orthopedics,
vol. 136, no. 2, pp. 168–174, 2009.

[18] S. R. Marquardt, “Dr. Stephen R. Marquardt on the Golden
Decagon and human facial beauty. Interview by Dr. Gottlieb,”
Journal of Clinical Orthodontics, vol. 36, no. 6, pp. 339–347, 2002.

[19] Y. Jefferson, “Facial beauty—establishing a universal standard,”
International Journal of Orthodontics, vol. 15, no. 1, pp. 9–22,
2004.

[20] W. B. Proffit, Contemporary Orthodontics, The Mosby, London,
UK, 1993.

[21] J. R. Landis and G. G. Koch, “The measurement of observer
agreement for categorical data,” Biometrics, vol. 33, no. 1, pp.
159–174, 1977.

[22] M. Y. Mommaerts and B. A. Moerenhout, “Ideal proportions
in full face front view, contemporary versus antique,” Journal of
Craniomaxillofacial Surgery, vol. 11, no. 2, pp. 10–22, 2010.

[23] M. Bashour, “An objective system for measuring facial attrac-
tiveness,” Plastic and Reconstructive Surgery, vol. 118, no. 3, pp.
757–774, 2006.

[24] V. F. Ferrario, C. Sforza, C. E. Poggio, G. Tartaglia, and L. G.
Farkas, “Facial morphometry of television actresses compared
with normal women,” Journal of Oral and Maxillofacial Surgery,
vol. 53, no. 9, pp. 1008–1015, 1995.

[25] N. A. Mandall, J. F. McCord, A. S. Blinkhorn, H. V. Worthing-
ton, and K. D. O’Brien, “Perceived aesthetic impact of maloc-
clusion and oral self-perceptions in 14-15-year-old Asian and
Caucasian children in Greater Manchester,” European Journal
of Orthodontics, vol. 22, no. 2, pp. 175–183, 2000.

[26] M. Varela and J. E. Garćıa-Camba, “Impact of orthodontics on
the psychologic profile of adult patients: a prospective study,”
American Journal of Orthodontics and Dentofacial Orthopedics,
vol. 108, no. 2, pp. 142–148, 1995.

[27] M. R. Mack, “Vertical dimension: a dynamic concept based on
facial form and oropharyngeal function,” The Journal of Pros-
thetic Dentistry, vol. 66, no. 4, pp. 478–485, 1991.

[28] S. Anic-Milosevic, S. Mestrovic, A. Prlić, and M. Šlaj, “Propor-
tions in the upper lip-lower lip-chin area of the lower face as
determined by photogrammetric method,” Journal of Cranio-
Maxillofacial Surgery, vol. 38, no. 2, pp. 90–95, 2010.

[29] M. Bisson and A. Grobbelaar, “The esthetic properties of lips:
a comparison of models and nonmodels,” Angle Orthodontist,
vol. 74, no. 2, pp. 162–166, 2004.

[30] R. E. Ward, “Facial morphology as determined by anthropom-
etry: keeping it simple,” Journal of Craniofacial Genetics and
Developmental Biology, vol. 9, no. 1, pp. 45–60, 1989.

[31] F. Torsello, L. Mirigliani, R. D’Alessio, and R. Deli, “Do the
neoclassical canons still describe the beauty of faces? An
anthropometric study on 50 Caucasian models,” Progress in
Orthodontics, vol. 11, no. 1, pp. 13–19, 2010.

[32] E. X. McKiernan, F. McKiernan, and M. L. Jones, “Psychological
profiles and motives of adults seeking orthodontic treatment,”
The International Journal of Adult Orthodontics and Orthog-
nathic Surgery, vol. 7, no. 3, pp. 187–198, 1992.

[33] D. Hall, R. W. Taylor, A. Jacobson, P. L. Sadowsky, and A. Bar-
toluccl, “The perception of optimal profile in African Americans
versus white Americans as assessed by orthodontists and the
lay public,” American Journal of Orthodontics and Dentofacial
Orthopedics, vol. 118, no. 5, pp. 514–525, 2000.

[34] G. Perseo, “The “Beauty” of homo sapiens: standard canons,
ethnical, geometrical and morphological facial biotypes. An
explained collection of frontal north-Europide contemporary
beauty facial canons. Part I,” Virtual Journal of Orthodontics, vol.
30, pp. 150–162, 2002.

[35] M. R. Farahvash, J. Khak, M. J. Horestani, Y. Farahvash, and B.
Farahvash, “Facial aesthetic analysis in beautiful persian female
subjects aged 13 to 30 years by means of photogrammetry,”
Plastic and Reconstructive Surgery, vol. 125, no. 6, pp. 245e–247e,
2010.

[36] A. B. Macias Gago, M. R. Maroto et al., “The perception of facial
aesthetics in a young Spanish population,” European Journal of
Orthodontics, vol. 34, no. 3, pp. 335–339, 2012.

[37] N. C. Springer, C. Chang, H. W. Fields et al., “Smile esthet-
ics from the layperson’s perspective,” American Journal of
Orthodontics and Dentofacial Orthopedics, vol. 139, no. 1, pp.
e91–e101, 2011.