RESEARCH Open Access

Survey on joint hypermobility in university
students aged 18–25 years old
Darcisio Hortelan Antonio and Claudia Saad Magalhaes*

Abstract

Background: Joint hypermobility is defined as a wide range of movements beyond the physiological limits, it has
been recognized in healthy people, gymnasts, acrobats, and carriers of genetic affections of connective tissue. A
survey among young adults was conducted to describe the frequency of joint hypermobility, estimating its impact
on function and quality of life.

Methods: Volunteer university students aged 18 to 25 years old who answered a valid 5-item questionnaire about
hypermobility, a physical activity questionnaire, and the Brazilian version of the Medical Outcome Survey Short
Form 36 (SF-36) were included. Hypermobility was also assessed by a guided self-examination, with Beighton’s
criteria being scored and scores greater than or equal to 4 or less than 4 being discriminated.

Results: A total of 388 subjects were included, of which 299 were women (77.06%) and 89 were men (22.94%); the
median age was 23 years old. Generalized joint hypermobility (Beighton score ≥ 4) was observed in 104 individuals
(26.8%). Localized hypermobility (Beighton score 1–3) was observed in 135 (34.79%) individuals, where the
hypermobility of the 5th finger was the most frequent in 165 (57.47%) individuals, followed by hypermobility of the
thumb in 126 (32.56%) individuals, hypermobility of the elbows and knees each in 72 (18.6%) individuals, and
hypermobility of the spine in 69 (17.79%) individuals. The descriptive observation of physical activity indicated
regular practice. The correlation coefficients between the SF-36 domains and hypermobility scores were very low
and statistical comparison not significant.

Conclusion: In this population of youngsters, predominantly women, localized hypermobility was more frequent
than generalized hypermobility; however, with low impact on health domains and quality of life scores, estimated
in each domain of the SF-36, the physical and mental component scores, and the time dedicated to physical
activity.

Keywords: Joint hypermobility, Generalized hypermobility, Localized hypermobility, SF-36 health questionnaire

Background
Hypermobility is defined as the wider range of movements
beyond the limits considered physiological. It has been
recognized as a phenomenon frequently observed in
healthy people, acrobats, gymnasts, and ballerinas [1–5].
Hypermobility is also part of the syndromic presentation
of certain genetic diseases, [6] such as Ehler-Danlos
Syndrome, Marfan Syndrome, Down Syndrome, Osteo-
genesis imperfecta, and Stickler Syndrome, among others.

The concept of benign joint hypermobility, as a
rheumatic condition leading to chronic musculoskeletal
symptoms, emerged in the 1970s with several case series
and population studies identifying the association with
chronic musculoskeletal pain [7, 8] and, more recently,
with dysautonomia and gastrointestinal dysmotility [7–9].
The incidence and prevalence of hypermobility vary

greatly among populations, with marked differences ac-
cording to age, gender, ethnicity, physical activity, or sports
and athletic abilities. Approximately 25–50% of children
younger than 10 years old have some degree of hypermo-
bility [10–17]. There is a higher prevalence in populations
of Asian origin, followed by populations of African and
European origins [10, 12, 14, 15, 17–26]. However,

* Correspondence: claudi@fmb.unesp.br
Pediatrics Department, Botucatu Medical School, Graduate Program in Public
Health of UNESP, Sao Paulo State University UNESP, Avenida Prof. Mario
Rubens Guimarães Montenegro SN, Campus da Unesp, Rubião Junior, CEP,
Botucatu, SP 18618-687, Brazil

Advances in Rheumatology

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comparisons among different populations have been ham-
pered by the use of different criteria and methodologies for
the evaluation of hypermobility.
Most clinicians recognize joint hypermobility in routine

practice and by the use of the range of motion scale as-
sessment proposed by Beighton [20]. The presence or ab-
sence of hypermobility in the joints is categorized,
signaling the flexibility of five areas of the body with ex-
tension beyond the physiological limits. The maneuvers
that make up the Beighton scale represented in Fig. 1 are
1) extension of 5th metacarpal phalangeal joint by placing
the 5th finger parallel to the forearm, 2) extension of the
thumb touching the flexor side of the forearm, 3) exten-
sion greater than 10o beyond the limit of 180o of the
elbow, 4) extension greater than 10o beyond the limit of
180o in the knee, and 5) flexion and elongation of the
spine by placing the hands flat on the floor with the knees
in maximum extension. These maneuvers are individually
scored on each side of the body and spine, to a total of 9
points. Scores greater than or equal to 4 are classified as
generalized joint hypermobility, and scores 1–3 are
classified as localized joint hypermobility [1, 4, 27].
Physiotherapists are trained to identify reduced range

of motion and its clinical repercussions, associating it
with several conditions of inflammatory origin. Greater
ranges of movement are interpreted as variations of the
normality of individual characteristics. Intervention with
physical exercises still does not result in consistent evi-
dence because a systematic review of intervention with
exercises for those with functional repercussions was not
conclusive regarding the effectiveness of the intervention
with exercises or physical activity on hypermobility and
its functional repercussions [28].
A wide spectrum of extra-articular clinical manifesta-

tions has been progressively recognized in association
with musculoskeletal symptoms [29], such as predispos-
ition to ecchymosis, poor wound healing, early onset of
osteoarthritis, valvulopathy, osteoporosis, vesicoureteral
reflux, inguinal hernia, and changes in intestinal motility
[5, 6, 26, 30–33]. There are also other manifestations,
such as fatigue, anxiety, and depression, negatively af-
fecting social function and well-being [34].
The main musculoskeletal manifestation is chronic and

generalized pain [7, 9, 17, 26, 35]. Proprioceptive functions
may also be adversely affected, possibly due to damage to
mechanical connective tissue receptors. Failure to
recognize extreme joint range of movement can lead to
joint instability and traumas to repetitive stress [36–38].
Decreased muscle strength can occur in children with
limb pain and joint hypermobility [39]. There is evidence
that hypermobility syndrome is a multisystemic manifest-
ation, incorporating three main components: chronic pain,
autonomic dysfunction, and dysfunction of gastrointes-
tinal motility [6, 8, 26, 30, 32, 39, 40].

There have been few population studies on the impact
of hypermobility among young adults. The frequencies of
generalized and localized hypermobility have been widely
studied in several populations, including the Brazilian
pediatric population of pre-schoolers and schoolchildren
[10, 14, 21]; however, studies on adolescents and young
adults are scarce in the global literature [11, 16] and have
not been referred to our population.

Objective
To investigate the frequency of joint hypermobility
among university students 18 to 25 years old through
survey and self-examination, estimating its functional
impact and its impact on quality of life through the
Medical Outcome Survey Short Form 36 (SF-36)
questionnaire.

Methods
Volunteers between 18 and 25 years of age from medical
and physiotherapy courses were invited to participate in
this study after the work team provided explanations
about the study.
The project obtained institutional ethics committee

approval (CEP-457/2010) and agreement from the
course councils; the subjects who agreed were included
in the study by signing the Terms of Free and Informed
Consent. The research was conducted in accordance
with the Helsinki Declaration for research on humans
beings.
Participants completed the self-administered question-

naires on hypermobility, including a valid five-item ques-
tionnaire adapted by Moraes et al. [41] and a survey on
multisystemic associations of hypermobility syndrome
[26]. The Brazilian version of the SF-36 [42] was com-
pleted by the subjects, and their records were identified
by alpha-numerical code without personal identification.
The self-examination was observed and recorded in case
report forms by three trained observers, and the data
were transferred to analysis worksheets.
The SF-36 is a widely used measure of health-related

quality of life. The purpose of this questionnaire is to de-
tect clinically and socially relevant differences in the
health conditions of both the general population and in-
dividuals affected by certain diseases, along with any
changes in health status over time through a small num-
ber of statistically efficient dimensions. The SF-36 con-
sists of 36 items in 8 domains: Physical Functioning (CF)
, Role-Physical (RF), Bodily Pain (BP), General Health
(GH), Vitality (VT), Social Functioning (SF), Role-
Emotional (RE), and Mental health (MH), resulting in
two summary components, the Physical Component
(PCo) and the Mental Component (MCo). The score
ranges from 0 to 100 points, where 0 represents the

Antonio and Magalhaes Advances in Rheumatology  (2018) 58:3 Page 2 of 7



worst state of health and 100 the best state of health in
the last 4 weeks.
A single evaluation was performed; there was no gen-

der selection, and participation was voluntary, with con-
secutive inclusion of participants until reaching the
sample size estimated by means of statistical calculation.
The specific musculoskeletal examination, which in-
cludes hypermobility maneuvers, was instructed and
conducted according to the scheme outlined in Fig. 1.
The sample size was calculated considering the preva-

lence of hypermobility in this specific age group as un-
known (p = 0.50), with a reliability of 95% and a margin of
error of 5%. The minimum size calculated for the sample
was 385 subjects, and the maximum was 400 subjects.
The descriptive analysis of the frequency of signs and

symptoms of the joint hypermobility survey and of the
Beighton scale score was performed. Qualitative variables
were described by absolute and percentage frequencies.
Quantitative variables were described by medians and
variation ranges (minimum-maximum) or means and
standard deviations when appropriate. SF-36 scores on
valid questionnaires (< 5% lost data) were calculated using
SAS for Windows software version 9.3.
The frequency of hypermobility was scored individu-

ally by determining the frequency of joints scored and
compared by gender. The comparison of hypermobility
areas in men and women was performed using Student’s t
test (two categories). The categorization of generalized hy-
permobility by means of the limit of 4 or more joints scored
using the Beighton criteria was also estimated according to
the frequencies and possible associations explored.

The association tests between the hypermobility pa-
rameters and the SF-36 domain scores with the respect-
ive summary scores were performed using the Pearson
Correlation Test. The association is represented by the
Pearson r, and the significance is expressed by the values
of p < 0.05. Correlations < 0.4 were considered weak
or with no association, those between 0.4 and 0.7 were
considered moderate, and those > 0.7 were considered
strong.

Results
The participants of the research were volunteers who
agreed to participate in the study through signing the
Terms of Informed Consent. There was no refusal to
participate. The sample consisted of 388 subjects, of
which 28 were from the Medicine course and 360 were
from the Physiotherapy course. The evaluation period
was from February 2013 to April 2014.
A total of 388 subjects were recruited, including 299

women (77%) and 89 men (23%), with a minimum age of
18 years and a maximum age of 25 years (median 23), with
the following anthropometric characteristics: mean weight
(64.5 ± 15.7), median weight 60 kg, mean height (1.66 ± 0.
09), and median height 1.65 m. The mean body mass index
(BMI) was (23 ± 4), and the median BMI was 22.
The self-evaluation of physical activity, by means of esti-

mating the number of hours per week of practice of leisure
activities, sports, and competitions, was compiled. The de-
scriptive analysis was as follows: 165 declared a mean leis-
ure activity practice time of (1.7 ± 2.9) hours/week; 124
subjects declared a mean sports practice time of (1.6 ± 3.2)

Fig. 1 Percentage frequencies of unilateral or bilateral signs of hypermobility identified through 5 maneuvers in the Beighton scale: 1) extension
of the 5th metacarpal phalangeal joint by placing the 5th finger parallel to the forearm, 2) extension of the thumb touching the flexor side of the
forearm, 3) extension greater than 10o beyond the limit of 180o of the elbow, 4) extension greater than 10o beyond the limit of 180o in the knee,
and 5) flexion and elongation of the spine by placing the hands flat on the floor with knees in maximum extension

Antonio and Magalhaes Advances in Rheumatology  (2018) 58:3 Page 3 of 7



hours/week, and 23 subjects declared a mean competition
practice time of (0.2 ± 1.2) hours/week.
The responses to the 5-item hypermobility question-

naire, estimating the presence or absence of joint hyper-
mobility, are presented in Table 1. Among the most
scored items, the highest was the spine (48.2%).
The survey on musculoskeletal and extra-articular or

systemic complaints associated with joint hypermobility
and their respective frequencies is presented in Table 2.
The most frequently reported problem was low back
pain, present in 176 (45.4%) of the subjects.
The classification of hypermobility was established

using the instructed self-examination recorded by three
trained observers, using the criteria of Beighton [20],
with a limit of 4 or more joints (≥ 4) to determine gener-
alized hypermobility and a 3-joint limit (≥ 1 and ≤ 3) for
localized hypermobility [43].
Generalized joint hypermobility was observed in 104

(26.8%) individuals. The frequency of generalized joint
hypermobility in women was 27.8%, and that of the male

population was 23.6%. The locations of the hypermobility
signs and their respective frequencies and distributions are
shown in Fig. 1, with the paired signs being independently
and bilaterally scored in the majority.
The 5th finger hypermobility sign was the most fre-

quent, being described in 165 (42.52%) individuals,
followed by the thumb in 126 (32.56%) individuals, elbows
and knees in 72 subjects each (18.6%), and spine in 69 (17.
79%) individuals. There were no statistically significant
differences in gender for any of the signs (Table 3).
In the SF-36 questionnaire, the results were compar-

able with the normative data in adults of the Brazilian
population. No significant differences were observed in
the results of each domain and in the physical and men-
tal indices among those with generalized hypermobility,
localized hypermobility, or absence of hypermobility
(Table 4).
The following correlations were found between each

SF-36 domain and the generalized hypermobility condi-
tion (score ≥ 4): Vitality (VT) r = − 0.05284, p = 0.2991;
Mental Health (MH) r = − 0.10007, p = 0.05; Physical
Functioning (PF) r = − 0.04907, p = 0.3350; Role-Physical
(RP) r = − 0.03178, p = 0.5325; Bodily Pain r = 0.07304,
p = 0.1510; General Health (GH) r = − 0.11050, p = 0.03;
Role-Emotional (RE) r = − 0.02224, p = 0.6623; Social
Functioning (SF) r = − 0.05410, p = 0.2878; Physical
Component (PCo) r = − 0.06839, p = 0.1789; and
Mental Component (MCo) r = − 0.02491, p = 0.6248.
All correlations were weak (0.1 to 0.3), although they
were significant for Mental Health and General

Table 2 Frequencies of valid responses in the inquiry of signs
and symptoms, musculoskeletal and systemic, related to joint
hypermobility

Signs and symptoms Yes No

Contortionist tricks 54 (15%) 328 (85%)

Ankle sprain 118 (32%) 255 (68%)

Other ligament injuries 55 (15%) 309 (85%)

Arthralgia 122 (33%) 252 (67%)

Arthritis 18 (5%) 356 (95%)

Frequent cramps 143 (37%) 243 (63%)

Pain in the knees 102 (27%) 278 (73%)

Cervical pain 107 (28%) 270 (72%)

Dorsal pains 111 (29%) 268 (71%)

Lower back pain 176 (46%) 206 (54%)

Shoulder dislocations 29 (8%) 355 (92%)

Patella dislocations 16 (4%) 362 (96%)

Poor wound healing 28 (7%) 351 (93%)

Fractures 79 (20%) 304 (80%)

Table 1 Frequencies of responses on hypermobility, described in a 5-item questionnaire for joint hypermobility [41]

Yes No Do not know

1. Can you or have you managed to get your hands placed flat on the floor
without bending your knees?

187 (48.2%) 188 (48.4%) 13 (3.4%)

2. Can you or have you been able to turn your thumb until it touches your forearm? 101 (26%) 278 (71.7%) 9 (2.3%)

3. When you were a kid, did you amuse your friends by twisting your body in strange
positions OR did you open your legs completely?

153 (39.4%) 229 (59%) 6 (1.6%)

4. As a child or teenager have you dislocated your shoulder or patella more than once? 29 (7.5%) 348 (89.7%) 11 (2.8%)

5. Do you consider your joints supple? Do you think your joints bend as much as those
of a contortionist?

31 (8%) 337 (86.9%) 20 (5.1%)

Table 3 Comparison of the frequencies of joint hypermobility
signs scored in the Beighton Scale according to gender
(Student’s t-test)

Sign Manouver Men Women Total p

1) 5th Finger 32/89 (35.95%) 133/299 (44.48%) 165 (42.52%) NS*

2) Thumb 24/89 (26.96%) 102/299 (34.11%) 126 (32.56%) NS*

3) Elbow 9/89 (10.11%) 63/299 (21.07%) 72 (18.6%) NS*

4) Knee 11/89 (12.35%) 61/299 (20.40%) 72 (18.6%) NS*

5) Spine 14/89 (15.73%) 55/299 (18.39%) 69 (17.79%) NS*

*NS - not significant

Antonio and Magalhaes Advances in Rheumatology  (2018) 58:3 Page 4 of 7



Health. There was no association between the SF-36
score and hypermobility, indicating a minimal impact
on the health, physical, and psychosocial aspects of
volunteers.

Discussion
The primary objective was to estimate the frequency of hy-
permobility among young university students and the pos-
sible repercussions on their health condition as evaluated
using objective methods. Women were predominantly in-
cluded in an unselected population, as students of both
genders were invited. We found a frequency of 27% gener-
alized joint hypermobility and an interesting result of 35%
localized hypermobility. Localized signs of hypermobility
predominated on the hands and secondarily on the elbows,
knees, and spine. The selection of volunteers in medical
and physiotherapy schools was aimed at achieving a homo-
geneous sample of the healthy population with regular
physical activity.
The frequency of generalized hypermobility found in

our study in young people was similar to that of English
adolescents reported by Clinch et al. 2011 [16] using the
same threshold of more than 4 points in the Beighton scale
found in the cohort up to 14 years old, with proportions of
27.5% in girls and 10.6% in boys. Accordingly, 45% of the
girls had finger hypermobility compared with 29% of boys
with finger hypermobility. These authors also did not de-
scribe any associations between hypermobility and physical
activity, body mass index, or maternal education level.
A recent study among Korean girls and women [44]

described the presence of generalized hypermobility in
50% of respondents, 59% in girls and 36.5% in adult
women, with the number of signs inversely proportional
to age. Significant differences of localized hypermobility
in the thumb and 5th finger were found in both groups.
The lower frequency of hypermobility according to age

occurred symmetrically on both thumbs but it was more
pronounced in the fifth finger of the dominant hand,
more often on the right hand.
Based on anthropometric data including weight,

height, and body mass index, overweight was occasional,
and physical activity was relatively regular, with a higher
proportion of patients with localized hypermobility, es-
pecially in the hands. Population studies are described in
the pediatric literature, but data on their frequency, ef-
fects, and consequences in the young adult population
have been infrequent. Musculoskeletal pain is a sign often
related to hypermobility and obesity; sedentary lifestyle
may play a relevant role [45, 46], as there is a two-fold in-
creased risk in adolescents with hypermobility.
Although the Bodily Pain domain had minimum im-

pact or correlation with hypermobility in the SF-36 in-
vestigation, the frequency of musculoskeletal pain was
relevant, mainly due to the proportions of low back pain,
frequent cramps, arthralgia, and sprains. Long-term
studies on sequelae, including the risk of osteoarthritis,
are still inconclusive. Conditions such as tendinitis, bur-
sitis, fasciitis, and fibromyalgia correspond to 25% of re-
ferrals to rheumatologists. The association with
generalized and localized joint hypermobility, repetitive
strain activities, and pain in areas of localized hyper-
mobility [47], has been explored in professional artis-
tic activities such as ballet, gymnastics, and acrobatics
[48, 49], predisposing to pain and injury due to asso-
ciated mechanical trauma,.
In a Brazilian study, the prevalence of hypermobility in

academic ballet activity was 58%, with a higher fre-
quency among teachers compared with students [49]. It
is also interesting to observe the performance of flute
players, who have particularly greater range of motion in
the hands, and even finger hypermobility, presenting
more accurate proprioception through training, which is

Table 4 Comparison of the SF-36 scores in the total sample of volunteers, without hypermobility (Beighton score = 0) or with localized
hypermobility (1–3) and generalized hypermobility (≥ 4)

Variable n Total Sample Median N (%) Localized hypermobility (1–3)
Without hypermobility (0)

Median N (%) Generalized
hypermobility (≥ 4)

Median

PF 388 88.2 ± 12.4 90 284 (73.2%) 88.3 ± 12.7 90 104 (26.8%) 87.7 ± 11.5 90

RP 388 72.4 ± 31 75 284 (73.2%) 73.9 ± 30 75 104 (26.8%) 68 ± 33.3 75

BP 388 51.7 ± 8.1 50 284 (73.2%) 51.3 ± 8.5 50 104 (26.8%) 52.6 ± 7 50

GH 388 60.8 ± 15.5 65 284 (73.2%) 61.7 ± 15.3 65 104 (26.8%) 58.4 ± 15.8 60

VT 388 54.8 ± 19.7 57.5 284 (73.2%) 55.4 ± 19.3 60 104 (26.8%) 53.1 ± 20.7 55

SF 388 64 ± 11.5 65.1 284 (73.2%) 64.4 ± 11.5 65 104 (26.8%) 62.8 ± 11.3 64.8

RE 388 67.2 ± 38.2 100 284 (73.2%) 67.5 ± 37.7 100 104 (26.8%) 66.4 ± 39.6 100

MH 388 65 ± 19.4 68 284 (73.2%) 66 ± 19.7 68 104 (26.8%) 62 ± 18.3 64

PCo 388 65.5 ± 11 67 284 (73.2%) 66.1 ± 10.9 67.5 104 (26.8%) 64 ± 11 65.5

MCo 388 61.3 ± 16.3 64.2 284 73.2% 61.6 ± 16.2 64.6 104 26.8% 60.7 ± 16.6 61.7

Physical Functioning (PF), Role-Physical (RP), Bodily Pain (BP), General Health (GH), Vitality (VT), Social Functioning (SF), Role-Emotional (RE), and Mental Health
(MH); Physical Component (PCo), and Mental Component (MCo)

Antonio and Magalhaes Advances in Rheumatology  (2018) 58:3 Page 5 of 7



an ideal model to study the interaction between localized
flexibility and joint proprioception [50].
Questions about the practice of music or dance activ-

ities were not part of our inquiry; we questioned only
the number of hours practicing leisure physical activities
and sports activities. The options for the Beighton cri-
teria may have some criticism due to variability and di-
vergence in the cutoff scores. The higher scores, such as
≥4, ≥ 5, ≥ 6, and ≥ 7 hipermobile joints could also be
considered; however, the score ≥ 4 was the most widely
reported in the literature as the most frequent cutoff
point [1, 2, 11–13, 17, 20, 21, 39, 49, 50].
For the diagnosis of generalized joint hypermobility in

children and adolescents, at least 5 of the 9 criteria on the
Beighton scale are recommended; the difference between
the conditions of generalized joint hypermobility and joint
hypermobility syndrome is the presence of symptoms. As-
sociated symptoms including predominant musculoskel-
etal conditions, such as joint pain and instability [26], are
more frequently observed in adults and are possibly re-
lated to mechanical impact or repeated strain activity.
However, dysfunctional gastrointestinal manifestations

[32, 40], such as constipation, vesicoureteral reflux [3], or
inguinal hernia [31], are more frequently described in
pediatric age. Our survey was limited in the approach of
other systems involved. Among the systemic manifesta-
tions, poor wounds healing, which had a low frequency of
responses, was questioned. In the recall survey about pain
in the lumbar spine region and arthralgia, these complaints
were the most frequent, involving 319 reports in total, but
without repercussions on quality of life and health status.
Our data are consistent with Ruperto et al. 2004 [25],
who used the CHQ-PF 50 questionnaire among healthy
schoolchildren with hypermobility and also did not
identify repercussions in their physical and psychosocial
components.
Musculoskeletal pain can be triggered by physical activity

in the absence of adequate physical conditioning, intense
physical exercise, an accident, or a traumatic event or may
develop without any apparent reason; its association with
hypermobility mmay be of mere chance. There are also as-
sociations of chronic pain with fatigue, dysautonomia, and
negative impacts on quality of life scores due to anxiety and
depression [28], which require intervention. However, these
associations have been reported in samples of symptomatic
hypermobile individuals who seek clinical treatment, com-
prising approximately 1% of men and 5% of women.
More comprehensive population studies including

healthy individuals are still needed to estimate the magni-
tude of the problem and the generalization of our results.

Conclusion
In conclusion this young population sample with a pre-
dominance of women, localized hypermobility was more

frequent than generalized hypermobility; however, there
was minimum impact on either health or quality of life.

Acknowledgments
Darcisio Hortelan Antonio attended the Public Health Graduate Course, Sao
Paulo State University (Universidade Estadual Paulista - UNESP), accredited by
the Brazilian Federal Agency for the Support and Evaluation of Graduate
Education (CAPES). Claudia Saad Magalhães MD, graduate mentor was
funded by CNPq Scholarship (301644-2010, 301479/2015). The students
Fabricio Lopes Stafussi, Juliana de Freitas, and Susan Nawaly collaborated in
the data collection and Prof. José Eduardo Corrente (UNESP) perfomed the
statistical analysis.

Availability of data and materials
The original data basis that generated the work is filed by the first Author
Darcisio Hortelan Antonio.

Authors’ contributions
Both authors contributed equally to the paper development. It was
developed as master’s thesis under the Public Health Graduate
Programme at UNESP.

Authors’ information
No other than the above disclosure and acknowledgement.

Ethics approval and consent to participate
The project obtained institutional ethics committee approval (CEP-457/2010)
and agreement from the undergraduate course councils of the Medical
School and Physiotherapy School; the subjects who agreed were included in
the study by signing the Terms of Free and Informed Consent. The research
was conducted in accordance with the Helsinki Declaration for research on
humans beings.

Competing interests
There is no other competing interest than the academic research.

Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in
published maps and institutional affiliations.

Received: 26 March 2018 Accepted: 19 April 2018

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	Abstract
	Background
	Methods
	Results
	Conclusion

	Background
	Objective

	Methods
	Results
	Discussion
	Conclusion
	Availability of data and materials
	Authors’ contributions
	Authors’ information
	Ethics approval and consent to participate
	Competing interests
	Publisher’s Note
	References