Int. J. Environ. Res. Public Health 2021, 18, x. www.mdpi.com/journal/ijerph 

Article 

Alcohol Contribution to Total Energy Intake and Its  
Association with Nutritional Status and Diet Quality in Eight 
Latina American Countries 
Juan Carlos Brenes 1,*, Georgina Gómez 2, Dayana Quesada 2, Irina Kovalskys 3, Attilio Rigotti 4,  
Lilia Yadira Cortés 5, Martha Cecilia Yépez García 6, Reyna Liria-Domínguez 7,8, Marianella Herrera-Cuenca 9,  
Viviana Guajardo 10, Regina Mara Fisberg 11, Ana Carolina B. Leme 11,12,13, Gerson Ferrari 14  
and Mauro Fisberg 12,15 on behalf of the ELANS Study Group † 

1 Neuroscience Research Center, Institute of Psychological Research, University of Costa Rica, San José 10501-
2060, Costa Rica 

2 Departament of Biochemistry, School of Medicine, University of Costa Rica,  
San José 11501-2060, Costa Rica; georgina.gomez@ucr.ac.cr (G.G.) dahiana.quesada37@gmail.com (D.Q.) 

3 Career of Nutritión, Faculty of Medical Sciences, Pontificia Universidad Católica Argentina,  
Buenos Aires C1107AAZ, Argentina; ikovalskys@gmail.com 

4 Departament of Nutrition Diabetes and Metabolism, School of Medicine, Faculty of Medicine, Pontificia 
Universidad Católica de Chile, Santiago 8330024, Chile; arigotti@med.puc.cl 

5 Departament of Nutritión and Biochemistry, Pontificia Universidad Javeriana, Bogotá 110231, Colombia; 
ycortes@javeriana.edu.co 

6 School of Health Sciences, San Francisco University of Quito, Quito 17-1200-841, Ecuador;  
myepez@usfq.edu.ec 

7 Institute of Nutritional Research, Lima 15026, Peru; rliria@iin.sld.pe 
8 Career of Nutrition and Dietetics, Faculty of Health Sciencies, Peruvian University of Applied Sciences, 

Lima 15067, Peru 
9 Center for Development Studies, Central University of Venezuela/Bengoa Fundation of Food and Nutrition, 

Caracas 1053, Venezuela; manyma@gmail.com 
10 Institue for Scientific Cooperation in Health and Environment, Buenos Aires Santa Fe Av. 1145,  

Caba C1059ABF, Argentina; viviana.guajardo@comunidad.ub.edu.ar 
11 Department of Nutrition, School of Public Health, University of São Paulo, Sao Paulo 01246-904, Brazil;  

regina.fisberg@gmail.com (R.M.F.); acarol.leme@gmail.com (A.C.B.L.) 
12 Center for Nutrology and Feeding Difficulties, Pensi Institute, José Luiz Egydio Setubal Foundation, Sarabá 

Children’s Hospital, Sao Paulo 01228-200, Brazil; mauro.fisberg@gmail.com 
13 Family Relations and Applied Nutrition, University of Guelph, Guelph, ON N1G 2W1, Canada 
14 Sciences of Physical Activity, Sports and Health School, Universith of Santiago of Chile, Santiago 7500618, 

Chile; gerson.demoraes@usach.cl  
15 Departament of Pediatrics, School of Medicine, Federal University of Sao Paulo, São Paulo 04023-061, Brazil 
* Correspondence: juan.brenessaenz@ucr.ac.cr 
† Members are listed in Acknowledgments. 

Abstract: Alcohol consumption is a modifiable risk factor for non-communicable diseases. This 
study aimed to characterize alcohol consumers at the nutritional, anthropometric, and sociodemo-
graphic levels. Data from 9218 participants from Argentina, Brazil, Chile, Colombia, Costa Rica, 
Ecuador, Peru, and Venezuela participating in “Latin American Health and Nutrition Study 
(ELANS),” a multi-country, population-based study, were used. Dietary intake was collected 
through two, 24 h recalls. Participants were classified into consumers (n = 1073) and non-alcohol 
consumers (n = 8145) using a cut-off criterium of ≥15 g/day of alcohol consumption calculated from 
the estimation of their usual daily intake. Among alcohol consumers, the mean alcohol consumption 
was 69.22 ± 2.18 grams (4.6. beverages/day), contributing to 484.62 kcal, which corresponded to 
16.86% of the total energy intake. We found that the risk of alcohol consumption was higher in 
young and middle-aged men from low and middle socioeconomic status. Argentine, Brazil, and 
Chile had the highest percentage of consumers, while Ecuador showed the highest alcohol con-
sumption. Alcohol drinkers were characterized by having higher body weight and wider neck, 
waist, hips circumferences. Alcohol drinkers had a higher energy intake, with macronutrients 

Citation: Brenes, J.C.; Gómez, G.; 

Quesada, D.; Kovalskys, I.; Rigotti, 

A.; Cortés, L.Y.; Yépez García, M.C.; 

Liria-Domínguez, R.; Herrera-

Cuenca, M.; Guajardo, V.; et al. Alco-

hol Contribution to Total Energy In-

take and Its Association with Nutri-

tional Status and Diet Quality in 

Eight Latina American Countries. 

Int. J. Environ. Res. Public Health 2021, 

18, x.  

Academic Editor(s): Paul B. 

Tchounwou 

Received: 6 October 2021 

Accepted: 5 November 2021 

Published: date 

Publisher’s Note: MDPI stays neu-

tral with regard to jurisdictional 

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tional affiliations. 

 

Copyright: © 2021 by the authors. Li-

censee MDPI, Basel, Switzerland. 

This article is an open access article 

distributed under the terms and con-

ditions of the Creative Commons At-

tribution (CC BY) license (http://crea-

tivecommons.org/licenses/by/4.0/). 



Int. J. Environ. Res. Public Health 2021, 18, x  2 of 19 
 

 

providing relatively less energy at the expense of the energy derived from alcohol. Alcohol drinkers 
showed lower and higher consumptions of healthy and unhealthy food groups, respectively. In ad-
dition, adequacy ratios for all micronutrients assessed were lower in alcohol consumers. All these 
deleterious effects of alcohol on nutritional and anthropometric parameters increased with the num-
ber of alcoholic beverages consumed daily. Altogether, these findings suggest that limiting alcohol 
consumption can contribute to reducing the risk of obesity, metabolic syndrome, and diet-related 
diseases. 

Keywords: alcohol intake; macronutrients; micronutrients; food groups; Latin America; nutrition 
survey 
 

1. Introduction 
Historically, alcoholic beverages have been part of the human diet for cultural, social, 

and spiritual reasons [1]. According to World Health Organization, in 2016, approxi-
mately 43% of the worldwide population who were 15 years old or above had consumed 
alcohol in the previous 12 months, with an average consumption of pure alcohol of 6.4 L 
per capita [2]. Spirit beverages are the most consumed type of alcoholic beverage (44%), 
while beer and wine represent the second and third most consumed alcoholic drinks rep-
resenting 34.3% and 11.7% of total alcohol consumption, respectively. The Americas and 
European regions exhibited the highest alcohol consumption in the world [2,3]. Popula-
tion studies reported higher frequencies of alcohol consumption in men than women, 
while factors such as age, socioeconomic status (SES), and educational level vary among 
regions [4–6]. The excessive consumption of alcohol has been linked to adverse health 
consequences with high economic costs both at the individual and societal level [3]. Alco-
hol consumption is considered a risk factor for early death, causing approximately 3 mil-
lion deaths worldwide each year [7]. It is also a modifiable risk factor associated with a 
wide range of non-communicable diseases, such as cardiovascular and liver diseases, can-
cer, neurological and psychiatric disorders (e.g., neurocognitive and drug dependence 
disorders), and unintentional injuries [7,8]. However, one of the most important yet ne-
glected factors is the impact that alcohol may have on body weight gain, obesity, meta-
bolic syndrome, and diet-related diseases [9]. Alcohol provides 7 kcal/g, making it the 
second most important source of energy in the diet, surpassed only by fats, which have 
about 9 kcal/g [10]. It is expected, therefore, that the energy derived from alcohol con-
sumption will sum up to other energy sources promoting a positive energy balance po-
tentially leading to weight gain [11,12]. Furthermore, alcohol consumed before or with 
meals induces orexigenic effects by increasing appetite and reducing satiation due to 
changes in the rewarding perception of food [1]. The alcohol-driven, inhibitory control 
impairment may be another mechanism explaining higher food intake when drinking al-
cohol before or during meals [12].  

Despite all this evidence, the relationship between alcohol consumption and obesity 
is still unclear. While some studies have reported that mild to moderate alcohol intake is 
associated with a lower prevalence of obesity, others have found quite the opposite. Evi-
dence suggests that alcohol type, consumption patterns, and sex affect the relationship 
between alcohol and obesity [13]. Sayon et al. (2011) reported that at least seven beers and 
spirits per week, but not wine, increased the risk for overweight and obesity [10]. In the 
United States population, it was found that men, but not women, consuming 5 drinks per 
day increased body mass index (BMI) and waist circumference compared to those con-
suming 1 to 2 drinks per day [6]. In contrast, alcohol consumption has been associated 
with a reduced risk of clinical events showing positive effects on cardiovascular health 
and lower mortality, perhaps by improving the lipid profile and insulin sensitivity among 
moderate drinkers [14,15]. These positive outcomes of alcohol consumption seem to be 



Int. J. Environ. Res. Public Health 2021, 18, x  3 of 19 
 

 

dependent on the amount and frequency of alcohol consumption. In Japanese male drink-
ers, the prevalence of metabolic syndrome and its risk factors increase with alcohol con-
sumption. However, the metabolic syndrome prevalence was significantly higher among 
the nondrinkers when compared to light or moderate drinkers [14,15]. In Korean men, a 
consumption greater than 2–3 times per week increased the likelihood of suffering meta-
bolic syndrome, but no associations were found in those drinking less than 2–3 times per 
week [16]. One other study showed that consuming two or more alcoholic beverages per 
drinking session was enough to increase waist circumference, triglycerides levels, blood 
pressure, and fasting plasma glucose [16]. The type of alcoholic beverage appears to have 
a role in nutritional and health outcomes. For instance, the consumption of beer and spirits, 
but not wine, increased the risk for obesity and produced greater weight gain after a me-
dian follow-up of six years [17]. However, many of these studies did not analyze in detail 
the dietary habits of their participants, something that should be evaluate to elucidate the 
contribution of alcohol consumption to the nutritional and health status [18]. This may 
have compromised identifying a clear cause-and-effect association between alcohol con-
sumption and overweight parameters. Considering that both obesity and excessive alco-
hol consumption are of public health concern, a better understanding of the association 
between alcohol consumption and bodyweight gain is warranted. 

Latin America and the Caribbean regions have the fifth-highest adult alcohol per cap-
ita (APC) (6.8 L) in the world, with most (61%) countries in the Americas exhibiting a total 
adult APC that is higher than the global average [7]. Coincidently, a representative study 
with urban samples of Latin America countries showed that ~60% of the population was 
overweight or obese [19]. To our knowledge, however, there are no studies that have eval-
uated the relationship between alcohol consumption and the risk of obesity in the Latin 
American region. The purpose of the present study was, therefore, to determine the drink-
ing patterns of current alcohol consumers according to sociodemographic variables (i.e., 
country, sex, age, and SES) and the association between alcohol consumption and anthro-
pomorphic measurements (i.e., BMI, body weight, neck, waist, and hips circumference), 
food intake (e.g., macro- and micronutrients intake and contribution to total energy intake 
and preferred food groups consumed) and diet quality (e.g., diet quality score and diver-
sity indexes and micronutrients adequacy) in a large, multinational representative sample 
of urban areas of eight Latin American countries (Argentina, Brazil, Chile, Colombia, 
Costa Rica, Peru, and Venezuela).  

2. Materials and Methods 
2.1. Study Population 

The Latin American Study of Nutrition and Health (Estudio Latino Americano de 
Nutrición y Salud, ELANS) aimed to assess weight status, food consumption, and physi-
cal activity in a representative sample of urban areas of eight Latin American countries 
(Argentina, Brazil, Chile, Colombia, Costa Rica, Peru, and Venezuela). ELANS is a cross-
sectional, household-based multinational survey. A total of 9218 participants aged 15–65 
years old were included by a random complex selection of primary and secondary sam-
pling units. The households were selected within each secondary sampling unit and 
through systematic randomization. Selection of respondents within a household was con-
ducted, including 50% of the sample next birthday and 50% last birthday methods [20], 
controlling quotas for sex, age, and SES. SES was classified into low, middle, and high, 
using a country-dependent questionnaire based on governmental reference according to 
national population census and on legislative requirements or established local standard 
layouts. Data collection was conducted from September 2014 to July 2015. Details have 
been previously published [21]. The ELANS protocol was approved by the United States 
Western Institutional Review Board (#20140605) and the Ethics Review Boards of each of 
the participating institutions and was registered at Clinical Trials (#NCT02226627). All 
participants provided written informed consent. Individual confidentiality for the pooled 



Int. J. Environ. Res. Public Health 2021, 18, x  4 of 19 
 

 

data were maintained by using numeric identification codes rather than names. All data 
transfer was conducted with a secure file sharing system.  

2.2. Anthropometric Measurements 
Anthropometric measurements were taken in duplicate by trained interviewers, ac-

cording to the procedures proposed by the WHO [22]. The WHO reference was used to 
determine weight status in adults [22]: underweight (BMI < 18.5 kg/m2), normal weight 
(BMI = 18.5–24.99 kg/m2), overweight (BMI = 25.0–29.99 kg/m2), obesity (BMI ≥ 30–39.99 
kg/m2), morbid obesity (BMI ≥ 40 kg/m2). Adolescents were classified according to the 
WHO z-scores for age and sex of each participant [23], considering < −2SD for thinness; > 
−2 to < +1SD for normal weight, > +1 to < +2SD for overweight, and > +2SD obesity. 

2.3. Dietary Assessment 
Dietary intake data were obtained from 2 face-to-face, 24 h recalls. Weekdays and 

weekend days were included with a proportional distribution of days among the sample 
to capture the day-to-day variations in food consumption. A photographic album of com-
mon foods of each country and household utensils were used to estimate portion sizes. 
Participants were asked to report all the foods and beverages consumed on the previous 
day, following the multiple-pass method [24]. Data were converted into energy, macro-, 
and micronutrients using the Nutrition Data System for Research software (NDS-R ver-
sion 2013) [25]. Since NDS-R is based on the US Department of Agriculture food compo-
sition table, trained dietitians performed a previous standardization procedure to match 
local foods in each country in order to minimize errors [25]. Usual energy and nutrients 
intake were estimated for using the Multiple Source Method (MSM) (https://msm.dife.de/ 
(accessed on 16 July 2015)), which combines the probability and the amount of food con-
sumed to estimate the usual intake for each individual [26]. 

Dietary quality score (DQS) was assessed following a methodology proposed by 
Imamura et al., 2015 [27]. Briefly, this approach evaluates the consumption of key dietary 
items adjusted for 2000 kcal per day, including healthy [i.e., fruits, vegetables, beans and 
legumes, nuts and seeds, whole grains, dairy, polyunsaturated fats (PUFAs), fish, plant 
omega 3, and dietary fiber] and unhealthy [i.e., unprocessed read meats, processed meats, 
sugar-sweetened beverages (SSB), saturated fat, trans fat, dietary cholesterol, and sodium] 
items. For each dietary factor mean, the intake was divided into age-, sex-, and country-
specific quintiles. Each quintile was assigned an ordinal score. Higher scores were given 
to quintiles with higher mean intakes of healthy foods (from 1 to 5) for lower mean intakes 
of unhealthy foods. For unhealthy foods, higher scores were given to quintiles with lower 
mean intakes (from 5 to 1 points). All items were summarized and standardized to a 100-
point scale in which the higher the scores, the healthier the diet. A detailed analysis of 
DQS in the ELANS study population was previously published [28]. All food items re-
ported to have been consumed during the first 24 h recall were classified into 10 food 
groups to assess dietary diversity score (DDS), according to the Minimum Dietary Diver-
sity Score for Women (MDD-W) proposed by FAO [29]: (1) starchy staples (grains, with 
roots and tubers and plantains); (2) meat, poultry, and fish; (3) dark-green leafy vegeta-
bles; (4) other vitamin A-rich fruits and vegetables; (5) other vegetables; (6) other fruits; 
(7) pulses (beans, peas, and lentils); (8) dairy; (9) eggs; and (10) nuts and seeds. For the 
consumption of at least 15 g/day, 1 point was assigned if consumed or 0 points if intake 
of that specific food group was less than 15 g/day, for a maximum score of 10 points. Mi-
cronutrient’s adequacy was determined using the Estimated Average Requirements 
(EAR) from the Institute of Medicine. They were used because they were a recommended 
standard parameter to estimate the prevalence of inadequate nutrient intake within a 
group [30]. Nutrient adequacy ratios (NAR) were estimated for vitamins A, C, D, and E, 
calcium, iron, thiamin, riboflavin, niacin, cobalamin, pyridoxine, zinc, magnesium, cop-
per, phosphorus, and selenium. The NAR value for a given nutrient was the ratio of a 



Int. J. Environ. Res. Public Health 2021, 18, x  5 of 19 
 

 

participant’s current nutrient intake to the EAR for the corresponding sex and age cate-
gory [31]. NAR’s values close to 1 implies that recommended nutrient intake was achieved 
or exceeded. Considering that a nutrient with a high NAR cannot be compensated by a 
nutrient with a low NAR, all NARs were truncated at 1. The mean adequacy ratio (MAR) 
was calculated as the sum of all NARs divided by the number of nutrients assessed. 

2.4. Statistical Analyses 
Data were analyzed using the Statistical Package for Social Sciences (SPSS) software 

program (version 23, SPSS Inc., Chicago, IL, USA). We classified the participants accord-
ing to the level of alcohol intake using a cut-off criterium of ≥15 g/day of alcohol consumed 
calculated from the estimation of their usual daily intake. Thus, 2 subgroups were created: 
(1) alcohol consumers and (2) non-alcohol consumers. A chi-square test (χ2) was used to 
estimate the significant differences in the distribution of participants between countries, 
sex, and age intervals within the group of alcohol consumers.  

Table 1. Alcohol-consumption parameters according to the sociodemographic characteristics of alcohol consumers. 

  Alcohol Consumption (g)/day Energy from Alcohol 
(Kcal)/day 

1 Energy from Alcohol 
(%)/day  

 N Mean 2 SEM Min Max Mean SEM Min Max Mean SEM Min Max 
Overall sample 1073 69.22 (4.6) 2.17 15.00 678.00 484.62 15.27 105.00 4793.46 16.81 0.34 2.36 69.64 
Sex              

Male 733 74.46 (5) 2.69 15.00 678.00 521.31 18.92 105.00 4793.46 17.00 0.42 2.36 69.64 
Female 340 57.91 (3.9) 3.59 15.00 575.00 405.61 25.20 105.00 4065.25 16.54 0.61 3.73 68.88 
Age group              

15–19 years 59 72.91 (4.9) 9.57 15.00 313.00 510.37 67.00 105.00 2191.00 15.40 1.49 2.36 56.83 
20–34 years 455 73.55 (4.9) 3.35 15.00 564.00 514.88 23.50 105.00 3948.00 17.04 0.55 2.81 69.64 
35–49 years 336 72.32 (4.8) 4.32 15.00 678.00 506.54 30.34 105.00 4793.46 17.61 0.62 3.50 67.89 
50–65 years 223 54.71 (3.6) 3.65 15.00 470.00 383.01 25.57 105.00 3290.00 15.74 0.70 3.96 68.88 
Countries              

Argentina 285 46.80 (3.1) 2.15 15.02 306.21 327.65 15.11 105.12 2143.49 11.64 0.41 2.81 49.64 
Brazil 324 79.05 (5.3) 4.05 15.00 564.00 553.34 28.39 105.00 3948.00 21.05 0.69 2.36 68.88 
Chile 115 50.61 (3.4) 4.58 15.00 306.00 354.29 32.06 105.00 2142.00 14.16 0.79 4.03 55.86 
Colombia 81 92.10 (6.1) 11.51 15.00 575.00 645.24 80.87 105.00 4065.25 18.64 1.70 3.72 69.64 
Costa Rica 67 64.64 (4.3) 6.80 15.00 346.00 452.49 47.63 105.00 2422.00 16.83 1.19 4.71 53.50 
Ecuador 33 115.33 (7.7) 27.97 15.00 678.00 808.98 196.69 105.00 4793.46 17.99 23.6 3.73 55.26 
Peru 84 67.44 (4.5) 5.78 16.00 257.00 472.09 40.51 112.00 1799.00 15.38 0.98 3.85 40.82 
Venezuela  84 98.05 (6.5) 8.99 16.00 435.00 686.39 62.99 112.00 3045.00 21.42 1.30 3.96 58.35 
Socioeconomic status             

Low 521 78.27 (5.2) 3.39 15.00 575.00 547.97 23.78 105.00 4065.25 18.58 0.54 2.81 68.88 
Middle 454 62.93 (4.2) 3.17 15.00 678.00 440.64 22.28 105.00 4793.46 15.56 0.49 2.36 69.64 
High 98 50.22 (3.3) 4.21 15.00 232.00 351.54 29.50 105.00 1624.00 13.71 0.79 4.56 38.60 

Standard error of the mean (SEM). Grams of alcohol (g). Kilocalories derived from alcohol (Kcal). 1 Percentage of energy 
from alcohol [(alcohol energy/total energy intake) × 100]. 2 The numbers in parenthesis represent the equivalent of alcohol 
beverages per day according to the average consumption of grams of alcohol (grams of alcohol/15). See main text for 
details. 

The between-group comparisons of alcohol intake parameters (i.e., grams, calories, 
and percentage of calories from alcohol relative to the total energy intake) were analyzed 
by means of factorial multivariance analyses (MANOVA). For sociodemographic varia-
bles we used a two-way MANOVA followed by Bonferroni post-hoc test (when appropri-
ate) with alcohol parameters as dependent variables and country, sex, socioeconomic sta-
tus (SES), and age as fixed factors and subgroups of alcohol consumers as a second factor. 



Int. J. Environ. Res. Public Health 2021, 18, x  6 of 19 
 

 

One-way MANOVA was used to compare all dependent variables (e.g., macronutrients. 
food groups, micronutrients, diet quality indicators, and anthropometric measurements) 
between the 2 alcohol subgroups controlled by country, sex, and age. For the analysis of 
NAR scores, we also controlled by total energy intake as NAR values are strongly depend-
ent of total energy consumed (see results for details).  

To further provide evidence that the alcohol intake is related to nutritional and an-
thropometric variables, we classified the grams of alcohol into quartiles (Q) within the 
subgroup of alcohol consumers. Based on the grams of alcohol consumed within each 
quartile, we estimated the number of alcohol beverages representing each quartile as fol-
lows (Q0) 0 beverages, (Q1) 1 beverage, (Q2) 2–3 beverages, (Q3) 4–6 beverages, (Q4) more 
than 10 beverages. This classification allows us to identify the breaking points where al-
cohol consumption started to bestow health risks compared to non-consumers. Therefore, 
we reported the minimal number of beverages required to observe significant differences 
compared to non-consumers (e.g., 0 beverages) according to Bonferroni pairwise compar-
isons (all p-values < 0.05) after controlling by sex, country, and age. If there were signifi-
cant differences between Q0 and Q1 or between Q0 and Q2 or Q3, the subsequent com-
parisons against Q0 were also significant.  

We reported marginal means ± standard error of the mean (SEM) because these 
means were adjusted for the covariates included in the models and showed the exact val-
ues corresponding to the statistical analysis. The advantage of marginal means resides in 
the fact that they are estimated from complex models reflecting intricated effects that can-
not be otherwise detected from the raw data. For that reason, the observed means and 
their standard deviation would not accurately represent the effects described by the mod-
els and, therefore, will slightly differ from the estimated marginal means. As an index of 
the effect size of the model, we reported the partial eta squared coefficients (η2p), which 
were also adjusted for the covariates included in the models. In all analyses, p < 0.05 values 
were considered statistically significant. 

3. Results 
3.1. Distribution of Sociodemographic Variables 

There was substantial variability in alcohol intake in the whole sample (Table 1 and 
Supplementary Table S1). As 14–15 g of alcohol is commonly used to define a standard 
drink (e.g., a 12-ounces beverage with 5% of alcohol), we used a cut-off criterium of ≥15 g 
of alcohol to ensure that participants who met that criterium consumed at least the equiv-
alent of one alcohol drink calculated as an estimation of their usual daily intake. Conse-
quently, there were significant differences between the subgroups of consumers and non-
consumers in the grams of alcohol consumed (F(1,9202) = 6452.292, p = 0.00001, η2p = 0.412), 
the net calories obtained from alcohol (F(1,9202) = 6440.413, p = 0.0001, η2p = 0.412), and the 
percentage of calories relative to the total energy intake (F(1,9202) = 12997.728, p = 0.0001, η2p 

= 0.585). In the subgroup of alcohol consumers (Table 1), the mean alcohol intake was 69.22 
± 2.18 grams (range: 15–678 g), contributing with 484.62 kcal (range: 105–4793.46 kcal), 
which corresponds to 16.86% of the total energy intake (range: 2.36–69.64%). According 
to our cut-off criterium, there were 11.6% (n = 1073) of daily alcohol consumers in the 
whole ELANS sample. The non-consumers group (88.4%) comprised 6209 participants 
with 0 g of alcohol consumption, 1484 participants consuming between 0.005 and 1 g, and 
452 participants consuming between >1 g and <15 g. Within the consumer's groups, the 
consumption of alcohol beverages was distributed as follows: beer 803 persons, wine 194 
persons, spirits 176 persons, and cocktails 53 persons. Although most participants drank 
more than one type of alcoholic beverages, there were more exclusive beer drinkers (83%) 
than those drinking only spirits (53%), cocktails (38%), and wine (27%).  

The distribution of alcohol consumers and non-consumers differed significantly 
throughout the different sociodemographic variables, as shown in Table 1. There were 
differences in the distribution of consumers among countries (χ2(7,9218) = 308.068, p = 0.0001), 



Int. J. Environ. Res. Public Health 2021, 18, x  7 of 19 
 

 

with Argentine (22.5%), Brazil (16.2%), and Chile (13%) having a percentage of consumer’s 
over 10% of the country sample. In contrast, Peru (7.5%), Venezuela (7.4%), and Ecuador 
(4.1%) had the lowest amount of alcohol consumers. Regarding the alcohol consumption, 
there was a main effect of Country (i.e., grams, calories, and percentage of calories: all p-
values < 0.0001; η2p = 0.064–0.098) and an interaction Country x Subgroups (i.e., grams, 
calories, and percentage of calories: all p-values < 0.0001; η2p = 0.063–0.098). Specifically, in 
the subgroup of consumers, Ecuador showed the highest alcohol intake in grams and cal-
ories, which were higher than those of Argentine, Chile, and Costa Rica (Bonferroni, all p-
values < 0.05). The second highest consumption (e.g., grams and calories) was detected in 
Venezuela, whereas the lowest consumption was observed in Argentine and Chile (Bon-
ferroni, all p-values < 0.05). When comparing the percentages of alcohol calories, Vene-
zuela and Brazil showed the highest proportion of calories derived from alcohol consump-
tion, which was higher than that in Argentine, Chile, and Peru (Bonferroni, all p-values < 
0.05). The lowest percentage of alcohol calories was observed in Argentine, which differed 
from all other countries except Chile and Peru (Bonferroni, all p-values < 0.05).  

Regarding the other sociodemographic variables (Table 1), there were sex differences 
in the number of alcohol consumers, with men representing 68.3% of the consumer's sam-
ple (χ2(1,9218) = 204.175, p = 0.0001). In terms of alcohol intake, there was a main effect of Sex 
(i.e., grams, calories, and percentage of calories: all p-values < 0.0001; η2p = 0.010) and an 
interaction Sex x Subgroups (i.e., grams, calories: all p-values < 0.0001; η2p = 0.010) for 
grams and calories of alcohol, but not for its percentage. In the total sample, but especially 
in the subgroups of consumers, men consumed more alcohol than women. In addition, 
there were age differences (χ2(3,9218) = 65.667, p = 0.0001) in the proportion of alcohol con-
sumers in the whole sample, with the largest percentages of consumers (42.4%) being 
within 20–34 years, followed by those in the intervals of 30–49 years (31.3%) and 50–65 
years (20.8%). Concerning the alcohol consumption, there was a main effect of Age (i.e., 
grams, calories, and percentage of calories: all p-values < 0.0001; η2p = 0.004–0.010) and an 
interaction Age x Subgroups (i.e., grams and calories and percentage of calories: all p-
values < 0.0001; η2p = 0.004–0.010). In the whole sample, but especially in the alcohol con-
sumers, the alcohol intake was almost the same in all age intervals excepting in the 50–65 
age, in which both alcohol grams and calories were lower compared with all previous age 
intervals (Bonferroni, all p-values < 0.05). Regarding the percentage of alcohol calories, it 
was lower in the age of 15–19 years as compared with the following two age intervals 
(Bonferroni, all p-values < 0.05). Finally, the proportion of subjects consuming alcohol var-
ied according to the socioeconomic status (SES) (χ2(2,9218) = 774.257, p = 0.0001). The large 
percentage of consumers were in the low (48.6%) and middle SES (42.3%), with only 9.1% 
of consumers belonging to the high SES. There were also differences in the alcohol intake 
with a main effect of SES (i.e., grams, calories, and percentage of calories: all p-values < 
0.0001; η2p = 0.016–0.022) and an interaction SES x Subgroups (i.e., grams, calories, and 
percentage of calories: all p-values < 0.0001; η2p = 0.009–0.014). In the subgroup of consum-
ers, the participants in the low SES consumed more grams that corresponded to more net 
calories and a higher percentage of calories relative to the total energy intake as compared 
with the middle and high SES (Bonferroni, all p-values < 0.005), which did not differ to 
each other. 

3.2. Anthropometric Parameters 
As shown in Table 2, anthropometric parameters were compared between consumers 

and non-consumers after controlling by country, age, and sex as those factors have their 
own impact on body composition and weight. Consumers had higher body weight (F(1,9212) 
= 10.614, p = 0.001, η2p = 0.001), neck (F(1, 9212) = 10.856, p = 0.001, η2p = 0.001), hips (F(1,9212) = 
4.771, p = 0.029, η2p = 0.001), and waist circumferences (F(1,9212) = 34.548 p = 0.0001, η2p = 
0.004), with no differences on BMI, although it was descriptively higher in consumers. The 
analysis of the BMI categories revealed no significant differences in the proportion of sub-
jects within each BMI category (data not shown). However, within the subgroup of 



Int. J. Environ. Res. Public Health 2021, 18, x  8 of 19 
 

 

consumers we found differences in the alcohol intake (grams and calories), especially 
when comparing the participants with normal weight versus those with morbid obesity 
(all p-values < 0.049; η2p = 0.005) (Table 3).  

Table 2. Anthropometric variables between consumers and non-consumers of alcohol. 

 Non-Consumers Consumers 
Anthropometric Variables Mean SEM Mean SEM 
Neck circumference (cm) 35.56 0.40 35.95 0.11 
Waist circumference (cm) 88.12 0.16 89.35 0.45 
Hip circumference (cm) 100.29 0.13 101.12 0.36 
Weight (Kg) 71.57 0.18 73.29 0.49 
Body mass index (Kg/m2) 26.93 0.06 27.17 0.18 
The mean and the standard error of the mean (SEM) were estimated based on multivariate vari-
ance analyses after controlling by country, age, and sex. See main text for details. 

Table 3. Alcohol intake among body mass index (BMI) levels within the group of alcohol consumers. 

 Alcohol Consumption (g)/day Energy from Alcohol (Kcal)/day Energy from Alcohol (%)/day 
BMI Levels Mean SEM Mean SEM Mean SEM 
Normal weight 67.08 3.45 469.68 24.18 16.16 0.56 
Overweight 67.20 3.42 470.42 23.95 16.83 0.56 
Obese 74.64 4.87 522.67 34.15 18.05 0.79 
Morbid obesity 98.72 15.61 691.00 109.43 19.97 2.53 

Grams of alcohol (g). Kilocalories derived from alcohol (Kcal). The mean and the standard error of the mean (SEM) were 
estimated based on multivariate variance analyses after controlling by country, age, and sex. See main text for details. 

3.3. Consumption of Kilocalories, Macronutrients, and Food Groups 
The food consumption parameters are shown in Table 4. After controlling by country, 

age, and sex, we found that consumers exhibited a higher energy intake (F(1,9212) = 1080.508, 
p = 0.0001, η2p = 0.105), carbohydrates (F(1,9212) = 30.055, p = 0.0001, η2p = 0.003), fats (F(1,9212) = 
57.835, p = 0.0001, η2p = 0.006), and proteins (F(1,9212) = 78.317, p = 0.0001, η2p = 0.008). When 
analyzing the percentage of calories derived from macronutrients, we found that consum-
ers obtained less calories from carbohydrates (F(1,9212) = 1747.413, p = 0.0001, η2p = 0.159), 
proteins (F(1,9212) = 701.275, p = 0.0001, η2p = 0.071), and fats (F(1,9212) = 550.686, p = 0.0001, η2p 

= 0.056), but obtained on average 16.88% ± 0.35 calories from alcohol that non-consumers 
did not obtain (0.10% ± 0.001. Regarding the food groups, we ranked them according to 
the effect size (i.e., percentage of variance explained by the alcohol intake) to highlight the 
eating pattern that differentiates the groups the most. Consumers ate a greater amount of 
some unhealthy food groups such as processed meat (F(1,9213) = 62.248, p = 0.0001, η2p = 0.007) 
and read meat (F(1,9213) = 58.057, p = 0.0001, η2p = 0.006). Although not significant, consumers 
also had a descriptively higher intake of SSB and added sugar. In contrast, consumers ate 
fewer of the healthy foods such as dairy products (F(1,9213) = 42.620, p = 0.0001, η2p = 0.005), 
fruits (F(1,9213) = 32.308, p = 0.0001, η2p = 0.003), fiber (F(1,9213) = 26.494, p = 0.0001, η2p = 0.003), 
whole grains (F(1,9213) = 14.112, p = 0.001, η2p = 0.002), and legumes (F(1,9213) = 10.084, p = 0.0001, 
η2p = 0.001). No significant differences were detected for fish, vegetables, and nuts. 

Table 4. Energy, macronutrients, and food groups according to alcohol consumption. 

 Non-Consumers Consumers 
 Mean SEM Mean SEM 
Energy (Kcal) 1980.96 6.39 2611.39 17.97 
Carbohydrates (g) 270.58 0.04 286.02 2.64 
Fats (g) 65.21 0.25 70.96 0.71 



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Protein (g) 78.04 0.24 84.41 0.68 
Alcohol (g) 0.29 0.01 69.22 2.18 
Carbohydrates (%) 54.42 0.08 44.63 0.22 
Fats (%) 29.58 0.18 25.03 0.18 
Protein (%) 16.01 0.03 13.40 0.09 
Alcohol (%) 0.10 0.00 16.86 0.35 
Wholegrains (g) 9.06 0.18 7.05 0.50 
Fruits (g) 76.24 0.82 62.34 2.29 
Vegetables (g) 105.48 0.59 106.93 1.65 
Fish and seafood (g) 18.30 0.23 18.85 0.64 
Nuts & seeds (g) 2.02 0.10 2.30 0.28 
Beans & legumes (g) 37.81 0.42 33.86 1.17 
Dairy products (g) 96.60 1.05 76.06 2.95 
Sugar sweetened beverages (g) 677.59 5.12 683.86 14.39 
Red meat (g) 63.45 0.38 72.21 1.07 
Processed meat (g) 18.96 0.78 23.17 0.50 
Added sugar (g) 65.30 0.40 67.13 1.10 
Fiber (g) 15.87 0.06 14.94 0.17 
Grams (g). Kilocalories (Kcal). The percentage from total energy intake (%). The mean and the 
standard error of the mean (SEM) were estimated based on multivariate variance analyses after 
controlling by country, age, and sex. See main text for details. 

3.4. Micronutrient Adequacy Ratio (NAR) and Diet Quality Indicators 
The NAR values were compared between consumers and non-consumers after con-

trolling by country, sex, age, and especially total energy intake because NAR values 
strongly depend on the amount of food consumed, and alcohol consumers had a higher 
caloric intake than non-consumers. In fact, all micronutrients’ intake correlated positively 
with energy intake irrespective of alcohol consumption, with Pearson’s correlation coeffi-
cients ranging from 0.038 to 0.567 (all p-values < 0.0001) (Table 5). In general terms, all 
NAR values were significantly lower in alcohol consumers (all p-values < 0.05). According 
to the effect size, the largest group differences were observed for vitamins E, A, and D, 
with eta square coefficients (η2p) ranging from 0.037 to 0.032, respectively. Other important 
differences were obtained for zinc, magnesium, vitamin C, and iron (η2p = 0.019–0.012). 
Despite finding differences for all NAR values, the MAR score did not differ between 
groups, nor did the DQS. Significant differences were only observed for the DDS, which 
was lower in consumers (F(1,9212) = 100.999, p = 0.0001, η2p = 0.011). 

Table 5. Nutrients Adequacy Ratio according to alcohol consumption. 

 Non-Consumers Consumers 
 Mean SEM Mean SEM 
Calcium 0.713 0.005 0.585 0.014 
Iron 0.991 0.001 0.971 0.002 
Vitamin D 0.368 0.002 0.254 0.006 
Vitamin A 0.861 0.002 0.744 0.006 
Vitamin C 0.865 0.002 0.779 0.007 
Vitamin E 0.034 0.000 0.024 0.001 
Thiamine 0.993 0.001 0.077 0.002 
Riboflavin 0.990 0.001 0.981 0.002 
Niacin 0.997 0.000 0.995 0.001 
Pyridoxin 0.973 0.001 0.964 0.003 
Cobalamin 0.968 0.001 0.978 0.002 



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Phosphorous 0.986 0.001 0.976 0.002 
Magnesium 0.771 0.001 0.714 0.004 
Zinc 0.970 0.001 0.931 0.003 
Copper 0.990 0.001 0.971 0.002 
Selenium 0.999 0.000 0.998 0.001 
Mean Adequacy Ratio 0.814 0.001 0.816 0.002 
Diet quality score 63.02 0.10 52.88 0.30 
Dietary diversity 4.84 0.15 4.38 0.43 
Micronutrient’s adequacy ratio (Mean consumption/Estimated Average Requirements (EAR)). The 
mean and the standard error of the mean (SEM) were estimated based on multivariate variance 
analyses after controlling by country, age, total energy intake, and sex. See main text for details. 

3.5. Classification of Consumers According to Their Intake of Alcohol in Grams 
We selected the grams of alcohol intake to classify in quartiles (Q) the participants of 

the subgroup of consumers as shown in Table 6. This classification allows us to identify 
the breaking points where alcohol consumption started to bestow risks of micronutrients 
inadequacy compared to non-consumers. We ranked the results to highlight the minimal 
number of beverages required to observe significant differences compared to non-con-
sumers (e.g., 0 beverages).  

Table 6. Energy, macronutrients, and food groups consumption according to alcohol consumption quartiles. 

 
Consumers (N = 1073) 

Q0 (N = 8145) 
0 Beverage 

Q1 (N = 268) 
1 Beverage 

Q2 (N = 268) 
2–3 Beverages 

Q3 (N = 268) 
4–6 Beverages 

Q4 (N = 269) 
>10 Beverages 

 Mean SEM Mean SEM Mean SEM Mean SEM Mean SEM 
Energy (Kcal) 1981.3 6.11 2195.7 33.83 2316.9 33.75 2566.4 33.83 3339.1 33.69 
Carbohydrates (g) 270.59 0.93 267.51 5.18 272.63 5.17 294.11 5.18 309.20 5.16 
Fats (g) 65.21 0.25 72.59 1.39 71.91 1.39 70.34 1.39 68.94 1.39 
Proteins (g) 78.04 0.24 81.69 1.33 83.37 1.32 83.82 1.33 88.66 1.32 
Alcohol (g) 0.29 0.01 20.64 0.21 34.89 0.32 60.01 0.70 160.94 5.50 
Carbohydrates (%) 54.41 0.42 48.53 0.42 46.85 0.42 45.33 0.42 37.86 0.42 
Fats (%) 29.58 0.06 29.41 0.35 27.51 0.35 24.35 0.35 18.91 0.35 
Proteins (%) 16.00 0.03 15.00 0.18 14.50 0.18 13.17 0.18 10.93 0.18 
Alcohol (%) 0.10 0.01 7.03 0.13 11.11 0.21 17.08 0.31 32.16 0.64 
Wholegrains 9.07 0.18 8.58 0.99 7.69 0.99 6.51 099 542 0.99 
Fruits 76.24 0.82 73.35 4.51 62.67 4.50 64.17 451 4937 4.50 
Vegetables 105.48 0.50 116.62 3.26 108.99 3.26 105.63 326 96.63 3.25 
Fish and seafood 18.29 0.23 17.58 1.27 18.33 1.26 17.87 126 21.53 1.25 
Nuts and seeds 2.02 0.10 1.94 0.55 2.43 0.55 2.95 055 1.88 0.55 
Beans and legumes 37.81 0.42 29.40 2.30 29.57 2.29 34.68 229 41.68 2.29 
Dairy products 96.59 1.05 93.55 5.81 82.43 5.79 68.98 580 59.52 5.78 
Sugar sweetened beverages 677.58 5.12 672.05 28.34 688.28 28.28 760.48 280.30 615.47 28.24 
Red meat 63.46 0.38 71.02 2.11 69.09 2.12 70.31 2.12 78.36 2.11 
Processed meats 18.97 0.18 22.96 0.98 23.02 0.98 20.79 0.98 25.87 0.98 
Added sugar 65.30 0.40 66.46 2.17 67.00 2.17 72.78 2.17 62.33 2.17 
Fiber 15.87 0.06 14.98 0.33 14.88 0.33 15.24 0.33 14.65 0.33 

Grams (g). Kilocalories (Kcal). Percentage from total energy intake (%). Grams of alcohol were split into quartiles (Q) and 
the mean values of each quartile was divided by 15 to obtain the equivalent number of beverages per day. The mean and 
the standard error of the mean (SEM) were estimated based on multivariate variance analyses after controlling by country, 
age, and sex. See main text for details. 



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For the anthropometric parameters (Table 7) to differ from non-consumers only the equiv-
alent of 1 alcohol beverage was enough to increase body weight (F(4,9198) = 11.857, p = 0.0001, η2p = 
0.005; Q0 vs. Q1–4). For the neck and waist circumferences more than 4 (F(4,9198) = 29.120, p = 0.0001, 
η2p = 0.013; Q0 vs. Q3–4) and 10 beverages (F(4,9198) = 3.160, p = 0.013, η2p = 0.001; Q0 vs. Q4) were 
rather needed to increase, respectively. As shown in (Table 6), the total energy intake (F(4,9209) = 
467.438, p = 0.0001, η2p = 0.169; Q0 vs. Q1–4) increased with the equivalent of only 1 alcohol bev-
erage as well as the reduction in the percentages of carbohydrates (F(4,9209) = 548.750, p = 0.0001, 
η2p = 0.192; Q0 vs. Q1–4) and proteins (F(4,9209) = 259.539, p = 0.0001, η2p = 0.101; Q0 vs. Q1–4). The 
percentage of energy from fats consumed reduced after 2 or more beverages (F(4,9209) = 277.208, p 
= 0.0001, η2p = 0.107; Q0 vs. Q2–4). The intake of proteins and carbohydrates increased after 2 or 
more beverages (F(4,9209) = 23.457, p = 0.0001, η2p = 0.010; Q0 vs. Q2-Q4) and 4 or more alcoholic 
beverages (F(4,9209) = 18.077, p = 0.0001, η2p = 0.008; Q0 vs. Q3-Q4), respectively. Regarding the food 
groups (Table 6), we found that the equivalent of only 1 alcoholic beverage was enough to in-
crease the consumption of red meat (F(4,9210) = 17.490, p = 0.0001, η2p = 0.008; Q0 vs. Q1–4) and 
decrease the consumption of fiber (F(4,9210) = 7.030, p = 0.0001, η2p = 0.003; Q0 vs. Q1–4). For fruits 
(F(4,9210) = 11.429, p = 0.0001, η2p = 0.005; Q0 vs. Q2–4) and dairy products (F(4,9210) = 15.708, p = 0.0001, 
η2p = 0.007; Q0 vs. Q2–4) 2 or more alcoholic beverages already produced a reduction in the con-
sumption, while for whole grains and vegetables the reduction appeared after 4 (F(4,9210) = 4.999, 
p = 0.0001, η2p = 0.002; Q0 vs. Q3–4) and 10 beverages (F(4,9210) = 5.060, p = 0.0001, η2p = 0.002; Q0 vs. 
Q4), respectively. No significant differences were observed in the consumption of fish and sea-
food and nuts and seeds. 

Table 7. Anthropometric measurements according to alcohol consumption quartiles. 

 Alcoholic Consumers (N = 1073) 

 Q0 (N = 8145) 
0 Beverage 

Q1 (N = 268) 
1 Beverage 

Q2 (N = 268) 
2–3 Beverages 

Q3 (N = 268) 
4–6 Beverages 

Q4 (N = 269) 
>10 Beverages 

 Mean SEM Mean SEM Mean SEM Mean SEM Mean SEM 
Neck circumference (cm) 35.47 0.04 36.28 0.24 36.11 0.24 36.92 0.23 37.58 0.24 
Waist circumference (cm) 88.13 0.17 88.27 0.81 88.71 0.81 89.38 0.81 90.75 0.80 
Hip circumference (cm) 100.42 0.13 99.65 0.69 100.67 0.69 100.10 0.69 100.08 0.69 
Weight (kg) 71.37 0.18 73.37 0.98 74.60 0.98 74.68 0.98 76.48 0.98 
Body Mass Index (Kg/m2) 26.99 0.06 26.42 0.33 26.60 0.33 26.87 0.33 27.15 0.33 

Grams of alcohol were split into quartiles (Q) and the mean values of each quartile was divided by 15 to obtain the equiv-
alent number of beverages per day. The mean and the standard error of the mean (SEM) were estimated based on multi-
variate variance analyses after controlling by country, age, and sex. See main text for details. 

The NAR values were inversely related to the alcohol consumption (Table 8), with 
significant differences being detected for all micronutrients analyzed. Magnesium (F(4,9209) 
= 83.247, p = 0.0001, η2p = 0.035; Q0 vs. Q1–4), and vitamin C (F(4,9209) = 47.581, p = 0.0001, η2p 

= 0.020; Q0 vs. Q1–4) decreased only after 1 beverage. Vitamin E (F(4,9209) = 208.097, p = 
0.0001, η2p = 0.083; Q0 vs. Q2–4), vitamin A (F(4,9209) = 161.864, p = 0.0001, η2p = 0.066; Q0 vs. 
Q2–4), vitamin D (F(4,9209) = 157.443, p = 0.0001, η2p = 0.064; Q0 vs. Q2–4), zinc (F(4,9209) = 93.626, 
p = 0.0001, η2p = 0.039; Q0 vs. Q2–4), iron (F(4,9209) = 51.266, p = 0.0001, η2p = 0.022; Q0 vs. Q2–
4), copper (F(4,9209) = 40.965, p = 0.0001, η2p = 0.017; Q0 vs. Q2–4), and thiamin (F(4,9209) = 38.213, 
p = 0.0001, η2p = 0.016; Q0 vs. Q2–4) showed a reduction after 2 or more beverages. For 
calcium (F(4,9209) = 61.718, p = 0.0001, η2p = 0.026; Q0 vs. Q2–4) and riboflavin (F(4,9209) = 21.675, 
p = 0.0001, η2p = 0.009; Q0 vs. Q2–4) 4 or mores beverages produced a reduction in the 
values, whereas for pyridoxin (F(4,9209) = 24.141, p = 0.0001, η2p = 0.010; Q0 vs. Q4), phospho-
rus (F(4,9209) = 18.821, p = 0.0001, η2p = 0.008; Q0 vs. Q4), cobalamin (F(4,9209) = 10.545, p = 0.0001, 
η2p = 0.005; Q0 vs. Q4), niacin (F(4,9209) = 9.368, p = 0.0001, η2p = 0.004; Q0 vs. Q4), and selenium 
(F(4,9209) = 4.123, p = 0.002, η2p = 0.002; Q0 vs. Q4) 10 or more beverages were sufficient to 



Int. J. Environ. Res. Public Health 2021, 18, x  12 of 19 
 

 

produce a reduction. Finally, the DDS (F(4,9209) = 52.730, p = 0.0001, η2p = 0.022; Q0 vs. Q3–4) 
reduced after 4 or more beverages. 

Table 8. Nutrients Adequacy Ratio and Dietary Diversity Score according to alcohol consumption quartiles. 

  Alcohol Consumers (N = 1073) 
 Q0 (N = 8145) 

0 Beverage 
Q1 (N = 268) 
1 Beverage 

Q2 (N = 268) 
2–3 Beverages 

Q3 (N = 268) 
4–6 Beverages 

Q4 (N = 269) 
>10 Beverages 

 Mean SE Mean SE Mean SE Mean SE Mean SE 
Calcium 0.715 0.005 0.755 0.026 0.684 0.026 0.549 0.026 0.296 0.028 
Iron 0.991 0.001 0.990 0.003 0.98 0.003 0.963 0.003 0.947 0.003 
Vitamin D 0.369 0.002 0.356 0.001 0.298 0.011 0.241 0.011 0.086 0.012 
Vitamin A 0.862 0.002 0.837 0.011 0.798 0.011 0.74 0.011 0.567 0.012 
Vitamin C 0.865 0.002 0.828 0.013 0.794 0.013 0.771 0.013 0.705 0.014 
Vitamin E 0.034 0.000 0.032 0.001 0.03 0.001 0.023 0.001 0.006 0.001 
Thiamine 0.993 0.001 0.991 0.003 0.982 0.003 0.971 0.003 0.960 0.003 
Riboflavin 0.990 0.001 0.993 0.003 0.987 0.003 0.981 0.003 0.959 0.003 
Niacin 0.997 0.000 0.999 0.002 0.998 0.002 0.995 0.002 0.985 0.002 
Pyridoxin 0.973 0.005 0.985 0.005 0.975 0.005 0.964 0.005 0.924 0.005 
Cobalamin 0.986 0.001 0.990 0.005 0.984 0.005 0.980 0.005 0.054 0.005 
Phosphorous 0.986 0.001 0.987 0.004 0.987 0.004 0.977 0.004 0.95 0.004 
Magnesium 0.772 0.007 0.743 0.007 0.741 0.007 0.721 0.008 0.631 0.008 
Zinc 0.970 0.001 0.968 0.005 0.946 0.005 0.924 0.005 0.874 0.005 
Copper 0.990 0.001 0.987 0.003 0.978 0.003 0.967 0.003 0.948 0.004 
Selenium 0.999 0.000 1.000 0.001 0.999 0.001 0.998 0.001 0.994 0.001 
Dietary Diversity Score 4.847 0.014 4.725 0.079 4.63 0.079 2.373 0.080 3.647 0.085 

Micronutrient’s adequacy ratio (Mean consumption/Estimated Average Requirements (EAR)). Grams of alcohol were split 
into quartiles (Q) and the mean values of each quartile was divided by 15 to obtain the equivalent number of beverages 
per day. The mean and the standard error of the mean (SEM) were estimated based on multivariate variance analyses after 
controlling by country, age, total energy intake, and sex. See main text for details. 

4. Discussion 
The main goals of the present study were first, describing the alcohol consumption 

of the ELANS sample, and second and foremost, estimating the role of alcohol consump-
tion as an obesogenic factor affecting anthropometric parameters of obesity and nutri-
tional status, which increase the risk of a myriad of health problems. To our knowledge, 
this is the first study evaluating alcohol consumption in relation to sociodemographic var-
iables, dietary habits, and weight status among a large sample of the Latin American pop-
ulation.  

In average, 11.6% of the population consumed at least one alcoholic beverage daily. 
Although the number of alcoholic drinks per day is not a sufficient criterium for diagnos-
ing an alcohol use disorder, the consumption of more than 4 drinks per day (5.83%) con-
stitute a pattern of heavy drinking that confer a higher risk for alcoholism and other psy-
chiatric (e.g., neurocognitive, anxiety, and mood disorders) and non-psychiatric health 
problems (peripheric neuropathies, metabolic syndrome, obesity, and cardiovascular dis-
eases). Those drinking 10 or more beverages per day are very likely to meet the criteria 
for alcohol use disorders (2.92%).  

The pattern of alcohol consumption varied according to country, sex, age, and SES 
variables. In the whole sample, the alcohol drinkers consumed in average 4.6 beverages 
per day, although it ranged from 3.1 in Argentine and 7.7 in Ecuador, which showed the 
lowest and the highest number of alcohol drinkers, respectively. According to that num-
ber of alcoholic beverages per day, it is not surprising that Latin America and the Carib-
bean had the third-highest (6.7%) percentages of the population that met the criteria for 



Int. J. Environ. Res. Public Health 2021, 18, x  13 of 19 
 

 

an alcohol use disorder (AUD), surpassed only by North America (8.1%) and Europe 
(8.3%) [32]. Within Latin-American countries, Ecuador has the highest prevalence of AUD, 
which coincides with our data of Ecuador having the highest proportion of heavy drink-
ers.  

On the other hand, we found a higher frequency of men drinkers compared to 
women (2.16:1 ratio), in agreement with previous studies consistently describing almost 
the same trend [6,15]. Although alcohol consumption has been progressively increasing 
in young women from middle and high SES [32], the gender gap in the proportion of 
drinkers is still present in Latin-American countries. This difference may be attributable 
to social constructs and gender roles, which have normalized alcohol consumption in men 
while have disapproved it in women as it has been considered as an immoral and unfem-
inine behavior [5,33]. In the subgroup of alcohol consumers, nevertheless, the differences 
between men and women in the number of alcoholic beverages consumed per day are 
rather small (5 versus 3.9 beverages), suggesting that the drinking patterns of the two 
genders are becoming more alike, especially in women consuming alcohol daily, who 
showed a moderate drinking habit. Interestingly, if alcohol consumption (e.g., grams of 
the number of beverages) is adjusted by body weight (e.g., kg), significant differences 
were no longer observed in these parameters, suggesting that women and men consumed 
almost the same amount of alcohol according to their body composition (data not shown). 
In the Americas, a small number of beverages consumed per day in men, and especially 
in women (4.3 versus 1.4), have been reported [32], which may be due to the use of a 
stricter cut-off criterion (e.g.,15 g/day) in our study that allowed us to describe only cur-
rent and frequent consumers that have drunk at least one 12-ounce beverage with 5% of 
alcohol per day. Nor was there information in that study to estimate alcohol consumption 
relative to body weight, thus that the real dimensions of those gender differences in alco-
hol consumption are still unknown. 

Regarding age, we observed the highest frequency of current alcohol drinkers in the 
range of 20–39 years, in agreement with previous reports [6,34-36]. However, in other 
world regions, such as in Nepal (5), higher odds ratios for alcohol consumption were ob-
served in older adults (44–65 years old) belonging to disadvantaged ethnic groups, high-
lighting the geographic, cultural, and sociodemographic variations in the pattern of alco-
hol consumption worldwide. It is worth noting that there was 5.5% of adolescents or 
barely legal young adults (i.e., 15–19 years old) that consumed at least one alcoholic drink 
daily in our study. These data are not something to be taken lightly considering the age 
of the consumers. Furthermore, 51% of those young alcohol consumers were in the low 
SES, and only 10% were in the high SES, indicating that this population is at higher risk 
for developing an AUS due to its alcohol consumption pattern and its socioeconomic vul-
nerabilities. In fact, an early onset of alcohol use can shape the course of a problematic 
drinking pattern that substantially increases the risk for an AUS [37].  

In regards to the latter, we found that there were more alcohol consumers in low SES 
irrespective of age, which also had the highest alcohol consumption in agreement with 
other studies [4,38,39]. The International Alcohol Study [42] demonstrated that drinkers 
below the poverty line across seven countries had a greater probability of being heavy 
drinkers, suggesting that the burden of heavier alcohol consumption is falling on people 
at the most vulnerable end of the socioeconomic spectrum. In contrast, other studies in 
Danish samples [4,41] found no significant role of income in determining drinking pat-
terns. Data from more than 101,000 men and women from 33 countries of the GENACIS 
study found that higher SES was positively associated with drinking status and that a 
higher country SES was associated with a higher proportion of drinkers [42]. However, it 
has been argued that even when people in the high SES consume similar or greater 
amounts of alcohol than those in the low SES, the less socioeconomically-disadvantaged 
individuals used to bear a disproportionate burden of negative alcohol-related conse-
quences [39]. In addition, alcoholic beverages are expensive compared with traditional 



Int. J. Environ. Res. Public Health 2021, 18, x  14 of 19 
 

 

foods, which could lead to a reduction in healthy food purchases in those with limited 
income. 

Previous ELANS findings have shown that poorer socioeconomic conditions were 
associated with less diet quality and diversity as well as fewer micronutrients adequacy 
ratios [43]. High alcohol intake is associated with less healthy dietary patterns [11]. 
Breslow et al. [44] found that the Healthy Eating Index-2005 scores significantly decreased 
with the consumption of alcoholic beverages based on the data from the US National Exa-
mination Survey (1999–2006). Even though we assessed diet quality using another ap-
proach, we have previously reported that diet quality in ELANS participants is poor in 
general [28]. In our current study, no significant differences in that score were observed 
between alcohol consumers and non-consumers. When assessing dietary diversity as a 
dimension of diet quality, we found that DDS decreased from 4.84 in non-alcohol con-
sumers to 3.64 in alcohol-consumers in the fourth quartile (>10 beverages per day). Dietary 
diversity is widely recognized as a fundamental characteristic of a healthy diet [29], and 
monotonous diets have been related to micronutrients malnutrition in previous studies 
[31,45,46] and may be associated with the lower NAR scores observed among alcohol con-
sumers in the present study.  

In the current study, we found significant differences in food consumption and nu-
trient intake between alcohol drinkers and non-drinkers, which were proportionally 
higher according to the number of beverages consumed per day. In general terms, diet 
quality worsened as alcohol consumption increased, in agreement with previous research 
[47]. Energy intake was higher in alcohol consumers. In those consuming 10 or more bev-
erages per day, the energy intake was 1.69-folds higher than that in non-consumers, sup-
porting the association between the amount of alcohol consumed and the risk of surpas-
sing the daily energy requirements that increase the likelihood of gaining weight. This 
also suggests that energy from alcoholic beverages is not well compensated by eating less 
food or substituting it for other foods, as mentioned elsewhere [11,48,49]. In heavy drink-
ers, alcohol consumption can represent up to 60% of total energy intake, which may lead 
to nutritional deficiencies and metabolic dysregulation, such as changes in the metabolism 
of carbohydrates and fiber, loss of protein mass, and the derangement of liver function 
[50]. Our data showed that alcohol drinkers consumed more carbohydrates, proteins, and 
fats than nondrinkers, but obtained significantly less energy from those macronutrients 
relative to the total energy intake. This proved to be even more true for heavy drinkers 
that obtained substantially less energy from macronutrients and more from alcohol. In 
contrast, there is evidence showing differences in the energy obtained from proteins and 
fats but no from carbohydrates in alcohol consumers [49], which highlights the variations 
in dietary patterns observed among countries.  

Regarding food groups, we found that alcohol consumers, and especially moderate 
and heavy drinkers, consumed more red meat and less fiber, fruits, dairy products, whole 
grains, and vegetables. In line with our results, previous research has found lower intakes 
of fiber, fruits, and dairy products in alcohol drinkers and higher intakes of animal prod-
ucts as fish, poultry, meats, and animal fats [11,48]. The research developed in the Finish 
population found that moderate drinkers have higher energy intake from fats and pro-
teins, lower consumption of fiber, dairy products, and fruits but higher intake of vitamin 
D, compared with non-drinkers [49,50].  

Previous studies described that diet quality is deficient in alcohol drinkers [11,31,46]. 
We found that all NARs were significantly lower in alcohol consumers, with the NAR 
scores decreasing proportionally with the number of alcoholic drinks consumed per day. 
This effect of alcohol consumption on NAR values can be understood by two non-mutu-
ally exclusive explanations. First, alcoholic beverages provide a considerable number of 
calories but contain few or no micronutrients; and second, heavy alcohol consumption 
can lead to vitamins deficiency by reducing their absorption, altering their metabolism, or 
increasing their loss [51]. The largest shortfalls were observed for vitamins E, A, and D 
after consuming two or more alcoholic beverages per day. It is worth noting that the NAR 



Int. J. Environ. Res. Public Health 2021, 18, x  15 of 19 
 

 

scores for vitamin E were already low for the whole ELANS’ sample, but in alcohol con-
sumers, the vitamin E levels were the lowest, meaning that in this population, oxidative 
stress from alcohol consumption and other sources may produce greater damage due to 
a weakened antioxidant system [52]. Besides energy and protein deficiency, chronic alco-
holism has been associated with micronutrients inadequacy, including vitamin D, vitamin 
E, zinc, iron, and magnesium shortfalls, which can be caused by malabsorption due to 
cholestasis, pancreatic insufficiency, poor dietary intake, or metabolism impairments 
[52,53]. Regarding vitamin A, it has been reported that alcohol intake can alter retinoids 
homeostasis leading to a depletion of hepatic retinyl esters and retinol levels in chronic 
alcohol consumers, which can be linked to the development of alcoholic liver disease [57]. 
In addition, low serum vitamin D levels in alcohol users have been associated with cardi-
ovascular diseases, hypertension, diabetes mellitus, metabolic syndrome, cancer, depres-
sion, schizophrenia, and other psychotic disorders [53]. Remarkably, for magnesium and 
vitamin C, only one alcoholic drink was enough to produce a reduction in the NAR levels 
compared to non-consumers. Two or more daily drinks already reduced the NAR scores 
for zinc, iron, copper, and thiamin, whereas differences for other micronutrients such as 
calcium and riboflavin could only be observed after 10 or more daily alcoholic beverages. 
Chronic alcohol consumption is known to decrease the absorption of thiamine and the 
activation of thiamine pyrophosphate, which acts as a coenzyme for many enzyme reac-
tions in the metabolism of carbohydrates and amino acids and the subsequent production 
of energy. Impairment of that process in the nervous system is strongly associated with 
severe neurological conditions such as Wernicke–Korsakoff syndrome, alcoholic periph-
eral neuropathies, and the Marchiafava–Bignami disease [55]. Heavy drinkers have been 
found to have lower intake of several nutrients, including calcium and iron compared to 
non-drinkers [50] and may have less favorable micronutrients status compared with mod-
erate and non-drinkers. Our findings should be interpreted with caution as this is a cross-
sectional study that does not allow raising cause-and-effect inferences. Further studies 
exploring causal relationships between alcohol consumption and micronutrients short-
falls-induced health problems are warranted. Nevertheless, our results suggest that alco-
hol consumption might affect differentially the micronutrients status increasing the risk 
of an inadequate intake, which aggravates in heavy drinkers.  

Alcohol has been suggested to stimulate further eating, besides adding calories to the 
total energy intake that are not compensated by eating less, non-alcoholic foods [56,57]. 
Alcohol-induced food consumption could be promoted by impairing inhibitory control 
leading to an overconsumption of energy-dense foods [12]. Additionally, alcohol can in-
hibit the action of satiety hormones such as leptin or glucagon-like petide-1, while increas-
ing opioid, serotonergic, and GABAergic signaling pathways that stimulate appetite and 
potentiate the hedonic representation of foods, which reinforces cyclically the pattern of 
alcohol drinking, snacking, and binge eating [56]. Prior studies have shown a relationship 
between alcohol consumption and body mass index [48,58]. Our study demonstrated that 
body weight, waist, and neck circumference were significantly higher in alcohol consum-
ers compared with non-consumers. Furthermore, alcohol consumers with normal weight 
consumed significantly less alcohol than those with morbid obesity. When analyzing the 
number of daily beverages needed to detect differences relative to non-consumers in the 
anthropometric parameters, we found that only one alcoholic beverage per day was 
enough to produce an increase in body weight, whereas 4 and 10 daily drinks were re-
quired to observe an increase in the circumference of neck and waist, respectively. In 
agreement with our results, others have also reported that heavier drinking is positively 
associated with BMI [6], waist circumference [10,6], and a higher risk for obesity [10]. Fi-
nally, one of the major strengths of our study is having a large, multinational representa-
tive sample of urban areas of eight Latin American countries following a standardized 
methodology that allowed a better comparison among them. Although rural areas were 
not represented, it is worth mentioning that the urban areas here included corresponded 
to more than 60% of the total Latin American population. Contrary to most studies of 



Int. J. Environ. Res. Public Health 2021, 18, x  16 of 19 
 

 

alcohol consumption, we also included a detailed analysis of nutritional and dietary pat-
terns and anthropometric parameters of obesity. This study also had limitations as our 
results are based on two 24 h recalls of dietary intake. However, in order to minimize that 
bias, dietary data were collected by a trained interviewer using a standardized method, 
with the usual intake being estimated with the Multiple Source method that minimizes 
intra-individual variations in food consumption. Nevertheless, further studies may assess 
separately weekend and weekday recalls of dietary intake to better represent binge drink-
ing patterns occurring at weekends.  

5. Conclusions  
The risk of alcohol consumption and its health consequences was higher in young 

and middle-aged men from low and middle SES. Alcohol consumption can be considered 
as an obesogenic factor as it increased anthropometric parameters of obesity (e.g., body 
weight, and neck, and waist circumference) and total energy intake, with macronutrients 
providing relatively less energy at expenses of the energy derived from alcohol. Alcohol 
drinkers characterized by having lower and higher consumption of healthy and unhealthy 
food groups, respectively. In addition, alcohol consumers showed an inadequate intake 
of micronutrients. All these deleterious effects of alcohol increased according to the num-
ber of alcoholic beverages consumed per day. Although it is well-known that alcohol de-
pendence can increase the risk of dementia (e.g., Wernicke–Korsakoff type) and other neu-
rocognitive disorders that are related to nutritional shortages, prevention, and treatment 
programs barely include nutritional components or evaluate the effects that alcohol and 
other drugs of abuse may have on nutritional status. To counteract those issues, we rec-
ommend capacitating public health personnel about the implications of heavy drinking 
on nutritional status and how that aggravates many health problems. In addition, it may 
be useful to implement educational programs in educative centers to provide simple but 
meaningful information at early ages about the risk of alcohol abuse and its consequences 
on the overall health, especially the effect of alcohol drinking on nutritional status. All this 
information should also be presented to decision-makers in government departments. As 
meeting micronutrients recommendations is essential to prevent chronic diseases, prem-
ature deaths, morbidity, and disability, additional efforts are required to ensure adequate 
vitamin and minerals intake in alcohol consumers. Thus, residential and medical centers 
aimed to treat drug dependence should consider including vitamins and minerals supple-
mentation and personalized nutritional programs. Finally, moderating alcohol consump-
tion is a prudent recommendation not only to reduce the risk of psychiatric, neurological, 
and cardiovascular diseases but also of obesity, metabolic syndrome, and diet-related dis-
eases.  

Supplementary Materials: The following are available online at www.mdpi.com/xxx/s1, Table S1: 
Alcohol-consumption parameters according to the sociodemographic characteristics of non-alcohol 
consumers. 

Author Contributions: Conceptualization, J.C.B., G.G., and D.Q.; data curation, J.C.B., G.G., and 
D.Q.; formal analysis, J.C.B.; investigation, J.C.B., G.G., and D.Q.; methodology, J.C.B., G.G., and 
D.Q.; supervision, M.F., I.K., and V.G.; writing—original draft, J.C.B., G.G., and D.Q.; writing—re-
view and editing, A.R., L.Y.C.S., R.L.-D., M.C.Y.G., M.R.L.-D., M.H.-C., R.M.F., A.C.B.L, G.F., and 
M.F. All authors have read and agreed to the published version of the manuscript.  

Funding: The ELANS study was supported by a scientific grant from the Coca-Cola Company (At-
lanta, GA, USA) and by the Latin American countries ILSI (International Life Science Institute) or-
ganizations for data collection. The University of Costa Rica supported the publication of this man-
uscript. The funders have no role in the study design, data collection, analysis, decision to publish, 
or preparation of this manuscript. 

Institutional Review Board Statement: The ELANS was approved by the Western Institutional Re-
view Board (#20140605) and registered in clinicaltrials.gov (n◦ NCT02226627). Local research insti-
tutes ethics review boards from each country also needed to approve the study.  



Int. J. Environ. Res. Public Health 2021, 18, x  17 of 19 
 

 

Informed Consent Statement: Written informed consent has been obtained from the patients to 
publish this paper.  

Data Availability Statement: Due to ethical and legal restrictions of the eight institutions involved, 
the data underlying this study are available upon request and must be approved by the Publishing 
Committee of ELANS. To apply for access to these data, interested researchers must submit a de-
tailed project proposal. Requests for the data can be made to the correspondence author.  

Acknowledgments: The authors would like to thank research participants and all 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, Georgina Gómez, Martha Cecilia Yépez, Rossina Gabriella 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, 
Alejandro Gerardi; Brazil: Mauro Fisberg, Ioná Zalcman Zimberg, and Natasha Aparecida Grande 
de França, Ana Carolina Leme, Gerson Ferrari and Ana Del’Arco; Chile: Attilio Rigotti, Guadalupe 
Echeverría, Leslie Landaeta, and Óscar 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 and Mó;nica Villar; Perú: Rossina Pareja, María Reyna Liria, Krysty Meza and Mellisa Abad; 
Venezuela: Marianella Herrera-Cuenca, Maritza Landaeta, Betty Méndez, Maura Vasquez, Omaira 
Rivas, Carmen Meza, Servando Ruiz, Guillermo Ramirez, 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 declared no potential conflict of interest with respect to the re-
search, authorship, and/or publication of this article. M.F. has received fees and consultancy pay-
ments from biotechnology, pharmaceutical and food and beverage companies and received fees and 
payments for consulting and financing research studies without any restrictions from government 
sources and non-profit entities. I.K. has received fees as the advisory board of Novo Nordisk. The 
rest of the authors also have no conflict of interest to declare. None of the entities mentioned had or 
have any role in the design or preparation of this manuscript. 

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