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Colombia Médica

versão On-line ISSN 1657-9534

Colomb. Med. vol.48 no.2 Cali abr./jun. 2017

 

Original articles

Population attributable fractions for colorectal cancer and red and processed meats in Colombia - a macro-simulation study

Fracción Atribuible Poblacional de carnes rojas y procesadas en cáncer colorrectal en Colombia - un estudio de macro-simulación

Esther de Vries1 

Doris C Quintero2 

Giana Henríquez-Mendoza3 

Oscar Fernando Herrán4 

1Department of Clinical Epidemiology and Biostatistics, Pontificia Universidad Javeriana. Bogotá. Colombia

2 Grupo de Estudios Epidemiológicos y Salud Pública-FCV. Fundación Cardiovascular de Colombia. Bucaramanga. Colombia

3 Subdirección de Investigaciones - Grupo Área de Salud Pública. Instituto Nacional de Cancerología. Bogotá. Colombia

4 Escuela de Nutrición y Dietética. Universidad Industrial de Santander. Bucaramanga. Colombia


Abstract:

Aim:

to estimate the population attributable risk of consumption of red and processed meat for colorectal cancer in Colombia.

Methods:

to model the expected incidence of colorectal cancer in the hypothetical situation of no red and processed meat consumption in Colombia, for the year 2010. A dynamic macrosimulation model, PREVENT 3.01, was used to integrate available cancer incidence, meat consumption prevalence and associated risk data and to evaluate the impact of eliminating red and processed meat from the Colombian diet on national colorectal cancer incidence.

Results:

Eliminating consumption of red meat altogether from the Colombian diet resulted in reductions in age-standardized colorectal cancer incidence, translating in reductions of 331 males (PAF 13%) and 297 female cases (PAF 10%). Eliminating processed meats had slightly stronger effects, with decreases of 362 males (PAF 14%) and 388 female cases (PAF 13%).

Conclusions:

A substantial proportion of the burden of colorectal cancer in Colombia can be attributed to the consumption of red and processed meat.

Keywords: Red meat; meat; processed meat; diet; risk; colorectal neoplasms; carcinogens; software; Colombia

Resumen:

Objetivo:

estimar la fracción atribuible poblacional de consumo de carne roja y procesada para el cáncer colorrectal en Colombia.

Métodos:

modelación de la incidencia esperada de cáncer colorrectal en la situación hipotética de no consumo de carne roja y procesada en Colombia para el año 2010. Se utilizó un modelo dinámico de macrosimulación, PREVENT 3.01, para integrar los datos disponibles sobre incidencia de cáncer y evaluar el impacto de la eliminación de la dieta colombiana de la carne roja y procesada sobre la incidencia nacional de cáncer colorrectal.

Resultados:

La eliminación del consumo total de carne roja de la dieta colombiana dio lugar a reducciones en la incidencia estandarizada por edad de cáncer colorrectal, traduciéndose en la disminución de 331 casos en hombres (FAP 13%) y 297 en mujeres (FAP 10%). La eliminación de carnes procesadas tuvo efectos ligeramente más fuertes, con disminución de 362 casos en hombres (FAP 14%) y 388 en mujeres (FAP 13%).

Conclusiones:

Una proporción sustancial de la carga de cáncer colorrectal en Colombia puede atribuirse al consumo de carne roja y procesada.

Palabras clave: Carne roja; carne; carne procesada; dieta; riesgo; neoplasias colorectal; programas de computo; Colombia

Introduction

Lifestyle factors, including diet, are important determinants of cancer risk 1. Recently, the International Agency for Research on Cancer (IARC) copied the conclusions previously made by the World Cancer Research Fund (WCRF). The conclusions are that the consumption of red meat is a probable carcinogen (class 2A) and that the consumption of processed meat is a carcinogen (class 1) 2. Red and processed meats particularly increase the risk of colorectal cancer.

Several components of meats are thought to be responsible for the carcinogenic effects, including heme iron, and chemicals that form during meat processing or cooking such as N-nitroso compounds, heterocyclic aromatic amines and polycyclic aromatic hydrocarbons. Some of these chemicals are known or suspected carcinogens 3,4. However, it is not yet fully understood how cancer risk is increased by red meat or processed meat consumption 4.

According to the most recent estimates by the Global Burden of Disease Project, worldwide about 34,000 cancer deaths per year can be attributed to diets high in processed meat. The attributable risk proportion depends on local consumption patterns 5, and is unknown for Latin American countries. For policymakers and formulation of primary prevention measures, however, it is very useful to have local estimates of the proportion of (cancer) patients which can be attributed to exposure to certain risk factors. Therefore, in this project, we estimated the population attributable risk of colorectal cancer because of consumption of red meat and processed meats. We used to national detailed exposure information and estimates of cancer incidence, international risk association estimates and the macrosimulation program Prevent 3.01.

Materials and Methods

In this study, we modelled the population attributable risk of colorectal cancer based on consumption of red and processed meats in Colombia for the year 2005. For the analysis, the following data were used: (i) sex-specific exposure patterns of red and processed meat; (ii) age- and sex-specific colorectal cancer incidence rates for the period 2007-2011; (iii) age- and sex-specific population size for the year 2010; (iv) risk functions for red and processed meat in relation to colorectal cancer.

We used PREVENT 3.01, a dynamic simulation model 6 , to integrate the data and to evaluate the impact of eliminating red and processed meat from the Colombian diet.

Datasources

i. Consumption of red and processed meats. ENSIN-2005 collected information on food consumption in children and adults (between 2 and 64 years), using 24-Hour Dietary Recall (R24H) methodology. To estimate the size of the portions consumed, standardized geometric food models were used. This guaranteed the precision of the portions consumed in the survey. The details of the methodology, collection, capture and cleaning of the databases been published previously 7. ENSIN-2005 was performed in 17,740 households, where 39,413 subjects responded to R24H, of which 49.4% were men 7.

Since the table of food composition used in ENSIN-2005 to translate consumption into macronutrients and micronutrients does not have the items "red meats" or "processed meats”, it was necessary to prepare the original databases to estimate the consumption in grams (g) of these two items. For the above, first the different types of meats consumed were classified according IARC as "red meats", "processed meats" and "other" 2. The term “red meats” refers to beef, pork, lamb, veal and goat for domesticated animals. The term "processed meats" refers to meats preserved by smoking, fermentation, curing or salting, or addition de chemical preservatives. This classification was performed independently by two nutritionists; in cases when no consensus was established on the classification, the investigator (OFH) established the final classification. Subsequently, the consumption of red and processed meats in grams (g) was estimated for each subject, using FoodCalc, v.1.3 8. Finally, the mean intake of red and processed meats (g) and their standard deviation was estimated by sex and age group (0-14; 15-44; 45-54; 55-64), constituting one of the inputs for the PREVENT software 6. Data processing was performed using Stata SE® (9.

ii. Estimated age-and sex-specific colorectal cancer incidence rates for the period 2007-2011 were obtained from a publication by the National Cancer Institute of Colombia - which estimated subnational and national cancer incidence - by age group, crude and age-standardized, following a methodology derived from Globocan resulting in more detailed data than provided by Globocan 2012 10.

iii. The age- and sex specific projected population size for Colombia was obtained from Colombia’s national statistics office Departamento Administrativo Nacional de Estadística (DANE).

iv. Risk functions for the relation between colorectal cancer and red and processed meat respectively were calculated based on the results of a large meta-analysis 11. We applied the following mathematical formula based on a consumption of 100 grams per day to calculate the reduction in risk for each reduction in steps of 20 grams per day (Table 1), assuming that Ln(RR(x))= intercept 12. Supplementary material, summarizes the calculations.

Table 1 Calculation of the risk functions 

Relation between colorectal cancer risk and consumption of Relative Risk Intercept (lnRR) Unit of change g/day Change in risk with each unit change in Prevent
Males Females Males Females Males Females Males Females
Red meat 1.17 1.17 -0.157 -0.157 20 20 0.002 0.002
Processed meat 1.35* 1.35* -0.300 -0.300 20 20 0.002 0.002

*1.17 is the figure from the literature, corresponding to a consumption of 50 g per day of processed meat, transforming this risk to 100 g per day corresponds to 1.35.

PREVENT model

To model the proportion of the colorectal cancer burden in Colombia attributable to consumption of red and processed meats, we used the simulation software PREVENT 3.01, adapted version for EUROCADET. A detailed description of the mathematical calculations of the PREVENT modelling software is given in a previous publication 6. In short, PREVENT 3.01 compares the projected future incidence of a disease without interventions (reference scenario) with the projected future incidence after reduction of exposure to risk factors (intervention scenarios) based on the standard formulae for estimation of population attributable fraction (PAF). Also PREVENT include a latency time in the model.

As we wanted an estimate of the PAF, we reduced the actual exposure to zero in the year 2010 for the intervention scenario, resulting in PREVENT calculating incidence in the reference (“real”) scenario with the observed prevalence of red and processed meat consumption - versus incidence in the intervention scenario (with zero exposure) - resulting in the PAF. Since for PAF time lags in the effects of the risk factors are irrelevant in the PAF estimation, we did not model any latency or lag times. The only difference between the reference and intervention scenarios was therefore the reduction in the exposure.

Outcome measures were both absolute numbers and age-standardized rates of incident cases under the reference and intervention scenarios. Incidence rates were age-standardized using the SEGI world population and expressed per 100,000 person-years. The differences in absolute numbers were used to calculate the population attributable fraction under this model (i.e., proportion of colorectal cancers which would be avoided if red or processed meat were to be eliminated from the Colombian diet).

Sensitivity analysis: in order to estimate the range of uncertainty because of relative risks used, we used the lower and upper end of the confidence intervals of the meta-analysis in two sensitivity analyses, using the same prevalence and incidence data and the same modeling methods as in the main analyses (Table 2).

Table 2 Results of sensitivity analysis assuming the confidence intervals for the attributable fraction. 

Relation between colorectal cancer risk and consumption of Relative Risk Intercept (lnRR) Unit of change g/day Change in risk with each unit change in Prevent
Males Females Males Females Males Females Males Females
Lower limit
Red meat 1.05 1.05 -0.048 -0.048 20 20 0.002 0.002
Processed meat 1.27* 1.27* -0.239 -0.239 20 20 0.002 0.002
Upper limit
Red meat 1.31 1.31 -0.270 -0.270 20 20 0.002 0.002
Processed meat 1.45† 1.45† -0.371 -0.371 20 20 0.002 0.002

*1.10 and † 1.28 are the figures from the literature, corresponding to a consumption of 50 g per day of processed meat in its lower and upper limits, transforming this risk to 100 g per day corresponds to 1.27 and 1.45.

Ethical Standards Disclosure

This article was based on secondary analysis of data on the incidence estimates for colorectal cancer produced by the Instituto Nacional de Cancerología de Colombia and Encuesta de Salud Nutricional de Colombia - ENSIN 2005. Ethical approval for this study was not required.

Results

Consumption of red and processed meats.

In Colombia in 2005, we estimated the average daily consumption of red meats to be 62.4 g/day (95% CI: 61.4-63.3) for males and 55.0 g/day (95% CI: 54.2-55.7) for females. Mean daily consumption of processed meats was 58.3 g/day (95% CI: 56.4-60.1) for males and 50.7 g/day (95% CI: 49.1-52.3) for females. The consumption of red meat was highest in the age category 25-29 years (mean and SD of 70.4 g + 55.2), whereas the youngest age group of 2-4 years had the lowest consumption with 41.0 g + 26.7. Processed meat consumption was highest in ages 15-19 (mean consumption 61.6 g + 56.3) and lowest in the 55-59-year age group (42.9 g + 30.4). Supplementary material provides the estimated mean daily consumption for red and processed meat by sex and 5-year age group.

The intervention eliminating consumption of red meat altogether from the population resulted in reductions in age-standardized incidence rates from 12.2 to 10.5 and from 12.3 to 10.8 per 100,000 males and females, respectively, and to 10.3 and 10.6 for processed meats (Fig. 1).

In absolute numbers, the real incidence in 2010 was modelled to be 2,480 new male and 2,878 new female colorectal patients annually. In men, elimination of red meat consumption would avoid 331 patients and elimination of processed meats would avoid 362 new patients. For females, these numbers are 297 for red meat and 388 for processed meat elimination from the diet. This reduction translates into a population attributable fraction of 13% for males, and 10% for females for red meat consumption (average PAF 12%) and of 14% (males) and 13% (females) for processed meat consumption (average PAF 14%). Table 3 shows the effect of the risk function estimates, based on the upper and lower limits of the risk estimates, the proportion of new cases avoided under the scenario of elimination of red meat consumption, between 7 and 20% of male, and between 5 and 15% of female cases would be avoided. For elimination of processed meat consumption, this interval is 10-19% for males and 9-18% for females.

Figure 1 Age-standardized (SEGI standard population) colorectal cancer incidence rates estimated for Colombia, 2010, under the reference (real) and intervention scenarios  

Table 3 Population attributable fraction in absolute numbers and proportion of avoidable colorectal cancers by eliminating red and processed meat consumption 

Risk factor Sex Colorectal cancer incidence 2010 (reference) Colorectal cancer incidence 2010 under simulation* (intervention) 95% CI of optimal incidence in absolute numbers† Proportion avoidable colorectal cancers* 95% CI of proportion avoidable colorectal cancers†
Numbers Numbers Lower limit Upper limit % Lower limit % Upper limit %
Red meat Men 2,480 2,149 1,992 2,312 13 7 20
Women 2,878 2,581 2,439 2,727 10 5 15
Processed meat Men 2,480 2,118 2,003 2,236 15 10 19
Women 2,878 2,490 2,363 2,618 14 9 18

*under elimination of red or processed meat consumption

†Based on the lower and upper end of the 95% confidence intervals of the meta-analyses of the relative risks for colorectal cancer for red and processed meat consumption

Discussion

This modeling exercise, based on existing data sources, shows that an expected 11.9% of colorectal cancers occurring in the Colombian population is attributable to the consumption of red meats, whereas 13.9% is attributable to processed meats. Not many studies have estimated population attributable risks or fraction for the consumption of red and processed meat, one Australian study estimated that 18% of colorectal cancer occurring in Australians in 2010 were attributable to red/processed meat consumption, but this study did not differentiate between red and processed meat consumption 13. Similar figures for the UK were estimated to be 21.1% 14. Of course, this fraction is highly dependent on both the incidence of the disease, but more importantly, on the meat consumption patterns of the population.

Colorectal cancer in Colombia seems to be on the rise, based on trends with 2% annual increase in mortality figures 15 and observations since 1962 from the population-based cancer registry of the city of Cali 16,17. Important risk factors for cancer include, besides the consumption of meat, harmful use of alcohol, diabetes, low fruit and vegetable consumption, low physical activity, y tobacco consumption 18. A low participation rate of colorectal cancer screening also influences the risk substantially 19. The observed increases in colorectal cancer incidence are unlikely to be due to changes in alcohol consumption, which according to WHO has been flat over the past decades in Colombia 20. Trends in levels of physical activity are unclear; whereas leisure time physical activity decreased, active ways of transportation (walking, biking), increased in the Colombian population between 2005 and 2010 21. In general, levels of physical activity are relatively low in Colombia. Despite the enormous offer and diversity of fruits and vegetables in this tropical country, the consumption of fruits is very low with a median of 88 g/day (mode 12 g/day), and the vegetable consumption is even lower: 45.75 g/day (mode 14.5 g/day) 22. Trends in diabetes are increasing, according to unofficially published figures by the Colombian Observatory for Diabetes 23.

The consumption prevalence on which we based the figures for the population and incidence data of 2010 was for 2005. We modelled this delay because exposure to dietary carcinogens is unlikely to have a very short term effect and therefore we believe the five-year gap between prevalence and incidence data does not cause any problem for these estimates.

Strengths and weaknesses

As in any modeling exercise, the results depend entirely on the input data and assumptions used, most importantly the cancer incidence, consumption prevalence and risk function information. Even though all three sources have their levels of uncertainty, they were based on the best available information. Our incidence data were estimates based on modeling using data from 4 high quality regional population based cancer registries as well as official national mortality data, which methods are described in detail elsewhere 10. Although no national cancer registry is available, we believe these figures are close to represent the actual colorectal cancer incidence in Colombia. We used national representative studies to estimate the red and processed meat consumption in Colombia and were able to differentiate between the two types of meat consumption.

Sensitivity analysis using the extremes of the confidence intervals for the risk functions resulted in a range of likely estimates, which were wider for males and for red meat because of the greater spread of consumption pattern combined with wider confidence intervals of the relative risks. We did not perform any sensitivity analysis for the incidence and prevalence data, since their confidence intervals were rather narrow, therefore they will result in minimum variation in the final estimates.

Conclusion

Colorectal cancer incidence could be reduced if interventions were made to reduce red and processed meat consumption, because around 12% of colorectal cancer cases in Colombia can be attributed to red meat consumption, and 14% to processed meat consumption. The growing burden of this cancer can be curbed by reducing this consumption as well as focusing on increasing dietary fiber consumption (eg. fruit and vegetable) as well as physical activity and increase participation in screening programs.

Acknowledgments:

We would like to thank Dr. Jan Barendregt and epigear for providing us with the Prevent Software.

References

1. Norat T, Scoccianti C, Boutron-Ruault M-C, Anderson A, Berrino F, Cecchini M, et al. European Code Against Cancer 4th edition: diet and cancer. Cancer Epidemiol. 2015;39:S56-66. [ Links ]

2. International Agency for Research on Cancer. IARC Monograph. Red Meat and Processed Meat. Lyon, Fr: WHO; 2015. Available from: http://www.iarc.fr/en/media-centre/iarcnews/pdf/Monographs-Q&A_Vol114.pdf. [ Links ]

3. Bastide NM, Pierre FH, Corpet DE. Heme iron from meat and risk of colorectal cancer: a meta-analysis and a review of the mechanisms involved. Cancer Prev Res (Phila). 2011;4(2):177-84. [ Links ]

4. Demeyer D, Mertens B, De Smet S, Ulens M. Mechanisms linking colorectal cancer to the consumption of (processed) red meat: A review. Crit Rev Food Sci Nutr. 2016; 56(16): 2747-66. [ Links ]

5. School Public Health, Harvard Chan TH. WHO report says eating processed meat is carcinogenic: Understanding the findings. Nutrition Source. 2015. Available from: https://www.hsph.harvard.edu/nutritionsource/2015/11/03/report-says-eating-processed-meat-is-carcinogenic-understanding-the-findings/Links ]

6. Soerjomataram I, De Vries E, Engholm G, Paludan-Muller G, Bronnum-Hansen H, Storm HH, et al. Impact of a smoking and alcohol intervention programme on lung and breast cancer incidence in Denmark: An example of dynamic modelling with Prevent. Eur J Cancer. 2010;46(14):2617-24. [ Links ]

7. Borda VC (Edit). Encuesta nacional de la situación nutricional en Colombia, 2005. Primera. Villegas CB, editor. Bogotá DC: Instituto Colombiano de Bienestar Familiar; 2006. Available from: http://www.icbf.gov.co/portal/page/portal/PortalICBF/bienestar/nutricion/ensin/LIBRO_2005.pdf. [ Links ]

8. Lauritsen J. Software FoodCalc v. 1.3. Diet, cancer and Health Project. Copenhague Danish Cancer Soc. 1998. Available from: http://www.ibt.ku.dk/jesper/foodcalc/Links ]

9. Stata Corp. Stata Statistical Software: Release 13 Stata Corp. College Station, TX: Stata Corp LP; 2013. [ Links ]

10. Pardo RC, Cendales DR. Incidencia, mortalidad y prevalencia de cáncer en Colombia, 2007-2011. Instituto Nacional de Cancerología: Bogotá DC; 2015. [ Links ]

11. Chan DSM, Lau R, Aune D, Vieira R, Greenwood DC, Kampman E, et al. Red and processed meat and colorectal cancer incidence: meta-analysis of prospective studies. PLoS One. 2011;6(6):e20456. [ Links ]

12. Greenland S. Regression Methods for Epidemiologic Analysis. In: Ahrens W, Pigeot I, editors Handbook of Epidemiology. Springer: New York; 2007. p 625. [ Links ]

13. Nagle CM, Wilson LF, Hughes MCB, Ibiebele TI, Miura K, Bain CJ, et al. Cancers in Australia in 2010 attributable to the consumption of red and processed meat. Aust N Z J Public Health. 2015;39(5):429-33. [ Links ]

14. Parkin DM. Cancers attributable to dietary factors in the UK in 2010. Br J Cancer. 2011;105:s24-S26. [ Links ]

15. Piñeros M, Gamboa O, Hernández-Suárez G, Pardo C, Bray F. Patterns and trends in cancer mortality in Colombia 1984-2008. Cancer Epidemiol. 2013;37(3):233-9. [ Links ]

16. Bravo LE, Collazos T, Collazos P, García LS, Correa P. Trends of cancer incidence and mortality in Cali, Colombia. 50 years experience. Colomb Med (Cali). 2012;43(4):246-55. [ Links ]

17. Armando C, Bravo LE, Clín P, García LS, Collazos P. Incidencia, mortalidad y supervivencia por cáncer colorrectal en Cali, Colombia, 1962-2012. Salud Publica Mex. 2014;56(5):457-64. [ Links ]

18. Huxley RR, Ansary-Moghaddam A, Clifton P, Czernichow S, Parr CL, Woodward M. The impact of dietary and lifestyle risk factors on risk of colorectal cancer: a quantitative overview of the epidemiological evidence. Int J cancer. 2009;125(1):171-80. [ Links ]

19. Meester RGS, Doubeni CA, Lansdorp-Vogelaar I, Goede SL, Levin TR, Quinn VP, et al. Colorectal cancer deaths attributable to nonuse of screening in the United States. Ann Epidemiol. 2015;25(3):208-13. [ Links ]

20. WHO. Global status report on alcohol and health 2014. World Health Organization: Genova; 2014. [ Links ]

21. González S, Lozano Ó, Ramírez A. Physical activity levels among Colombian adults: Inequalities by gender and socioeconomic status. Biomedica. 2014;34(3):447-59. [ Links ]

22. Combariza JA. Perfil nacional de consumo de frutas y verduras. Ministerio de Salud y Protección Social, FAO: Bogotá DC; 2013. [ Links ]

23. Observatorio de diabetes en Colombia. Diabetes mellitus en Colombia: estudio de tendencias a partir de SISPRO y CAC, las herramientas oficiales. Organización para la excelencia en Salud: 2014. Available from: http://www.cgh.org.co/odc/itemlist/user/62-administrador.html?start=10. [ Links ]

Founding: This work was supported by the National Cancer Institute of Colombia. Proyecto C4103061-0001 “Diseño e implementación de herramientas administrativas para apoyo y control al proceso de investigación” Recursos Inversión Nación, Vigencia 2015.

Supplementary material

Table 4 Age groups by sex and average amounts of consumption of red meats and processed meats. 

Age group Red meat Processed meats
Men Women Men Women
N (gr) Mean (gr) Sd (gr) N (gr) Mean (gr) Sd (gr) N(gr) Mean (gr) Sd (gr) N (gr) Mean (gr) Sd (gr)
2-4 1,181 41.63 25.74 1,151 40.34 27.69 279 44.52 37.11 285 42.02 34.97
5-9 2,090 49.57 33.72 2,137 47.87 31.66 755 51.31 46.97 667 49.10 46.13
10-14 2,358 57.98 43.35 2,271 57.38 39.96 802 61.97 59.22 779 56.21 49.42
15-19 2,018 69.13 53.45 1,966 60.75 42.25 619 70.17 64.19 644 53.43 46.07
20-24 800 77.03 58.27 853 62.62 44.19 261 54.52 46.25 248 50.61 42.00
25-29 520 76.77 61.81 580 64.74 47.82 137 66.24 58.87 138 48.99 41.85
30-34 444 79.79 67.22 476 60.16 44.09 108 63.45 68.75 103 46.09 46.47
35-39 423 78.02 55.70 461 56.56 37.71 102 54.98 60.58 110 47.24 40.41
40-44 384 77.86 58.97 415 58.35 42.25 79 49.07 40.34 87 46.07 38.40
45-49 365 71.53 53.74 339 52.86 34.62 56 55.82 47.90 64 48.56 49.83
50-54 259 71.12 60.20 278 54.20 36.42 40 53.15 44.50 49 40.33 39.53
55-59 176 75.22 58.72 201 53.48 34.26 22 47.27 34.20 21 38.29 25.83
60-64 162 65.18 48.70 146 51.03 36.58 27 46.72 37.28 27 46.31 48.29

Received: August 04, 2016; Revised: April 04, 2017; Accepted: February 06, 2017

Corresponding author: Esther de Vries. Department of Clinical Epidemiology and Biostatistics, Pontificia Universidad Javeriana, Bogotá, Colombia. Carrera 7 No. 40 - 62 - Tel: (57 1) 3208320. E-mail: estherdevries@javeriana.edu.co

Conflict of interest: none declared

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