International  Journal  of

Environmental Research

and Public Health

Article

Correlation between Neck Circumference and Other
Anthropometric Measurements in Eight Latin American
Countries. Results from ELANS Study

Reyna Liria-Domínguez 1,2,* , Marcela Pérez-Albela 2, María-Paz Vásquez 2, Georgina Gómez 3 ,
Irina Kovalskys 4 , Mauro Fisberg 5,6 , Lilia Yadira Cortés 7 , Martha Cecilia Yépez García 8 ,
Marianella Herrera-Cuenca 9, Attilio Rigotti 10, Gerson Ferrari 11 , Rossina G. Pareja 1

and on behalf of the ELANS Study Group †

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Citation: Liria-Domínguez, R.;

Pérez-Albela, M.; Vásquez, M.-P.;

Gómez, G.; Kovalskys, I.; Fisberg, M.;

Cortés, L.Y.; Yépez García, M.C.;

Herrera-Cuenca, M.; Rigotti, A.; et al.

Correlation between Neck

Circumference and Other

Anthropometric Measurements in

Eight Latin American Countries.

Results from ELANS Study. Int. J.

Environ. Res. Public Health 2021, 18,

11975. https://doi.org/10.3390/

ijerph182211975

Received: 1 October 2021

Accepted: 9 November 2021

Published: 15 November 2021

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1 Instituto de Investigación Nutricional, Lima 15026, Peru; rpareja@iin.sld.pe
2 Facultad de Ciencias de la Salud, Carrera de Nutrición y Dietética, Universidad Peruana de Ciencias

Aplicadas-UPC, Lima 15067, Peru; marcela.par31@gmail.com (M.P.-A.); mariapazvp07@gmail.com (M.-P.V.)
3 Departamento de Bioquímica, Escuela de Medicina, Universidad de Costa Rica,

San José 11501-2060, Costa Rica; georgina.gomez@ucr.ac.cr
4 Carrera de Nutrición, Facultad de Ciencias Médicas, Pontificia Universidad Católica Argentina,

Buenos Aires C1107 AAZ, Argentina; ikovalskys@gmail.com
5 Centro de Excelencia em Nutrição e Dificuldades Alimentaes (CENDA), Instituto Pensi, Fundação José Luiz

Egydio Setubal, Hospital Infantil Sabará, São Paulo 01228-200, Brazil; mauro.fisberg@gmail.com
6 Departamento de Pediatria, Universidade Federal de São Paulo, São Paulo 04023-061, Brazil
7 Departamento de Nutrición y Bioquímica, Pontificia Universidad Javeriana, Bogotá 110231, Colombia;

ycortes@javeriana.edu.co
8 Colegio de Ciencias de la Salud, Universidad San Francisco de Quito, Quito 17-1200-841, Ecuador;

myepez@usfq.edu.ec
9 Centro de Estudios del Desarrollo, Universidad Central de Venezuela (CENDES-UCV)/Fundación Bengoa,

Caracas 1053, Venezuela; manyma@gmail.com
10 Centro de Nutrición Molecular y Enfermedades Crónicas, Departamento de Nutrición, Diabetes y

Metabolismo, Escuela de Medicina, Pontificia Universidad Católica, Santiago 8330024, Chile;
arigotti@med.puc.cl

11 Escuela de Ciencias de la Actividad Física, el Deporte y la Salud, Universidad de Santiago de Chile (USACH),
Santiago 7500618, Chile; gerson.demoraes@usach.cl

* Correspondence: rliria@iin.sld.pe or pcnumlir@upc.edu.pe
† Membership of the ELANS Study Group is provided in the Acknowledgments.

Abstract: Neck circumference (NC) is being used to identify the risk of chronic diseases. There is a
high prevalence of overweight and obesity in Latin America, and neck circumference is a simple and
practical measurement to assess this, especially in primary health centers. We analyzed the correlation
between the NC anthropometric indicator and other anthropometric measurements such as BMI and
waist circumference (WC) in eight Latin American cities. We applied Pearson’s correlation to identify
the correlate NC with the other anthropometric variables stratified by sex; the sensitivity (Se) and
specificity (Sp) by sex were evaluated according to the cut-off established with the Youden Index.
The strongest correlations between NC and WC were found when stratified by sex (women: r = 0.71;
men: r = 0.69, respectively) followed by the correlation between NC and BMI (r = 0.65, both sex). NC
cut-off points of 39.0 cm in men and 32.9 cm in women identified those individuals with an increased
WC and 39.8 and 33.7 cm, respectively, for a substantial increase in WC. For BMI ≥ 25.0 kg/m2 for
men, the cut-off point was 37.5 cm, and for women, it was 33.1 cm, and for BMI ≥ 30 kg/m2, the
cut-off points were 39.2 and 34.2 cm, for men and women, respectively. Conclusion: NC proved
to be a useful, practical, and inexpensive tool that can be used to identify, evaluate, and monitor
overweight and obese individuals.

Keywords: waist circumference; body mass index; neck circumference; obesity; overweight

Int. J. Environ. Res. Public Health 2021, 18, 11975. https://doi.org/10.3390/ijerph182211975 https://www.mdpi.com/journal/ijerph

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Int. J. Environ. Res. Public Health 2021, 18, 11975 2 of 12

1. Introduction

Excessive fat accumulation in the body is detrimental to health, as it is associated with
different diseases such as type 2 diabetes mellitus, hypertension, and an increased risk of
cardiovascular disease [1,2].

There are different methods or indicators to measure excess fat. Among the most com-
mon are body mass index (BMI), waist circumference (WC), waist/hip ratio, waist/height,
and skinfolds. BMI is the simplest and best-known method of all. However, it has limita-
tions, since it does not measure body fat or its location, nor can it differentiate between fat
and lean tissue, resulting, for example, in a diagnosis of overweight or obesity in people
with a high percentage of muscle mass [3]. Another important and commonly used marker
is WC, which is widely used to determine the accumulation of abdominal fat [4,5]. WC is
more specific than BMI for the determination of metabolic risk, as it distinguishes body fat,
specifically visceral fat located at the abdominal level, from lean mass [4,6,7]. However,
in the case of WC, the population, especially women, may feel discomfort when being
measured and may be affected by the time of day when it is measured [8].

Fat can accumulate in different areas of the body, and the location can affect the degree
of risk of illness. Fat accumulated in the upper part of the body (e.g., neck fat) can be
related to a higher risk than fat accumulated in the abdomen [9]. This can be because fat
accumulated in the neck is located in a separated compartment, in contrast to abdominal
fat, which is divided into subcutaneous and intra-abdominal deposits [10]. Moreover, neck
circumference (NC) has been shown to be correlated with risk factors independently of
BMI and WC [9]. It has been associated with the components of metabolic syndrome such
as elevated blood pressure, hypertriglyceridemia, hypercholesterolemia, elevated fasting
glucose, insulin resistance [9], and obstructive sleep apnea [10,11].

NC could be a good indicator of cardiovascular risk, and may be an alternative
tool, specifically for the measurement of upper subcutaneous fat. It is an anthropometric
measurement characterized by its simplicity and practicality and it is not affected by the
time of day when it is measured [12]. WC, however, is sensitive to abdominal distension
and can be affected by gas exchange on inhalation and exhalation [13]. BMI is a universal
measure practiced by health personal, but it does not reflect the body fat composition [14].

Latin America has high rates of excess weight and chronic diseases that require atten-
tion, especially in urban areas. First-level health facilities tend to have a high demand for
work, and a simple and practical measure to carry out can help identify populations at
risk of metabolic diseases. Our interest was to evaluate if there is a correlation between
NC with BMI and WC in a Latin American population living in urban areas and to estab-
lish cut-off points where NC reaches the highest sensitivity and specificity to determine
overweight and obesity. This measure could be used in different epidemiological studies
or in the clinical area as a reliable, simple, fast, low-cost, and less invasive way than other
anthropometric measurements, especially those involving skinfold and WC measurements.

2. Materials and Methods
2.1. Study Design

This was a secondary analytical study using information from the ELANS database.
The ELANS study is a cross-sectional, multicenter nutritional and health study (2014–2015),
conducted in urban populations from eight Latin American countries (Argentina, Brazil,
Chile, Colombia, Costa Rica, Ecuador, Peru, and Venezuela) [15].

2.2. Population

We included people aged 15 to 65 years from more populated urban areas and ex-
cluded pregnant and lactating women (in the first 6 months postpartum), people with
physical disabilities that may affect food intake and/or physical activity, people living in a
residential setting other than a home (hospitals, regiments, and nursing homes), and those
who cannot read. In our study, we mainly excluded people with incomplete information
for the variables of interest.



Int. J. Environ. Res. Public Health 2021, 18, 11975 3 of 12

2.3. Study Sample and Sampling

This study included the data analysis of 9218 participants. The Epidat program was
used to calculate the statistical power. Considering a correlation coefficient of 0.50 and a
confidence level of 95%, the sampling design was complex and multistage stratified by
sex, age, and socioeconomic status. Details of the sampling are presented in the study
publication [15].

2.4. Data Collection Procedure

Sociodemographic: A questionnaire was used to collect information on demographic
data: age, sex, years of education, and marital status. In addition, socioeconomic status was
also assessed by means of a questionnaire and classified into three strata (high, medium,
and low) according to the national indexes used in each country [15].

Anthropometry: All subjects were weighted and measured with the least possible
clothing. Measurements were taken in the following order: weight, height, WC, and
NC. All measurements were made according to WHO [16] and ISAK (WC and NC) stan-
dards [17]. For weight, a Seca Model 813 electronic scale was used, previously calibrated,
with a capacity of up to 200 kg and an accuracy of 0.1 kg. The participant was asked
to step on the scale with the least clothing possible. To measure height, a Seca Model
213 portable stadiometer was used, with a capacity of 205 cm and an accuracy of 0.1 cm.
For circumference measurements, a Seca Model 201 retractable measuring tape was used,
with a capacity of 205 cm and an accuracy of 0.1 cm. The interviewers were trained by
certified nutritionists to collect all measurements. Each measurement was repeated twice to
ensure accuracy, and the average between the first and second measurement was taken. If
the two readings differed by more than the previously established point (0.1 kg for weight,
0.5 cm for height, 0.5 cm for neck circumferences, and 1 cm for waist circumferences), a
third measurement was taken. All three measurements were recorded, and the extreme
value was excluded during data processing.

2.5. Data Management and Analysis Plan

NC was correlated with WC and BMI. In addition, we considered other variables of
interest including age, socioeconomic status, educational level, region, department, and
marital status. The numerical variables are presented with mean and standard deviation
and the categorical variables as frequency and percentage. An ANOVA or t-test was used
to evaluate differences between the mean of the anthropometric measurements by the
variables of interest. The correlation between NC and other anthropometric measurements
(BMI and WC) was evaluated with Pearson’s correlation coefficient. The following levels
were used to assess the strength of correlation: insignificant (0.00–0.10), weak (0.10–0.39),
moderate (0.40–0.69), strong (0.70–0.89), and very strong (0.90–1.00). ROC curves were
used to evaluate the area under the curve (AUC) and the sensitivity (Se) and specificity
(Sp) by sex according to the cut-off point established with the Youden Index, and thus
evaluate NC as an indicator for an overweight or obesity in an individual according to BMI
(overweight > 25, obese > 30) and WC (overweight: women > 80 cm; men > 95 cm; obese:
men > 102; women > 88 cm). All analyses were performed with a significance level of 5%.
The Stata SE v.16.1 program was used.

3. Results
3.1. General Characteristics of the Population

Table 1 shows the general characteristics of the population. Slightly more than half of
the total population studied were women (52.2%), 37.7% were between 20 and 34 years of
age; most were between middle and low socioeconomic status (42.8% and 41.8%, respec-
tively), 61.2% had basic education, and most were married/cohabiting or single (47.7%
and 42.4%, respectively). In most countries, the same trend was observed for all variables,
except for educational level, where Peru shows a larger population with higher education.



Int. J. Environ. Res. Public Health 2021, 18, 11975 4 of 12

Table 1. Sociodemographic characteristics of the Latin American population. Latin American Health and Nutrition
Study/Estudio Latino Americano de Nutrición y Salud (ELANS).

Variables Argentina Brazil Chile Peru Colombia Costa Rica Ecuador Venezuela Total

n = 1266 n = 2000 n = 879 n = 1113 n = 1230 n = 798 n = 800 n = 1132 n = 9218

n (%)

Sex

Women 573 (54.7) 942 (52.9) 425 (51.7) 523 (53.0) 603 (51.0) 394 (50.6) 397 (50.4) 552 (51.2) 4409 (52.2)
Men 693 (45.3) 1058 (47.1) 454 (48.4) 590 (47.0) 627 (49.0) 404 (49.4) 403 (49.6) 580 (48.8) 4809 (47.8)

Age (years)

15–19 152 (12.0) 235 (11.8) 118 (13.4) 165 (14.8) 148 (12.0) 121 (15.2) 128 (16.0) 156 (13.8) 1223 (13.3)
20–34 446 (35.2) 745 (37.3) 307 (34.9) 460 (41.3) 445 (36.2) 301 (37.7) 316 (39.5) 459 (40.6) 3479 (37.7)
35–49 379 (29.9) 608 (30.4) 252 (28.7) 294 (26.4) 335 (27.2) 224 (28.1) 222 (27.8) 313 (27.7) 2627 (28.5)
50–65 289 (22.8) 412 (20.6) 202 (23.0) 194 (17.4) 302 (24.6) 152 (19.1) 134 (16.8) 204 (18.0) 1889 (20.5)

Socioeconomic status

High 65 (5.1) 705 (35.3) 80 (9.1) 225 (20.2) 67 (5.5) 108 (13.5) 104 (13.0) 62 (5.5) 1416 (15.4)
Medium 585 (46.2) 1034 (51.7) 388 (44.1) 355 (31.9) 384 (31.2) 428 (53.6) 582 (72.8) 190 (16.8) 3946 (42.8)

Low 616 (48.7) 261 (13.1) 411 (46.8) 533 (47.9) 779 (63.3) 262 (32.8) 114 (14.3) 880 (77.7) 3856 (41.8)

Education level
Primary school 955 (75.4) 968 (48.4) 572 (65.1) 257 (23.1) 799 (65.0) 651 (81.6) 664 (83.0) 777 (68.6) 5643 (61.2)

High school 257 (20.3) 864 (43.2) 208 (23.7) 747 (67.1) 294(23.9) 101 (12.7) 84 (10.5) 142 (12.5) 2697 (29.3)
Undergraduate or

higher 54 (4.3) 168 (8.4) 99 (11.3) 109 (9.8) 137 (11.1) 46 (5.8) 52 (6.5) 213 (18.8) 878 (9.5)

Marital status
Single 441 (34.8) 852 (42.6) 398 (45.3) 443 (39.8) 570 (46.3) 359 (45.0) 315 (39.4) 534 (47.2) 3912 (42.4)

Marriage 634 (50.1) 929 (46.5) 406 (46.2) 587 (52.7) 562 (45.7) 368 (46.1) 414 (51.8) 493 (43.6) 4393 (47.7)
Separated,

divorced, widowed 191 (15.1) 219 (11.0) 75 (8.5) 83 (7.5) 98 (8.0) 71 (8.9) 71 (8.9) 105 (9.3) 913 (9.9)

3.2. Bivariate Analysis

Table 2 shows the bivariate and stratified analysis of mean NC, WC, and BMI. The
means (SD) for NC, WC, and BMI were 35.6 (4.1), 88.3 (14.3), and 26.9 (5.6), respectively.
For NC and WC, the measurements were higher in men (NC: 37.7 (0.1), WC: 89.2 (14.2))
than in women (NC: 33.7 (0.2); WC: 87.4 (14.4); p < 0.001). BMI was higher in women than
in men ((27.5 (5.9), 26.3 (5.2); respectively, <0.001). As age increased, NC, WC, and BMI
increased (p < 0.001). Although we found no difference by socioeconomic status in the
total population for any of the measurements (NC, WC, and BMI), we observed that, in
men, the WC and BMI decreased as the socioeconomic status increased but, in women,
these measurements decreased. In almost all the categories of the variables evaluated,
differences by sex were observed, except among the measurements of WC for those with
low socioeconomic status, basic education, and BMI in the high school level and university
or higher education.

Table 2. Bivariate analysis for the total population and by sex between anthropometric measurements and variables of
interest. Latin American Health and Nutrition Study/Estudio Latino Americano de Nutrición y Salud (ELANS).

NC (Mean (SD)) WC (Mean (SD)) BMI (Mean (SD))

Total p + Male Female p ++ Total p + Male Female p ++ Total p + Male Female p ++

Total 35.6
(4.1)

37.7
(0.1)

33.7
(0.0) <0.001 88.3

(14.3)
89.2
(14.2)

87.4
(14.4) <0.001 26.9

(5.6)
26.3
(5.2)

27.5
(5.9) <0.001

Country <0.001 <0.001 <0.001

Argentina 35.6
(4.0)

37.7
(0.2)

33.8
(0.1) <0.001 88.5

(15.5)
90.2
(15.1)

87.1
(15.7) <0.001 27.1

(6.0)
26.7
(5.4)

27.4
(6.4) 0.042

Brazil 34.8
(4.6)

36.8
(0.1)

32.9
(0.1) <0.001 87.6

(14.7)
88.4
(14.6)

86.8
(14.8) 0.021 26.7

(5.7)
26.1
(5.4)

27.3
(5.9) <0.001

Chile 37.3
(3.9)

39.5
(0.2)

35.2
(0.2) <0.001 92.1

(14.3)
93.9
(13.4)

90.4
(14.9) <0.001 28.1

(5.5)
27.6
(4.8)

28.5
(5.9) 0.009

Peru 35.4
(3.6)

37.5
(0.1)

33.5
(0.1) <0.001 87.3

(12.3)
88.0
(12.4)

86.7
(12.1) 0.081 26.6

(4.9)
26.0
(4.7)

27.3
(5.1) <0.001



Int. J. Environ. Res. Public Health 2021, 18, 11975 5 of 12

Table 2. Cont.

NC (Mean (SD)) WC (Mean (SD)) BMI (Mean (SD))

Total p + Male Female p ++ Total p + Male Female p ++ Total p + Male Female p ++

Colombia 35.2
(3.5)

37.2
(0.1)

33.3
(0.1) <0.001 85.0

(13.1)
86.3
(13.1)

83.7
(13.0) <0.001 25.7

(5.0)
25.0
(4.7)

26.4
(5.3) <0.001

Costa Rica 36.7
(3.9)

38.6
(0.2)

34.7
(0.2) <0.001 91.9

(15.4)
91.9
(16.0)

91.9
(14.8) 0.978 27.6

(6.2)
26.6
(5.6)

28.7
(6.6) <0.001

Ecuador 35.1
(3.7)

36.8
(0.2)

33.4
(0.2) <0.001 87.4

(12.3)
87.3
(12.0)

87.5
(12.7) 0.794 26.8

(5.4)
25.7
(5.0)

27.8
(5.6) <0.001

Venezuela 36.2
(4.2)

38.2
(0.2)

34.3
(0.1) <0.001 88.8

(14.6)
90.0
(14.3)

87.7
(14.8) 0.010 27.3

(5.8)
26.9
(5.4)

27.6
(6.1) 0.031

Age (years) <0.001 <0.001 <0.001

15–19 33.8
(3.5)

35.2
(3.3)

32.0
(2.9) <0.001 77.0

(11.4)
77.6
(11.1)

76.2
(11.6) 0.026 22.9

(4.5)
22.6
(4.2)

23.4
(4.9) 0.002

20–34 35.3
(3.9)

37.4
(3.5)

33.2
(3.1) <0.001 85.6

(13.1)
87.3
(13.0)

83.9
(12.9) <0.001 26.1

(5.2)
25.9
(5.0)

26.3
(5.4) 0.017

35–49 36.4
(4.2)

38.7
(3.9)

34.4
(3.4) <0.001 92.3

(13.7)
93.9
(13.5)

90.8
(13.8) <0.001 28.4

(5.6)
27.8
(5.2)

29.0
(5.9) <0.001

50–65 36.4
(4.0)

38.7
(3.6)

34.7
(3.4) <0.001 94.9

(13.3)
96.1
(12.6)

94.0
(13.8) <0.001 28.8

(5.4)
27.8
(4.8)

29.5
(5.7) <0.001

Socioeconomic status 0.269 0.280 0.579

High 35.7
(4.2)

37.6
(4.0)

33.8
(3.5) <0.001 88.7

(14.2)
90.6
(14.1)

86.6
(14.1) <0.001 27.1

(5.5)
26.8
(5.4)

27.3
(5.7) 0.161

Medium 35.5
(4.2)

37.7
(3.8)

33.5
(3.4) <0.001 88.4

(14.2)
89.6
(14.4)

87.2
(13.9) <0.001 26.9

(5.5)
26.3
(5.2)

27.4
(5.7) <0.001

Low 35.7
(3.9)

37.6
(3.7)

33.9
(3.3) <0.001 88.0

(14.4)
88.3
(13.9)

87.7
(14.9) 0.240 26.9

(5.7)
26.0
(5.1)

27.7
(6.2) <0.001

Educational
level 0.012 <0.001 0.017

Primary
school

36.0
(4.1)

37.6
(3.9)

33.9
(3.4) <0.001 88.7

(14.8)
88.9
(14.7)

88.5
(14.9) 0.316 27.0

(5.8)
26.1
(5.3)

27.9
(6.1) <0.001

High school 35.0
(4.1)

37.6
(3.7)

33.4
(3.3) <0.001 87.2

(13.5)
89.2
(13.4)

85.5
(13.3) <0.001 26.7

(5.2)
26.4
(5.0)

26.9
(5.4) 0.019

Undergraduate
or higher

36.0
(4.1)

38.2
(3.6)

33.7
(3.2) <0.001 88.4

(13.4)
91.3
(12.6)

85.6
(13.6) <0.001 27.0

(5.2)
27.1
(4.9)

26.9
(5.5) 0.543

Marital
status <0.001 <0.001 <0.001

Single 35.0
(4.0)

36.9
(3.7)

33.1
(3.3) <0.001 83.8

(13.9)
84.8
(13.5)

82.7
(14.2) <0.001 25.3

(5.5)
24.9
(5.2)

25.8
(5.9) <0.001

Marriage 36.0
(4.1)

38.4
(3.8)

34.1
(3.3) <0.001 91.4

(13.6)
93.5
(13.3)

89.7
(13.7) <0.001 28.0

(5.4)
27.6
(4.9)

28.4
(5.7) <0.001

Separated,
divorced,
widowed

36.0
(4.1)

38.2
(3.9)

34.3
(3.5) <0.001 92.0

(14.2)
93.8
(14.8)

91.1
(13.9) 0.008 28.3

(5.5)
27.6
(5.0)

28.6
(5.7) 0.008

+ p value: difference between categories of each variable; ++ p value: difference between sex inside each category of the variable; NC: neck
circumference, WC: waist circumference, BMI: body mass index.

3.3. Correlation

Table 3 shows the correlation between NC and WC with BMI. With respect to the
total population correlation, the higher correlation was observed between NC and WC
(r = 0.64) and between NC and BMI (r = 0.51). However, a moderate correlation was
observed between NC and WC in men (r = 0.69) and a strong correlation in women
(r = 0.70). Similarly, it was observed that the correlation increased between NC and BMI
when stratified by sex (r = 0.65). When looking at the correlations by country, we can
see that in Argentina, Brazil, and Peru, the correlation between NC and BMI increased
when stratified by sex. In Brazil and Peru, the correlation between NC and WC was strong
(r = 0.71, 0.72, and 0.70, respectively). When analyzed by sex, there was a strong correlation
in men for all countries except Brazil and Costa Rica, and there was a strong correlation in
women in Argentina, Chile, Peru, and Costa Rica. The correlation between NC and BMI
was moderate in all countries; in the analysis by sex, there was a strong correlation in men
in Chile, Peru, Costa Rica, and Colombia, whilst, in women, there was a strong correlation



Int. J. Environ. Res. Public Health 2021, 18, 11975 6 of 12

in Argentina, Chile, Peru, and Costa Rica. In all age groups, the correlations between NC
and WC between NC and BMI were moderate. When analyzed by socioeconomic status,
it was strong only for the low level, both in men and women. By educational level, there
was only a strong correlation between NC and WC in men with basic and higher education
(r = 0.72 and 0.70, respectively) and in women with basic education (r = 0.71). By marital
status, the correlation between NC and WC was high in single men and women (r = 0.71
and 0.70, respectively).

Table 3. Correlation between NC and WC or BMI by sex and variables of interest. Latin American
Health and Nutrition Study/Estudio Latino Americano de Nutrición y Salud (ELANS).

TOTAL Men Women

NC-WC NC-BMI NC-WC NC-BMI NC-WC NC-BMI

Total 0.64 0.51 0.69 0.65 0.71 0.65

Country

Argentina 0.71 0.56 0.73 0.60 0.80 0.77
Brazil 0.55 0.41 0.58 0.52 0.59 0.50
Chile 0.72 0.59 0.79 0.75 0.78 0.78
Peru 0.70 0.57 0.81 0.80 0.80 0.76

Colombia 0.65 0.50 0.75 0.73 0.68 0.68
Costa Rica 0.64 0.59 0.69 0.80 0.79 0.79
Ecuador 0.62 0.48 0.75 0.67 0.67 0.64

Venezuela 0.64 0.51 0.70 0.61 0.69 0.65

Age (years)

15–19 0.61 0.50 0.63 0.61 0.68 0.62
20–34 0.63 0.50 0.67 0.62 0.67 0.62
35–49 0.64 0.48 0.68 0.62 0.68 0.63
50–65 0.59 0.42 0.66 0.55 0.63 0.60

Socioeconomic
status

High 0.61 0.49 0.62 0.56 0.63 0.58
Medium 0.64 0.50 0.70 0.64 0.68 0.63

Low 0.66 0.54 0.76 0.70 0.73 0.70

Educational
level

Primary school 0.64 0.51 0.72 0.66 0.71 0.67
High school 0.64 0.52 0.70 0.66 0.65 0.62

Undergraduate
or higher 0.65 0.49 0.62 0.54 0.68 0.60

Marital status

Single 0.65 0.54 0.71 0.67 0.70 0.65
Marriage 0.64 0.48 0.68 0.60 0.68 0.64
Separated,
divorced,
widowed

0.64 0.51 0.65 0.57 0.68 0.64

NC: neck circumference, WC: waist circumference, BMI: body mass index.

3.4. Cut-Off, Se, Sp, and AUC

Table 4 shows the cut-off point established taking into account the values of the
sensitivity and specificity analysis and AUC established by the ROC curve by sex and
according to nutritional status as defined by BMI (overweight, BMI > 25; and obese,
BMI > 30) and waist circumference (overweight: women > 80 cm; men > 95 cm; obese:
men > 102; women > 88 cm). The AUC, compared to WC for overweight in men was 85.9
(CI 95% = 84.6–87.1) for the cut-off point of 39.0 cm NC (Se: 76.5%, Sp: 83.4%), whilst, for



Int. J. Environ. Res. Public Health 2021, 18, 11975 7 of 12

women, the AUC value was 88.3 (CI 95% = 87.0–89.7) for the cut-off point of 32.9 cm (Se:
77.4%, Sp: 77.6%). For obesity compared to WC, the AUC was 88.3 (CI 95% = 87.0–89.7)
for the cut-off point of 39.8 cm (Se: 78.7%, Sp: 83.5%), and, in women, the AUC was
83.8 (CI 95% = 82.6–84.9), for the cut-off point of 33.7 cm (Se: 78.7%, Sp: 83.5%). Most
countries showed very similar values, and Brazil showed the lowest cut-off points for both
overweight and obesity in men and women (overweight: 37.4 cm in men and 32.0 cm in
women and obesity: 38.5 cm in men and 32.9 cm in women). The AUC when compared
with overweight and obesity values according to BMI are lower and the cut-off points are
also lower. Thus, in the total population, the AUC for overweight in men is 82.5 (CI 95%:
81.3–83.7) for the cut-off point of 37.5 cm (Se: 73.6% and Sp: 78.0%) and in women, the
AUC is 82.5 (CI 95%: 81.3–83.6) for the cut-off point of 33.1 cm (Se: 73.5% and Sp: 78.5%).
In the case of obesity in men, the AUC is 83.0 (CI 95%: 81.4–84.7) for the cut-off point of
39.2 cm (Se: 75.9% and Sp: 79.9%), and, in women, the AUC is 84.4 (CI 95%: 83.2–85.7) for
the cut-off point of 34.2 cm (Se: 80.0% and Sp: 75.9%).

Table 4. Cut-off for NC, sensibility, specificity, and area under the curve compared by nutritional level of WC and BMI for
the total population and by country. Latin American Health and Nutrition Study/Estudio Latino Americano de Nutrición y
Salud (ELANS).

Men Women

Cut-Off for
NC (cm)

Se
(%)

Sp
(%) AUC (CI 95%) (%) Cut-Off for

NC (cm)
Se
(%)

Sp
(%) AUC (CI 95%) (%)

TOTAL

WC

Overweight 39.0 76.5 83.4 85.9 (84.6–87.1) 32.9 77.4 77.6 83.8 (82.6–84.9)
Obesity 39.8 78.7 83.5 88.3 (87.0–89.7) 33.7 78.8 77.8 84.9 (83.8–86.0)

BMI

Overweight 37.5 73.6 78.0 82.5 (81.3–83.7) 33.1 73.5 78.5 82.5 (81.3–83.6)
Obesity 39.2 75.9 79.9 83.0 (81.4–84.7) 34.2 80.0 75.9 84.4 (83.2–85.7)

Argentina

WC

Overweight 38.6 79.2 86.8 87.9 (84.6–91.2) 33.2 75.5 84.3 88.5 (86.0–90.9)
Obesity 39.0 89.4 79.6 90.6 (87.4–93.8) 33.6 84.2 78.7 89.6 (87.3–91.9)

BMI

Overweight 38.0 64.6 82.5 76.6 (72.7–80.5) 33.4 76.3 82.5 87.5 (84.9–90.0)
Obesity 39.0 75.6 76.2 78.9 (73.5–84.3) 34.5 81.7 80.4 89.5 (86.9–92.0)

Brazil

WC

Overweight 37.4 74.6 70.0 78.5 (75.2–81.7) 32.0 75.0 63.2 75.9 (72.9–78.9)
Obesity 38.5 76.6 74.7 82.5 (78.9–86.1) 33.0 76.5 68.4 78.9 (76.2–81.6)

BMI

Overweight 37.0 70.1 68.1 75.0 (71.9–78.1) 32.0 74.7 56.7 72.7 (69.7–75.7)
Obesity 37.1 77.8 63.6 76.1 (72.1–80.0) 33.0 77.7 57.8 76.1 (72.8–79.3)

Chile

WC

Overweight 39.4 77.0 82.2 88.4 (85.3–91.6) 33.5 84.4 76.9 87.9 (84.1–91.6)
Obesity 40.2 85.3 82.9 91.9 (89.1–94.7) 34.8 83.6 80.0 88.7 (85.6–91.7)

BMI

Overweight 38.2 81.0 72.6 85.0 (81.2–88.8) 34.4 80.1 88.5 91.7 (89.1–94.3)
Obesity 40.2 85.7 82.2 90.4 (86.8–93.9) 35.3 86.4 76.4 89.3 (86.5–92.1)

Perú

WC

Overweight 38.6 84.1 86.5 91.7 (88.8–94.6) 32.7 76.9 87.8 89.4 (86.9–91.9)
Obesity 39.3 96.8 83.3 95.2 (93.4–97.0) 33.1 86.4 76.9 89.5 (87.0–91.9)



Int. J. Environ. Res. Public Health 2021, 18, 11975 8 of 12

Table 4. Cont.

Men Women

Cut-Off for
NC (cm)

Se
(%)

Sp
(%) AUC (CI 95%) (%) Cut-Off for

NC (cm)
Se
(%)

Sp
(%) AUC (CI 95%) (%)

BMI

Overweight 36.9 81.3 75.9 87.3 (84.4–90.3) 32.8 78.7 86.1 89.3 (86.7–91.9)
Obesity 39.1 92.0 84.0 92.6 (89.8–95.3) 33.8 90.3 71.3 88.1 (85.1–91.0)

Colombia

WC

Overweight 38.2 79.4 79.6 88.2 (85.3–91.1) 32.8 78.2 71.9 81.6 (78.2–84.9)
Obesity 39.9 77.5 86.4 89.3 (85.6–93.1) 33.8 88.0 58.8 84.1 (80.9–87.3)

BMI

Overweight 37.0 83.8 71.5 86.3 (83.4–89.1) 32.5 82.7 64.7 81.3 (78.0–84.7)
Obesity 39.1 83.1 82.9 89.9(86.4–93.5) 33.8 86.6 73.0 87.4 (84.2–90.5)

Costa Rica

WC

Overweight 38.9 87.3 79.2 86.9 (83.2–90.7) 32.6 84.7 81.9 90.5 (87.2–93.9)
Obesity 39.6 81.8 76.8 87.2 (82.9–91.5) 33.5 89.0 72.5 89.1 (86.0–92.3)

BMI

Overweight 38.4 79.9 87.1 90.2 (87.2–93.2) 33.7 81.1 82.2 91.0 (88.1–93.9)
Obesity 39.6 85.6 78.3 89.1 (85.2–93.1) 34.8 94.0 59.7 88.9 (85.6–92.1)

Ecuador

WC

Overweight 37.5 82.9 73.8 85.5 (81.4–89.7) 32.9 74.7 82.0 86.2 (82.5–89.9)
Obesity 38.7 87.5 77.9 87.7 (82.2–93.1) 33.7 69.7 79.3 82.2 (78.1–86.2)

BMI

Overweight 36.5 82.6 74.7 86.3 (82.8–89.9) 32.9 74.2 73.4 79.9 (75.4–84.5)
Obesity 38.7 75.0 80.0 83.8 (78.7–88.9) 34.2 79.0 83.2 84.6 (80.3–88.9)

Venezuela

WC

Overweight 39.0 80.5 81.9 86.4 (83.0–89.8) 33.1 76.1 82.8 86.6 (83.4–89.8)
Obesity 39.8 82.0 80.3 87.7 (83.9–91.4) 33.7 83.8 77.2 86.7 (83.7–89.7)

BMI

Overweight 37.6 78.3 79.1 84.6 (81.3–88.0) 33.3 77.1 79.3 84.3 (81.0–87.6)
Obesity 39.8 73.3 81.1 80.1 (75.4–84.9) 34.4 82.4 75.9 83.7 (80.1–87.3)

NC: neck circumference, WC: waist circumference, BMI: body mass index.

4. Discussion

The aim of our study was to evaluate the correlation between NC and BMI and WC in
Latin American populations living in urban areas and to propose cut-off points to determine
overweight and obesity through Se and Sp analyses and AUC. The results showed a
moderate correlation between CD and WC and NC and BMI in the total population
studied, although the correlation was higher when the data were stratified. This correlation
was slightly higher in women than in men, and the correlation was greater with WC than
with BMI. We found that an NC cut-off point of 39 cm identifies overweight in men when
compared to WC and 39.8 cm for obesity, and, in women, the cut off points were 32.9 and
33.7 cm, respectively. When compared with BMI, the cut-off point of NC for men was
37.5 cm and for obesity 39.2 cm, whilst in women, it was 33.1 and 34.2 cm, respectively.

The correlations we found in our study were moderate to strong. In a systematic
review, a higher correlation was found between NC and WC (r = 0.85) and between NC
and BMI (r = 0.88) [18]. This may be because this study was a review of 19 publications
from Europe and Asia. In Asia, the body composition of its population is different to Latin
Americans, and different BMI cut-off points are used to define overweight and obesity,



Int. J. Environ. Res. Public Health 2021, 18, 11975 9 of 12

which could explain some of the difference from the results of our study, where other
cut-off values for BMI have been used to compare with NC, which differ from the highest
cut-off points in South America; consequently, the body composition could be different
and, therefore, the correlations could change. Brazil showed a moderate correlation; this
was the lowest observed among all the countries, so it would be necessary to evaluate what
leads to these values.

In our study, the correlations between NC and WC and between NC and BMI were
stronger when stratified by sex. A similar situation has been described in an urban district in
southern Israel, (men = 0.86; females: r = 0.85) [19] and in subjects with metabolic syndrome
in Calcutta, India (males: r = 0.74 and females: r = 0.71) [20]. In Bangladesh, a moderate
correlation was found, lower in women than in men (r = 0.46 vs. r = 0.61, respectively) [21].
A study conducted in Karachi, Pakistan, with students aged 18 to 20 years, found a strong
correlation between NC and WC in men (r = 0.85) and a moderate correlation with women
(r = 0.62) [14]. In Peru, a study conducted in a province of Lima showed a strong correlation
in men and women (r = 0.74 and r = 0.72; respectively), slightly lower than that found in
our study in Peru, but like that found in the general population [22].

With respect to the correlations between NC and BMI, a moderate correlation was
found in our study. The author of the Peruvian study showed a strong correlation when
stratified by sex (men: r = 0.72 and women r = 0.78) [22]. A study conducted in Brazil [23])
and another in Calcutta [19] both found a strong correlation in men (r = 0.73, r = 0.74,
respectively) but a moderate correlation in women (r = 0.68 in both studies). These studies
suggest that this may be because men have more muscle mass compared to women.
However, it is worth mentioning that information differed from those we found in Brazil
in our study, where the correlations were the lowest.

When analyzed by age, the correlations were moderate in our study. In Pakistan, a
study conducted with university students between 18 and 20 years of age, the correlation
between NC and BMI was strong in both men and women (r = 0.86; r = 0.70, respec-
tively) [14]. In a study conducted in older adult Brazilian women, NC showed a moderate
correlation with BMI (r = 0.67) and also with WC (r = 0.56) [24]. It is worth mentioning that
the differences in the correlations found between NC, WC, and BMI compared to studies
from Asian countries may be because the height and, in general, the body morphology in
these populations are different.

Coutinho and collaborators in a study conducted with 2794 students between 6 and
19 years of age in Sao Paulo found a strong correlation between NC and BMI (r = 0.75) and
WC (r = 0.81) [25]. Similar results were found when stratified by sex [26]. These differences
in the results may be due to the fact that the populations of these studies were of different
ages; therefore, the correlations could differ with age.

Regarding NC cutoff points, other studies have identified similar values to those
found in our study. Thus, in Israel and a study conducted in Lima, Peru, the best NC
cut-off point for overweight was found to be 37 cm for men and 34 cm for women [16,22].
In addition, the Lima, Peru, study identified that for obesity the cut-off point was 39.5 cm
for men and 36.5 cm for women [21]. These values coincide with our results in the total
population of our study, especially when the cut-off point was identified with the values
for overweight and obesity for BMI.

Finally, to evaluate the advantages of using NC to assess overweight and obesity, it is
necessary to understand the limitations of the other measurements applied in our study
(WC and BMI) for comparison. Although we found a higher correlation between NC and
WC than with BMI, the most used method to determine overweight and/or obesity is
BMI. Several studies have discussed the accuracy of the use of the different anthropometric
measurements that are most used in clinical practice and conclude that, in patients with
overweight and obesity, the WC may present a greater margin of error in the measurement
due to the difficulty of locating the anatomical reference points [27,28]. In addition, the
WC requires more time and training and, like BMI, may be affected by the time of day
when it is measured. Nevertheless, BMI uses universally accepted measures that can be



Int. J. Environ. Res. Public Health 2021, 18, 11975 10 of 12

performed by a relatively simple procedure (weight and height). Therefore, it remains
the most useful measure for detecting overweight and obesity in medical practice, and it
is more accurate when performed by trained personnel [27]. However, evidence shows
that the existing anthropometric measurements are not entirely effective for adequately
diagnosing overweight and/or obesity because of the difficulty in their application and
accuracy in the measurement technique. It is for this reason that measurement of the NC
has emerged as a simple, low-cost, and minimally invasive method. Likewise, it is not
affected by the time of day when it is measured, nor does it change with food intake, nor
is it sensitive to abdominal distension (16). Finally, it is not impaired by gas exchange on
inhalation and exhalation. Therefore, it is considered an anthropometric measure that can
be used but further research is required for its validation.

This study has some limitations, since the ELANS study did not take as exclusion
criteria people who might have presented goiter related to iodine deficiency, so the mea-
surement of NC could be affected. However, this proportion of the population is expected
to be low. On the other hand, this study is only representative of the urban population
of the countries under study and does not represent the population living in rural areas.
Finally, it does not have information on chronic diseases: hypertension, diabetes, or others
that could help to better identify the usefulness of the NC measure. Nevertheless, this is
one of the few studies in Latin America that has a fairly large sample and has been carried
out in different regions of each country. It also has different anthropometric measures that
are rarely included in studies.

5. Conclusions

Our study found a moderate correlation between NC and WC and NC and BMI;
both correlations improved when stratified by sex. The cutoff point of 39 cm identi-
fies overweight men according to WC and 39.8 cm for obesity, and, in women, it was
32.9 and 33.7 cm, respectively. The cut-off point for NC in men, if considered overweight,
determined by BMI, was 37.5 cm, and for obesity, 39.2 cm, while in women, it was
33.1 and 34.2 cm, respectively. Taking into account that the WC is a better indicator of
central obesity, we consider that it is better to take into account the cut-off point that was
found, taking into account this indicator. These results indicate that NC can be used as a
simple, easy, and fast method to identify overweight and obesity in people and that it can
be applied especially at the first level of care, since it does not require heavy equipment
and can be easily transported. However, it is important to continue studying this tool as an
anthropometric measurement so that it can be used in the different primary care health
services. In addition, its potential as a predictor of different chronic diseases should be
further investigated and compared with other anthropometric measures such as BMI and
WC.

Author Contributions: Conceptualization, R.L.-D., M.P.-A., and M.-P.V.; methodology, R.L.-D.,
M.P.-A., and M.-P.V.; formal analysis, R.L.-D., M.P.-A., and M.-P.V.; resources, R.L.-D., M.P.-A.,
M.-P.V., G.G., I.K., L.Y.C., M.C.Y.G., M.H.-C., G.F., A.R., M.F., and R.G.P.; data curation, R.L.-D.,
G.G., I.K., L.Y.C., M.C.Y.G., M.H.-C., G.F., A.R., M.F., and R.G.P.; writing—original draft preparation,
R.L.-D., M.P.-A., M.-P.V., and R.G.P.; writing—review and editing, R.L.-D., and R.G.P.; supervision,
R.L.-D., project administration, R.L.-D., G.G., I.K., L.Y.C., M.C.Y.G., M.H.-C., G.F., A.R., M.F., and
R.G.P.; funding acquisition, R.L.-D., G.G., I.K., L.Y.C., M.C.Y.G., M.H.-C., G.F., A.R., M.F., and R.G.P.
All authors have read and agreed to the published version of the manuscript.

Funding: The ELANS was supported by a scientific grant from the Coca Cola Company, and support
from the Ferrero, Instituto Pensi/Hospital Infantil Sabara, International Life Science Institute of Ar-
gentina, Universidad de Costa Rica, Pontificia Universidad Católica de Chile, Pontificia Universidad
Javeriana, Universidad Central de Venezuela (CENDES-UCV)/Fundación Bengoa, Universidad San
Francisco de Quito, and Instituto de Investigación Nutricional de Peru. The sponsors had no role in
study design, in the collection, analyses, or interpretation of data, in the writing of the manuscript,
and in the decision to publish the results. This study is registered at www.clinicaltrials.gov (No.
NCT02226627).

www.clinicaltrials.gov


Int. J. Environ. Res. Public Health 2021, 18, 11975 11 of 12

Institutional Review Board Statement: The study was conducted according to the guidelines of the
Declaration of Helsinki and approved by the Institutional Review Board of the Western Institutional
Review Board (n20140605). Local ethics institutional review boards from each country also approved
the study.

Informed Consent Statement: Informed consent was obtained from all subjects involved in the
study.

Data Availability Statement: No new data were created or analyzed in this study. Data sharing is
not applicable to this article.

Acknowledgments: The authors would like to thank research participants and all the members
of ELANS Study Group. The following are members of ELANS Study Group: Chairs: Mauro
Fisberg, and Irina Kovalskys; Co-chair: Georgina Gómez; Core Group Members: Attilio Rigotti,
Lilia Yadira Cortés Sanabria, Georgina Gómez, Martha Cecilia Yépez García, Rossina G. Pareja,
and Marianella Herrera-Cuenca; Project Managers: Viviana Guajardo, and Ioná Zalcman Zimberg;
Dietary Intake Advisor: Agatha Nogueira Previdelli; Argentina: Irina Kovalskys, Viviana Guajardo,
Bryan Cavagnari, and Alejandro Gerardi; Brazil: Mauro Fisberg, Ioná Zalcman Zimberg, Natasha
Aparecida Grande de França, Gerson Ferrari, and Ana Del’Arco; Chile: Attilio Rigotti, Guadalupe
Echeverría, Leslie Landaeta, and Oscar Castillo; Colombia: Lilia Yadira Cortés Sanabria, Luz Nayibe
Vargas, Luisa Fernanda Tobar, and Yuri Milena Castillo; Costa Rica: Georgina Gómez, Rafael Monge
Rojas, Anne Chinnock, Dayana Quesada, and Juan Carlos Brenes; Ecuador: Martha Cecilia Yépez
García, and Mónica Villar Cáceres; Perú: Rossina Pareja Torres, Reyna Liria-Domínguez, Krysty
Meza, and Melissa Abad; Venezuela: Marianella Herrera-Cuenca, Maritza Landaeta-Jiménez, Betty
Méndez, Maura Vásquez, Omaira Rivas, Carmen Meza, Servando Ruiz, Guillermo Ramírez, and
Pablo Hernández; Accelerometry analysis: Priscila Bezerra Gonçalves and Claudia Alberico; Physical
activity advisor: Gerson Ferrari. In addition, the authors would like to thank the external committee,
Berthold Koletzko, Luis A. Moreno and Michael Pratt.

Conflicts of Interest: The authors declare no conflict of interest.

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	Introduction 
	Materials and Methods 
	Study Design 
	Population 
	Study Sample and Sampling 
	Data Collection Procedure 
	Data Management and Analysis Plan 

	Results 
	General Characteristics of the Population 
	Bivariate Analysis 
	Correlation 
	Cut-Off, Se, Sp, and AUC 

	Discussion 
	Conclusions 
	References