The under-reporting of energy intake influences the dietary pattern reported by obese women in the waiting list for bariatric surgery

RAVELLI, Michele Novaes; SARTORI, Maria Márcia Pereira; CORRENTE, José Eduardo; RASERA JUNIOR, Irineu; SOUZA, Noa Pereira Prada de; OLIVEIRA, Maria Rita Marques de

doi:10.1590/1678-98652018000200009

ABSTRACT

Objective

To verify the interference of the energy intake under-reporting in the determination of the dietary patterns and nutrient intakes reported by obese women in the waiting list for bariatric surgery.

Methods

The study included 412 women aged 20 to 45 years with a body mass index ranging from 35 to 60kg/m² who were on waiting list for bariatric surgery. Data from three reported food intake and physical activity, body weight, and height were used for estimating the reported energy intake, physical activity level, and resting energy expenditure. Subsequently, it was checked the biological plausibility of the reported energy intakes, classifying all participants as plausible reporters or under-reporters. Exploratory factor analysis was used to determine the participants’ dietary patterns. The Mann-Whitney test assessed the reported energy and nutrient intakes between plausible reporters and under-reporters groups. The Z-test assessed the variables of plausible reporters or under-reporters in relation to all participants of the study.

Results

Six dietary patterns were determined for all participants of study. After excluding information from under-reporting women, only two dietary patterns remained similar to those of all participants, while three other dietary patterns presented different conformations from food subgroups to plausible reporters. The reported energy intake did not present difference for the subgroups of fruits, leaf vegetables and vegetables. However, the energetic value reported for the other food subgroups was higher for the plausible reporters.

Conclusion

The under-reporting of energy intake influenced the determination of dietary patterns of obese women waiting for bariatric surgery.

Keywords
Energy intake; Dietary pattern; Multivariate analysis; Obesity.; Under-reporting

RESUMO

Objetivo

Esta pesquisa buscou verificar a interferência da subnotificação do consumo energético na determinação do padrão alimentar e consumo de nutrientes, relatados por mulheres obesas na fila de espera para cirurgia bariátrica.

Métodos

Participaram do estudo 412 mulheres com idade entre 20 e 45 anos e índice de massa corporal entre 35 e 60 kg/m2, que aguardavam na fila de espera de cirurgia bariátrica. Foram utilizadas informações de três registros do consumo alimentar, da atividade física de 24 horas e do peso corporal e altura, para estimativa da Ingestão Energética Relatada, Nível de Atividade Física e Gasto Energético de Repouso das participantes e subsequente verificação da plausibilidade biológica do consumo energético. As mulheres foram agrupadas em notificadoras plausíveis e subnotificadoras. A análise fatorial exploratória foi utilizada para classificar os padrões alimentares. Os valores relatados de energia e nutrientes entre os grupos de notificadoras plausíveis e subnotificadoras foram avaliados por meio do teste de Mann-Whitney. O Teste de hipótese Z avaliou as variáveis das notificadoras plausíveis ou subnotificadoras em relação a todas as participantes do estudo.

Resultados

Seis padrões alimentares foram determinados para todas as participantes do estudo. Após excluir as informações das mulheres subnotificadoras, apenas dois padrões alimentares mantiveram-se similares aos de todas as participantes, ao passo que outros três padrões alimentares apresentaram diferentes conformações de subgrupos alimentares para as notificadoras plausíveis. A ingestão energética relatada não apresentou diferença para os subgrupos das frutas, hortaliças e legumes. Porém, o valor energético relatado para os demais subgrupos alimentares foi maior para as notificadoras plausíveis.

Conclusão

A subnotificação do consumo energético influenciou a determinação de padrões alimentares de mulheres obesas na lista de espera para cirurgia bariátrica.

Palavras-chave
Ingestão de energia; Padrões alimentares; Análise multivariada; Obesidade; Subnotificação

INTRODUCTION

Food intake surveys used in nutritional epidemiology studies are based on self-report methods, which may cause intra- or interpersonal errors, affecting the results [¹1 Shim JE, Oh K, Kim HC. Dietary assessment methods in epidemiologic studies. Epidemiol Health. 2014;36:e2014009. http://dx.doi.org/10.4178/epih/e2014009
https://doi.org/10.4178/epih/e2014009... ]. Energy intake under-reporting is a great challenge for nutrition studies [¹1 Shim JE, Oh K, Kim HC. Dietary assessment methods in epidemiologic studies. Epidemiol Health. 2014;36:e2014009. http://dx.doi.org/10.4178/epih/e2014009
https://doi.org/10.4178/epih/e2014009...

2 Mendez MA. Invited Commentary: Dietary misreporting as a potential source of bias in diet-disease associations: Future directions in Nutritional Epidemiology Research. Am J Epidemiol. 2015;181(4):234. http://dx.doi.org/10.1093/aje/kwu306
https://doi.org/10.1093/aje/kwu306... -³3 Trijsburg L, Geelen A, Hollman PC, Hulshof PJ, Feskens EJ, Van’t Veer P, et al. BMI was found to be a consistent determinant related to misreporting of energy, protein and potassium intake using self-report and duplicate portion methods. Public Health Nutr. 2016;20(4)1-10. http://dx.doi.org/10. 1017/S1368980016002743
https://doi.org/10.1017/S136898001600274... ]. This condition can be influenced by social and cultural issues, such as the level of schooling of the participant and social norms regarding the expected consumption behaviors. Under-reporting may also be related to the characteristics of the food, depending on which may make it difficult to perceive the amount consumed and need to know the specificities of food consumption [²2 Mendez MA. Invited Commentary: Dietary misreporting as a potential source of bias in diet-disease associations: Future directions in Nutritional Epidemiology Research. Am J Epidemiol. 2015;181(4):234. http://dx.doi.org/10.1093/aje/kwu306
https://doi.org/10.1093/aje/kwu306... ,³3 Trijsburg L, Geelen A, Hollman PC, Hulshof PJ, Feskens EJ, Van’t Veer P, et al. BMI was found to be a consistent determinant related to misreporting of energy, protein and potassium intake using self-report and duplicate portion methods. Public Health Nutr. 2016;20(4)1-10. http://dx.doi.org/10. 1017/S1368980016002743
https://doi.org/10.1017/S136898001600274... ].

Under-reporters are identified by the premise that the Reported Energy Intake (EI_rep) of individuals with stable weight should be equal to their Total Energy Expenditure (TEE) [⁴4 Goldberg GR, Black AE, Jebb SA, Cole TJ, Murgatroyd PR, Coward WA, et al. Critical evaluation of energy intake data using fundamental principles of energy physiology: 1. Derivation of cut-off limits to identify under-recording. Eur J Clin Nutr. 1991;45(12):569-81.]. Although the variables of this statistically derived equation are imprecise, the minimum plausible energy intake can be calculated and expressed as multiples of the Resting Energy Expenditure (REE) [⁴4 Goldberg GR, Black AE, Jebb SA, Cole TJ, Murgatroyd PR, Coward WA, et al. Critical evaluation of energy intake data using fundamental principles of energy physiology: 1. Derivation of cut-off limits to identify under-recording. Eur J Clin Nutr. 1991;45(12):569-81.,⁵5 Black AE. Critical evaluation of energy intake using the Goldberg cut-off for energy intake: Basal metabolic rate: A practical guide to its calculation, use and limitations. Int J Obes. 2000;24(9):1119-30.]. Although, this approach does not differentiate between the under-reporting of nutrients, foods, or food groups.

The introduction of dietary pattern assessment by multivariate statistical methods was an important advance for nutritional epidemiology studies, enabling dietary assessment based on the characteristics of the foods consumed [⁶6 Cespedes EM, Hu FB. Dietary patterns: From nutritional epidemiologic analysis to national guidelines. Am J Clin Nutr. 2015;101(5):899-900.,⁷7 Moller SM, Reedy J, Millen AE, Dixon B, Newby PK, Tucker KL, et al. Dietary patterns: Challenges and opportunities in dietary patterns research. J Am Diet Assoc. 2007;107(7):1233-9.]. Factor and clusters analysis are the multivariate statistical methodologies commonly used in nutritional epidemiology for the characterization of food behavior and verification of the relationship between food and nutrient consumption with the health status of the individuals [⁶6 Cespedes EM, Hu FB. Dietary patterns: From nutritional epidemiologic analysis to national guidelines. Am J Clin Nutr. 2015;101(5):899-900.,⁷7 Moller SM, Reedy J, Millen AE, Dixon B, Newby PK, Tucker KL, et al. Dietary patterns: Challenges and opportunities in dietary patterns research. J Am Diet Assoc. 2007;107(7):1233-9.]. However, dietary pattern studies do not always check whether the reported intake is plausible, even though this factor has a great impact on the results.

Although excessive food intake is one of the main determinants of obesity and chronic diseases, overweight individuals are the greatest energy intake under-reporters, even though less accurate food intake data do exist [⁸8 Sichieri R. Dietary patterns and their associations with obesity in the Brazilian city of Rio de Janeiro. Obes Res. 2002;10(1):42-8.

9 Ma Y, Bertone ER, Stanek III EJ, Reed GW, Hebert JR, Cohen NL, et al. Association between eating patterns and obesity in free-living US Adult Population. Am J Epidemiol. 2003;158(1):58-92.-¹⁰10. Meyer J, Doring A, Herder C, Roden M, Koenin W, Thorand B. Dietary patterns, subclinical inflammation, incident coronary heart disease and mortality in middle-aged men from the MONICA/KORA Augsburg cohort study. Eur J Clin Nutr. 2011;65(7):800-7. http://dx.doi.org/10.1038/ejcn.2011.37
https://doi.org/10.1038/ejcn.2011.37... ]. Epidemiological studies often verify the associations between eating patterns and obesity and chronic diseases [¹¹11 Jessri M, Wolfinger RD, Lou WY, L’Abbe MR. Identification of dietary patterns associated with obesity in a nationally representative survey of Canadian adults: Application of a priori, hybrid, and simplified dietary pattern techniques. Am J Clin Nutr. 2017;105(3):669-84.,¹²12 Jannasch F, Kroger J, Schulze MB. Dietary patterns and Type 2 Diabetes: A systematic literature review and meta-analysis of prospective studies. J Nutr. 2017;147(6):1174-82.] however; few evaluate these associations in morbidly obese people [¹³13 Johns DJ, Lindroos AK, Jebb SA, Sjostrom L, Carlsson LMS, Ambrosini GL. Dietary patterns, cardiometabolic risk factors, and the incidence of cardiovascular disease in severe obesity. Obesity. 2015;23(5):1063-70. http://dx.doi.org/10.1002/oby.20920
https://doi.org/10.1002/oby.20920... ], especially in the waiting list for bariatric surgery.

Therefore, the aim of this study was to verify the interference of under-report of energy intake in the determination of the dietary patterns and nutrient intakes reported by obese women in the waiting list for bariatric surgery.

CASES AND METHODS

Subjects and General Information Variables

A cross-sectional study was conducted with 412 women in the waiting list for gastroplasty. The eligibility of this study population occurred by convenience once this manuscript is the result of a subproject extracted from a larger study [¹⁴14 Schnor NPP, Verlengia R, Novais PFS, Crisp AH, Leite CVS, Rasera-Junior I, et al. Association of 5-HT2C (rs3813929) and UCP3 (rs1800849) gene polymorphisms with type 2 diabetes in obese women candidates for bariatric surgery. Arch Endocrinol Metab. 2017;61(4):326-31.], in which the number of participants was calculated. The eligibility criteria, the following were considered: women aged 20 to 45 years and Body Mass Indix (BMI), from 35 to 60kg/m2, The inclusion criteria considered the subjects who were not losing weight, and did not have any diseases or take any medications that affected energy metabolism and consequently the verification of under-reporting of energy intake, during the data collection. There were no patients who refused or gave up participating in the survey.

Age, anthropometric data, reported dietary intake, and physical activity data were collected after the women signed an informed consent form. The project was approved by the Ethics Committee accredited to the National Health Council, under protocol nº 3303-2009.

Anthropometric and Energy Expenditure Variables

The measurements of Height (H) and current Weight (W) were performed by the same researcher with the same stadiometer and the same digital body weight scale. The weight was measured in a digital scale of the brand FILIZOLA^® (Recife, Pernambuco, Brazil) with a maximum capacity of 350kg. For this measurement, the patient was instructed to stand, barefoot and with as few clothes as possible, remaining erect, feet together in the center of the platform, arms along the body, to avoid possible changes in reading the measurements [¹⁵15 Gibson RS. Nutritional assessment: A laboratory manual. New York: Oxford University Press; 1993.]. The height was determined using the SECA^® (German Health Care Export Grup, Hamburg, Germany) vertical stadiometer with a 1.0mm scale. The patient was placed in the orthostatic position, head oriented in the Frankfurt plane, barefoot and, as far as possible, maintaining the heels, pelvic and scapular waists, and occipital region in contact with the device [15]. The Body Mass Index (BMI) of each patient was determined by body weight (kilos), divided by height (meters), squared.

The Resting Energy Expenditure (REE) was obtained through the predictive calculation described by Mifflin et al. [¹⁶16 Mifflin MD, Jeor ST, Hill LA, Scott BJ, Daugherty SA, Koh YO. A new predictive equation for resting energy expenditure in healthy individuals. Am J Clin Nutr. 1990;51(2):241-7.]. According with Quesada [¹⁷17 Quesada KR, Novais PFS, Detregiachi CRP, Barbalho SM, Rasera Jr I, Oliveira MRM. Comparative analysis of approaches for assessing energy intake underreporting by female bariatric surgery candidates. J Am Coll Nutr. 2014;33(2):155-62.], this equation presented a lower variation (3.6%) of the predictive REE value in relation to the value of the direct REE method.

REE=(9.99xW)+(6.25xH)-(4.92xA)-161

At where:

W = Weight (Kg).

H = Height (cm).

A = Age (years).

Food Intake Variables

The participants’ food intake data were collected by three 24-hour dietary record (24HR) on nonconsecutive days, including a weekend day. To obtain the Reported Energy Intake (EI_rep), the patients were trained to fill in the information appropriately in their home, considering the details of all food, beverages and dietary supplements consumed on the day, as well as the types and quantities of the preparations. On return to the clinic, after 30 days of training day, nutritionists checked the items registered with the patients, clarifying the possible doubts. The EI_rep was given by a compilation of national and international nutritional composition tables of foods described in the Pesquisa de Orçamentos Familiares (POF, Family Budgets Survey) by the Instituto Brasileiro de Geografia e Estatística (IBGE, Brazilian Institute of Geography and Statistics) [¹⁸18 Instituto Brasileiro de Geografia e Estatística. Pesquisa de orçamentos familiares, 2008-2009 (POF): tabelas de composição nutricional dos alimentos consumidos no Brasil. Rio de Janeiro: IBGE; 2011.].

The tabulated foods were distributed into the five food groups as recommended by the first edition of the Guia Alimentar para a População Brasileira (GAPB, Brazilian Food Guide) [¹⁹19 Ministério da Saúde (Brasil). Secretaria de Atenção à Saúde. Guia alimentar para a população brasileira: promovendo a alimentação saudável. Brasília: Ministério da Saúde; 2008. (Série A. Normas e Manuais Técnicos).]. Then the groups were divided into thirteen subgroups according to the foods’ nutritional characteristics to increase analytical specificity (Chart 1).

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Chart 1
Food subgroups and respective foods.

Physical Activity Level-Related Variables

Physical Activity Level (PAL) data were obtained on the same days as 24HR using three physical activity reported. Subjects were asked to report all activities performed during the day, including the time spent in each activity. The information on time spent sleeping, type of commuting, physical activities performed at work, development of domestic tasks, leisure activities, sports and scheduled physical exercises performed throughout the day are recorded.

The PAL was calculated considering the time spent on each activity multiplying it by a factor derived from the metabolic equivalent (MET), described in the Dietary Reference Intakes (DRI) references [²⁰20 Institute of Medicine. Food and Nutrition Board. Dietary Reference Intakes (DRIs): Dietary Reference Intakes for energy, carbohydrates, fiber, fat, protein and amino acids (macronutrients). Washington (DC): National Academy Press; 2005.]. Thus, for each activity, an energy cost was obtained, provided by an activity/energy expenditure conversion table that is multiplied by the time of physical activity. For the activities reported that were not in the DRI table, the compendium of physical activities [²¹21 Ainsworth BE, Haskell WL, Whitt MC, Irwin ML, Swartz AM, Strath SJ, et al. Compendium of physical activities: An update of activity codes and MET intensities. Med Sci Sport Exer. 2000;32(Supl 9):498-516.] was used to convert these activities considering the equivalence in energy expenditure.

The women were classified by the Activity Factor (AF), corresponding to PAL ranges, according to the DRI [²⁰20 Institute of Medicine. Food and Nutrition Board. Dietary Reference Intakes (DRIs): Dietary Reference Intakes for energy, carbohydrates, fiber, fat, protein and amino acids (macronutrients). Washington (DC): National Academy Press; 2005.].

Determination of Energy Intake Under-reporting

Food intake under-reporting was determined by confronting the EI_rep:REE ratio with the PAL.

\frac{{EI}_{rep}}{REE} = PAL

At where:

EI_rep = Reported energy intake

REE = Resting Energy Expenditure

PAL= Physical Activity Level

The cut-off point was defined according to equation of Goldberg et al. [⁴4 Goldberg GR, Black AE, Jebb SA, Cole TJ, Murgatroyd PR, Coward WA, et al. Critical evaluation of energy intake data using fundamental principles of energy physiology: 1. Derivation of cut-off limits to identify under-recording. Eur J Clin Nutr. 1991;45(12):569-81.], adjusted by Black [⁵5 Black AE. Critical evaluation of energy intake using the Goldberg cut-off for energy intake: Basal metabolic rate: A practical guide to its calculation, use and limitations. Int J Obes. 2000;24(9):1119-30.].

C P = P A L . e x p \{s d_{\min} . [\frac{\frac{s}{(100)}}{\sqrt{N}}]\}

At where:

CP = Cut-off point

PAL = Physical Activity Level, according to the classification indicated by the DRI document.

sd_min= Standard deviation assumed as -3 for the group.

N = Number of subjects.

S = Factor of Variation by the square root of the coefficients of variation of EI_rep, REE and PAL.

To determine the value of S, initially were found the coefficients of variation of the energy balance components as described in the equation below, which were inserted in equation before.

S = \sqrt{[(\frac{C V^{2} E I_{r e p}}{d}) + (C {V^{2}}_{REE}) + (C {V^{2}}_{PAL})]}

At where:

CV²_EIrep = Intra-individual coefficient of variation from the Reported Energy Intake.

d = number of days of reported food intake.

CV²_REE= Intraindividual coefficient of variation from Resting Energy Expenditure (8.5% was assumed, based on the recommendations of Black [5].

CV²_PAL= Intraindividual coefficient of variation from Physical Activity Level.

The cut-off point value was compared with the EI_reo: REE ratio of each woman, grouping the subjects as energy intake plausible reporters $(\frac{{EI}_{rep}}{REE} \geq C P)$ or under-reporters $(\frac{{EI}_{rep}}{REE} < C P)$ as proposed by Quesada et al. [¹⁷17 Quesada KR, Novais PFS, Detregiachi CRP, Barbalho SM, Rasera Jr I, Oliveira MRM. Comparative analysis of approaches for assessing energy intake underreporting by female bariatric surgery candidates. J Am Coll Nutr. 2014;33(2):155-62.].

Statistical Analysis

The statistical analyses were performed by the software Statistical Package for the Social Sciences (SPSS Inc., Chicago, Illinois, United States) version 21 for Windows (IBM Inc., Armonk, New York, United States).

The total daily intake of nutrients reported by women of study were corrected by intra- and inter-individual variation using Analysis of Variance (ANOVA).

The dietary patterns of each group of women (all participants of study, plausible reporters, and under-reporters) were obtained by the contribution of daily energy intake reported (kcal/day) of each food subgroup consumed by each woman. The dietary patterns were identified by exploratory factor analysis, using principal component analysis with VARIMAX rotation to extract the number of factors (number of dietary patterns in each group of women). Factors with eigenvalues greater than 1.0 and factor loadings ≥|0.400| for each food subgroup, were considered significant in the matrix interpretation and dietary pattern naming [²²22 Hair JF, Anderson RE, Tatham RL, Black WC. Análise multivariada de dados. 6a ed. Porto Alegre: Artmed; 2009.]. The dietary patterns found for each group (all participants of study, plausible reporters, and under-reporters) were then compared.

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Table 1
General information of female food intake plausible reporters and under-reporters in the waiting list for bariatric surgery.

In the descriptive analysis, the Kolmogorov-Smirnov test revealed the variables did not have normal distribution. The Mann-Whitney test compared the anthropometric and energy expenditure information, reported energy and nutrient intake variables between the two groups of women (plausible reporters and under-reporters). The Z-test was applied to verify if the average of energy and nutrient intake reported by plausible reporters and under-reporters is different of the average reported by all participants of study. The significance level was set at 5% (p≤0.05).

RESULTS

Table 1 showed the estimated anthropometric and energy requirements for the women participating in the study. The 412 obese women were classified as plausible reporters (#157; 38%) and under-reporters (#255; 62%) of energy intake. After excluding data from women who under-report their energy intake, the means of variables age and BMI of the women classified as plausible reporters did not present a difference (p>0.05) when compared to the values calculated for all the participants of study. However, the mean of the TEE-DRI, REE and PAL-DRI variables presented lower values (p<0.05) for the plausible reporters when compared to the values considering all participants.

Table 2 shows the factorial loads that determined the dietary patterns of all study participants and, after excluding information from under-reporters, describes the dietary patterns of plausible reporters. The name of the dietary patterns of all participants and for each group of women was based on the values > |0.400| of factorial loads.

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Table 2
Factor matrix of the scores that determined the general dietary patterns of the women in the waiting list for bariatric surgery and of the energy intake plausible reporters and under-reporters.

The dietary patterns determined for all women in the study were defined by six factors selected by factorial analysis. For the groups of women classified as plausible reporters and under-reporters of energy intake, five factors determined the dietary patterns of each of the groups. The dietary patterns described for all participants explained 61.4% of the variance of the reported daily energy intake, while 53.7% and 51.7% of the variance explained the consumption of plausible reporters and under-reporters, respectively (Chart 2).

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Chart 2
Dietary patterns of all participants, of plausible reporters, and of under-reporters of energy intake.

All food subgroups presented a high contribution in the determination of the six dietary patterns described for all the women in the study (Chart 2). Only the subgroup of milk and dairy products was evidenced in two factors, describing two distinct dietary patterns: one composed of pasta, milk and dairy products and sweets (3rd factor), and the other by fruit and dairy products (5th factor). The first factor evidenced a dietary pattern composed of tubers and roots, meat products and processed foods, while food subgroups composed of breads and grains and beans were highlighted in the 2nd factor for all participants. The fourth factor described a dietary pattern composed of the food subgroups of fast foods and beverages in general, while the last factor (6) described a dietary pattern based on vegetables and leafy vegetables (Table 2).

By excluding the energy consumption information reported by the under-reporting women, it was found that the dietary subgroup of meat, seafood and eggs contributed to the determination of three different dietary patterns of plausible reporters. The First factor described a more heterogeneous dietary pattern, composed of tubers and roots, fruits, vegetables, meats, seafood and eggs and processed salted foods. In the 3rd factor, besides the contribution in this component of the subgroup of the meat, the leaf vegetables and fast foods also participated in the determination of this dietary pattern. The food subgroups of meat, beverages and fruits also contributed to the description of the 4th factor of plausible reporters. The fifth factor of plausible reporters described a dietary pattern based on simple carbohydrate food sources, composed of the subgroups of the pasta and sweets, and the food subgroup of milks and derivatives (Table 2).

Table 3 shows the difference in energy intake reported for each of the food subgroups and in the daily energy, macro and micronutrient values between the data of all the women in the study, plausible reporters and under-reporters.

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Table 3
Mean, standard deviation, median, and quartile daily energy intake from the food subgroups, and the energy and nutrient intakes of women in the waiting list for bariatric surgery.

The energy intake reported for the food subgroups of fruits, leaf vegetables and vegetables did not present difference (p>0.05) for all participants in relation to the plausible reporters. In these food subgroups, the energy values reported by the plausible reporters and under-reporters were also similar. However, for the other food subgroups, after the exclusion of the energy intake information reported by the under-reporters, it was found that the plausible reporters presented a higher energy intake in comparison to the values presented by all the participants.

By excluding the values of daily energy intake reported by under-reporters, it was found that plausible reporters had a higher energy intake reported (p<0.05) than the data of all the participants. The same was verified for the reported intake of carbohydrates, proteins, fats, fibers and calcium. Only the mean value reported for vitamin C intake did not present difference (p>0.05) when compared to data from all participants.

DISCUSSION

The study confirms that under-reporting of energy intake may influence the determination of dietary patterns of obese women in the waiting list for bariatric surgery. After the exclusion of information from women classified as under-reporting, a different combination of food groups was highlighted, determining new dietary patterns described for the group of women classified as plausible reporters.

Most women (#255; 62%) was classified as under-reporters of energy intake, this can be a critical factor in the differentiation of dietary patterns, by excluding this information in the factor analysis. The high proportion of under-reporting is notable, but it was already expected since overweight is one of the main characteristics of individuals who do not report energy intake correctly [⁸8 Sichieri R. Dietary patterns and their associations with obesity in the Brazilian city of Rio de Janeiro. Obes Res. 2002;10(1):42-8.,⁹9 Ma Y, Bertone ER, Stanek III EJ, Reed GW, Hebert JR, Cohen NL, et al. Association between eating patterns and obesity in free-living US Adult Population. Am J Epidemiol. 2003;158(1):58-92.,²³23 Vanrullen IB, Volatier JL, Bertaut A, Dufour A, Dallongeville J. Characteristics of energy intake under-reporting in French adults. Br J Nutr. 2014;111:1292-302. http://dx.doi.org/10.1017/S0 007114513003759
https://doi.org/10.1017/S000711451300375... ]. The use of predictive equations is one of the least accurate methods to estimate energy expenditure when compared to indirect calorimetry and doubly-labeled water [²⁴24 Schoeller DA. Recent advances from application of doubly labeled water to measurement of human energy expenditure. J Nutr. 1999;129(10):1765-8.,²⁵25 Trabulsi J, Schoeller DA. Evaluation of dietary assessment instruments against doubly labeled water, a biomarker of habitual energy intake. Am J Physiol Endocrinol Metab. 2001;281(5):E891-9.]. However, a study of 100 women from this same population [¹⁷17 Quesada KR, Novais PFS, Detregiachi CRP, Barbalho SM, Rasera Jr I, Oliveira MRM. Comparative analysis of approaches for assessing energy intake underreporting by female bariatric surgery candidates. J Am Coll Nutr. 2014;33(2):155-62.] found a similar prevalence of under-reporting of energy intake using indirect calorimetry (78%) and predictive equations (84%) thus the possibility of energy hypometabolism as the answer for the high proportion of women who under-reporting the energy intake is discarded.

The inconsistencies in the data of the Brazilian Food Consumption Table [¹⁸18 Instituto Brasileiro de Geografia e Estatística. Pesquisa de orçamentos familiares, 2008-2009 (POF): tabelas de composição nutricional dos alimentos consumidos no Brasil. Rio de Janeiro: IBGE; 2011.], regarding the non-differentiation of the energy contribution in certain types of preparations (raw or cooked, fried or roasted), could explain a possible change in the cut-off point for the classification of women’s groups, leading to a greater number of under-reporting women. However, studies [¹⁷17 Quesada KR, Novais PFS, Detregiachi CRP, Barbalho SM, Rasera Jr I, Oliveira MRM. Comparative analysis of approaches for assessing energy intake underreporting by female bariatric surgery candidates. J Am Coll Nutr. 2014;33(2):155-62.,²⁶26 Rhee JJ, Sampson L, Cho E, Hughes MD, Hu FB, Willett WC. Comparison of methods to account for implausible reporting of energy intake in epidemiologic Studies. Am J Epidemiol. 2015;181(4):225-33.] identified a wide variation in the cut-off point for classification of plausible reporters and under-reporters, reaching proportions very similar to those found in this study. In addition, the high proportion of under-reporting women in this study may reflect the condition of these participants in the waiting list for bariatric surgery. Considering that obese individuals tend not only to under-reporting the energy intake, but also to over-reporting the daily energy expenditure [²⁷27 Warner ET, Wolin KY, Duncan DT, Heil DP, Askew S, Bennett GG. Differential accuracy of physical activity self-report by body mass index. Am J Health Behav. 2012;36(2):168-78.,²⁸28 Pietilainen KH, Korkeila M, Bogl LH, Westerterp KR, Yki-Jarvinen H, Kaprio J, et al. Inaccuracies in food and physical activity diaries of obese subjects: Complementary evidence from doubly labeled water and co-twin assessments. Int J Obes. 2010;34(3):437-45.], the probable over-reporting of the physical activity level evidenced in this study may have been another factor contributing to the imbalance of the women’s energy balance equation of the research. However, the limitations on physical activity assessment questionnaires are cannot be ignored [²⁹29 Shephard RJ. Limits to the measurement of habitual physical activity by questionnaires. Br J Sports Med. 2003;37:197-206.].

Studies with factor analysis and clusters analysis have shown that the presence of errors in food intake reports may induce changes in the dietary patterns or in the food quantities described in the patterns, regardless of the percentage of individuals classified as under-reporting of energy intake [³⁰30 Bailey RL, Mitchell DC, Miller C, Smiciklas-Wright H. Assessing the effect of underreporting energy intake on dietary patterns and weight status. J Am Diet Assoc. 2007;107(1):64-71.,³¹31 Shrestha A, Koju RP, Beresford SAA, Chan KCC, Karmacharya BM, Fitzpatrick AL. Food patterns measured by principal component analysis and obesity in the Nepalese adult. Heart Asia. 2016;8(1):46-53.].

Among the dietary patterns defined for the plausible reporters of this study, only the dietary pattern that describes the traditional Brazilian consumption (2nd factor) was not influenced by under-reporting of energy intake. Rice and beans are consumed at regular times and more frequently, which facilitates the identification of the amount consumed. In addition, because it is the basis of the food consumption of the Brazilian population, it is assumed that there is no constraint in reporting the consumption closer to the real. A lower influence was also observed in the dietary pattern described by the consumption of foods rich in simple carbohydrates (pasta and sweets) and dairy products that changed to the 5th factor of plausible women reporters. The pastas are not consumed regularly in main meals, while the report of the consumption of sweets could cause some embarrassment in the face of a supposed judgment of the professional evaluator. The other factors had different food subgroups that translated into new and more varied dietary patterns. The fact that plausible reporters describe more food items may represent a more varied and expected consumption for the western dietary pattern, while a smaller number of items in the under-reporters patterns may reflect forgetfulness or even less consumption.

While the exclusion of information of a high percentage of under-reporting patients contributed to a new conformation of dietary patterns, the exclusion of a low percentage of under-reporting patients (16.3%) did not induce variations in the definition of dietary patterns, but in different contributions from certain food subgroups described in plausible reporters patterns [³²32 Markussen MS, Veierod MB, Ursin G, Andersen LF. The effect of under-reporting of energy intake on dietary patterns and on the associations between dietary patterns and self-reported chronic disease in women aged 50-69 years. Br J Nutr. 2016;116(5):547-58.]. The influence of under-reporting of energy intake on dietary patterns determined by the clusters method were more prevalent in groups described as healthy [³³33 Scagliusi B, Ferriolli E, Pfrimer K, Laureano C, Cunha CS, Gualano B, et al. Under-reporting of energy intake is more prevalente in a health dietary pattern cluster. Br J Nutr. 2008;100(5):1060-8.,³⁴34 Funtikova AN, Gomez SF, Fito M, Elosua R, Benitez-Arciniega AA, Schroder H. Effect of energy under-reporting on secular trends of dietary patterns in a mediterranean population. PLoS One. 2015;10(5):e0127647. http://dx.doi.org/10.1371/journal.pone.0127647
https://doi.org/10.1371/journal.pone.012... ] and the exclusion of these individuals did not alter the contribution of the food group in the description of the cluster. However, by excluding under-reporters, the patterns described as mixed and western showed a high consumption of unhealthy food groups such as sausages, white bread, pastry, soft drinks and fast foods by plausible reporting participants [³⁴34 Funtikova AN, Gomez SF, Fito M, Elosua R, Benitez-Arciniega AA, Schroder H. Effect of energy under-reporting on secular trends of dietary patterns in a mediterranean population. PLoS One. 2015;10(5):e0127647. http://dx.doi.org/10.1371/journal.pone.0127647
https://doi.org/10.1371/journal.pone.012... ].

In terms of energy presented in the food subgroups, the highest mean values reported for most food subgroups of plausible reporters, except for the subgroups of fruits, leaf vegetables and vegetables, reflect the predilection for the omission of foods with high energy density and over-reporting of healthy foods by under-reporting women, corroborating with other studies [²³23 Vanrullen IB, Volatier JL, Bertaut A, Dufour A, Dallongeville J. Characteristics of energy intake under-reporting in French adults. Br J Nutr. 2014;111:1292-302. http://dx.doi.org/10.1017/S0 007114513003759
https://doi.org/10.1017/S000711451300375... ;³⁵35 Mendez MA, Wynter S, Wilks R, Forrester T. Under-and over-reporting of energy is related to obesity, lifestyle factors and food group intakes in Jamaican adults. Public Health Nutr. 2004;7(01):9-19. http://dx.doi.org/10.1079/PHN2003508
https://doi.org/10.1079/PHN2003508... ]. When considering macro and micronutrients, plausible reporters describe a higher consumption for carbohydrates, proteins, fats and fibers, but do not differ in the consumption of vitamin C, in relation to the data of all participants. By targeting the nutrients consumption to the dietary patterns determined for the plausible reporters, these nutrients can translate the derived food subgroups into the mixed pattern, evidenced in the 1st factor of this group of women.

Numerous studies are designed to verify the association between dietary patterns and health outcomes, especially obesity and cardiovascular diseases [¹¹11 Jessri M, Wolfinger RD, Lou WY, L’Abbe MR. Identification of dietary patterns associated with obesity in a nationally representative survey of Canadian adults: Application of a priori, hybrid, and simplified dietary pattern techniques. Am J Clin Nutr. 2017;105(3):669-84.,³⁶36 Arabshahi S, Ibiebele TI, Hughes MCB, Petra H, Lahmann PH, Williams GM, et al. Dietary patterns and weight change: 15-year longitudinal studyinl Australian adults. Eur J Nutr. 2017;56(4):1455-65. http://dx.doi.org/10.1007/s00394-016-1191-3
https://doi.org/10.1007/s00394-016-1191-... ,³⁷37 Livingstone KM, McNaughton SA. Dietary patterns by reduced rank regression are associated with obesity and hypertension in Autralian adults. Br J Nutr. 2017;117(2):248-59.]. A question raised by the results of this study is pertinent to exclude data from under-reporters of energy intake from epidemiological studies that evaluate the dietary patterns of populations, aiming at reducing the bias of the results. Researchers investigating under-reporting in their studies emphasize that this variable may modify research results [²2 Mendez MA. Invited Commentary: Dietary misreporting as a potential source of bias in diet-disease associations: Future directions in Nutritional Epidemiology Research. Am J Epidemiol. 2015;181(4):234. http://dx.doi.org/10.1093/aje/kwu306
https://doi.org/10.1093/aje/kwu306... ,³⁸38 Rhee JJ, Sampson L, Cho E, Hughes MD, HU FB, Willet WC. Comparison of methods to account for implausible reporting of energy intake in epidemiologic studies. Am J Epidemiol. 2015;181(4):225-33. http://dx.doi.org/10.1093/aje/kwu308
https://doi.org/10.1093/aje/kwu308... ], and systematic errors caused by under-reporting of energy intake may affect the association between dietary patterns and diseases [³²32 Markussen MS, Veierod MB, Ursin G, Andersen LF. The effect of under-reporting of energy intake on dietary patterns and on the associations between dietary patterns and self-reported chronic disease in women aged 50-69 years. Br J Nutr. 2016;116(5):547-58.] , especially when evaluated in groups of overweight individuals, a common condition among under-reporters [⁸8 Sichieri R. Dietary patterns and their associations with obesity in the Brazilian city of Rio de Janeiro. Obes Res. 2002;10(1):42-8.

9 Ma Y, Bertone ER, Stanek III EJ, Reed GW, Hebert JR, Cohen NL, et al. Association between eating patterns and obesity in free-living US Adult Population. Am J Epidemiol. 2003;158(1):58-92.-¹⁰10. Meyer J, Doring A, Herder C, Roden M, Koenin W, Thorand B. Dietary patterns, subclinical inflammation, incident coronary heart disease and mortality in middle-aged men from the MONICA/KORA Augsburg cohort study. Eur J Clin Nutr. 2011;65(7):800-7. http://dx.doi.org/10.1038/ejcn.2011.37
https://doi.org/10.1038/ejcn.2011.37... ,²³23 Vanrullen IB, Volatier JL, Bertaut A, Dufour A, Dallongeville J. Characteristics of energy intake under-reporting in French adults. Br J Nutr. 2014;111:1292-302. http://dx.doi.org/10.1017/S0 007114513003759
https://doi.org/10.1017/S000711451300375... ].

The women’s situation at the time may have encouraged under-reporting, since failure to lose weight through clinical treatments is a justification for bariatric surgery, to which these women were candidates [¹⁷17 Quesada KR, Novais PFS, Detregiachi CRP, Barbalho SM, Rasera Jr I, Oliveira MRM. Comparative analysis of approaches for assessing energy intake underreporting by female bariatric surgery candidates. J Am Coll Nutr. 2014;33(2):155-62.]. But one must also consider the societal trend of blaming the obese for their inability to lose weight, and in this case, under-reporting may have stemmed from the shame associated with reporting their real food habits [³⁹39 Evans B, Colls R. Measuring fatness, governing bodies: The spatialities of the Body Mass Index (BMI) in anti-obesity politics. Antipode. 2009;41(5):1051-83.]. This hypothesis is supported by plausible reporters’ and under-reporters’ significantly different energy intakes from different food subgroups, except for fruits, leaf vegetables, and vegetables (Table 3), since they are recognized as healthy foods [²³23 Vanrullen IB, Volatier JL, Bertaut A, Dufour A, Dallongeville J. Characteristics of energy intake under-reporting in French adults. Br J Nutr. 2014;111:1292-302. http://dx.doi.org/10.1017/S0 007114513003759
https://doi.org/10.1017/S000711451300375... ].

CONCLUSION

The results show that the under-reporting of energy intake occurs selectively for foods with higher energy density, influencing the determination of dietary patterns and consequently modifying the order of the food groups that determine the factors and describe the patterns of consumption of plausible reporting women. Researchers should be aware of the conditions associated with the under-reporting of energy intake in order to consider them in the statistical analysis of their studies, especially when the objective is to verify the relationship between dietary patterns and health status of the population.

ACKNOWLEDGMENTS

We thank the Clínica Bariátrica de Piracicaba, São Paulo, Brazil, the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq, process: 130877/2011-5) and the Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP, process:2012/03942-6). The authors state that there are no conflicts of interest in this study.

Como citar este artigo/How to cite this article

Ravelli MN, Sartori MMP, Corrente JE, Rasera Júnior I,Souza NPP, Oliveira MRM. The under-reporting of energy intake influences the dietary pattern reported by obese women in the waiting list for bariatric surgery. Rev Nutr. 2018;31(2):235-49. http://dx.doi.org/10.1590/1678-98652018000200009

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Publication Dates

Publication in this collection
Mar-Apr 2018

History

Received
17 Apr 2017
Reviewed
21 Mar 2018
Accepted
03 Apr 2018

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Ravelli MN, Sartori MMP, Corrente JE, Rasera Júnior I,Souza NPP, Oliveira MRM. The under-reporting of energy intake influences the dietary pattern reported by obese women in the waiting list for bariatric surgery. Rev Nutr. 2018;31(2):235-49. http://dx.doi.org/10.1590/1678-98652018000200009

Groups of the Brazilian Food Guide (Ministry of Health, 2008)	Food group subgroups
Group 1 Grains, tubers, and roots.	Subgroup 1: Breads and grains (rice and respective preparations, maize, oat, cornmeal, popcorn, polenta, soups).
	Subgroup 2: Tubers and roots (potato and respective preparations, cassava, cassava flour, arracacia xanthorrhiza).
	Subgroup 3: Pasta (Pasta and sauces, pancake, lasagna).
Group 2 Fruits and vegetables.	Subgroup 4: Fruits (pineapple, banana, apple, watermelon, melon, strawberry, orange, papaya, grapes, kiwi, pear, guava, etc. and respective juices).
	Subgroup 5: Leaf vegetables (lettuce, watercress, chicory, arugula, kale, cabbage, etc.)
	Subgroup 6: Vegetables (pumpkin, zucchini, chayote, beets, carrots, okra, broccoli, cauliflower, eggplant, radish, tomato, etc).
Group 3 Beans and other high-protein plants.	Subgroup 7: Beans and other high-protein plants (pea, lentil, chickpea, soybean and derivatives, kidney beans (brown or black), bean stew, nuts).
Group 4 Meat and eggs, milk and dairy products.	Subgroup 8: Meat, seafood, and eggs (beef, poultry, pork, seafood, eggs and respective preparations).
Group 4 Meat and eggs, milk and dairy products.	Subgroup 9: Milk and dairy products (whole and low-fat cow milk, whole and low-fat yogurt, chocolate cow milk or coffee and cow milk containing sugar, fermented milk, and cheeses).
Group 5 Fat, sugar, and salt sources.	Subgroup 10: Fast foods (snacks, pizza, cheese roll, baked salty snacks, deep-fried salty snacks).
	Subgroup 11: Sweets (sandwich cookies, cookies, chocolate mix, sugar, cake with and without icing, mousse, homemade sweets, chocolate, ice cream, fruit preserves, etc.).
	Subgroup 12: Processed salty foods (cold cuts, sausages, mayonnaise, catchup, mustard, potato chips and other packaged snacks, etc.)
	Subgroup 13: Beverages (artificial or industrialized fruit juice, alcoholic beverages, soda, powdered drinks/coffee and teas containing sugar).

General information	All Participants (n=412; 100%)					Plausible Reporters (n=157; 38%)					Under-reporters (n= 255; 62%)					p ^* * p<0.05 in the comparisons made by the Mann-Whitney test between energy intake plausible reporters and under-reporters.
General information	Mean	±	SD	Median	Quartiles	Mean	±	SD	Median	Quartiles	Mean	±	SD	Median	Quartiles
Age (years)	32	±	7	32	27 – 37	32	±	6	32	28 – 38	31	±	7	31	27 – 37	<0.313
BMI (kg/m²)	46.0	±	6.0	45.1	41.6 – 49.3	45.3	±	5.6	44.4	41.4 – 48.6	46.5	±	6.3	45.5	42.0 – 50.0	<0.102
TEE – DRI (kcal)	2902	±	382	2901	2637 – 3140	2775	±	339^†† †† = p≤0.01.	2744	2532 – 3009	2981	±	386^†† †† = p≤0.01.	2969	2714 – 3212	<0.001
REE (Kcal)	1884	±	191	1873	1748 – 2005	1849	±	191^† † Z-test of the all participants in relation to plausible reporters and under-reporters, where †=p≤0.05;	1849	1707 – 1981	1905	±	189	1885	1772 – 2035	<0.004
PAL – DRI	1.53	±	0.27	1.51	1.31 – 1.69	1.46	±	0.23^†† †† = p≤0.01.	1.45	1.27 – 1.62	1.58	±	0.27^†† †† = p≤0.01.	1.56	1.36 – 1.75	<0.001

Food Groups (Kcal/day)	All Subjects (n=412; 100%)						Plausible Reporters (n=157; 38%)					Under-reporters (n= 255; 62%)
	Factor loadings (>\|0.400\|)						Factor loadings (>\|0.400\|)					Factor loadings (>\|0.400\|)
	1º Factor	2º Factor	3º Factor	4º Factor	5º Factor	6º Factor	1º Factor	2º Factor	3º Factor	4º Factor	5º Factor	1º Factor	2º Factor	3º Factor	4º Factor	5º Factor
Bread and grains	-0.283	-0.727	-0.008	-0.109	-0.079	-0.020	-0.054	0.693	-0.285	-0.004	-0.154	-0.042	-0.601	-0.114	-0.249	-0.338
Tubers and roots	-0.625	-0.042	-0.217	-0.163	-0.123	-0.040	-0.668	-0.075	-0.078	-0.100	-0.083	-0.070	-0.118	-0.142	-0.221	-0.646
Pasta	-0.107	-0.189	-0.753	-0.005	-0.155	-0.049	-0.282	-0.272	-0.117	-0.292	-0.541	-0.019	-0.390	-0.275	-0.081	-0.125
Fruits	-0.019	-0.071	-0.045	-0.018	-0.790	-0.133	-0.418	-0.162	-0.090	-0.585	-0.150	-0.584	-0.204	-0.087	-0.162	-0.068
Leaf vegetables	-0.170	-0.044	-0.048	-0.077	-0.074	-0.777	-0.034	-0.125	-0.526	-0.056	-0.137	-0.074	-0.206	-0.094	-0.595	-0.105
Vegetables	-0.210	-0.033	-0.106	-0.018	-0.313	-0.633	-0.621	-0.150	-0.053	-0.089	-0.102	-0.215	-0.063	-0.102	-0.651	-0.110
Beans and high-protein plants	-0.096	-0.841	-0.021	-0.123	-0.038	-0.054	-0.078	-0.861	-0.059	-0.017	-0.151	-0.047	-0.115	-0.165	-0.183	-0.733
Meats, seafood, and eggs	-0.6	-0.201	-0.175	-0.028	-0.281	-0.330	-0.427	-0.038	-0.436	-0.536	-0.018	-0.362	-0.444	-0.097	-0.521	-0.111
Milk and dairy products	-0.109	-0.265	-0.499	-0.181	-0.513	-0.165	-0.061	-0.170	-0.176	-0.392	-0.695	-0.168	-0.127	-0.792	-0.095	-0.098
Fast foods	-0.086	-0.039	-0.030	-0.858	-0.073	-0.031	-0.093	-0.023	-0.723	-0.173	-0.113	-0.474	-0.512	-0.029	-0.127	-0.156
Sweets	-0.173	-0.157	-0.595	-0.362	-0.161	-0.047	-0.033	-0.014	-0.344	-0.141	-0.616	-0.329	-0.110	-0.683	-0.109	-0.046
Processed salty foods	-0.663	-0.085	-0.112	-0.059	-0.068	-0.079	-0.446	-0.099	-0.291	-0.050	-0.094	-0.065	-0.504	-0.094	-0.119	-0.333
Beverages	-0.315	-0.080	-0.228	-0.593	-0.252	-0.042	-0.137	-0.069	-0.216	-0.654	-0.119	-0.772	-0.08	-0.159	-0.035	-0.069
Eigenvalues	-1.500	-1.400	-1.300	-1.300	-1.200	-1.200	-1.500	-1.400	-1.400	-1.400	-1.300	-1.500	-1.400	-1.300	-1.300	-1.300

Factors		All Participants		Plausible Reporters		Under-reporters
Factors		Dietary patterns	Variance (%)	Dietary patterns	Variance (%)	Dietary patterns	Variance (%)
1^st Factor		Tubers, meats, and processed foods	11.6	Tubers, fruits, vegetables, meats and processed food	11.6	Fruits, Fast foods and beverages	11.5
2^nd Factor		Bread, grains, and beans	11.0	Bread, grains, and beans	10.9	Breads, grains, meats, fast food and processed foods	10.6
3^rd Factor		Pasta, milk and dairy products and sweets	10.2	Leaf vegetables, meats and fast foods	10.7	Milk and dairy products and sweets	10.0
4^th Factor		Fast foods and beverages	10.1	Fruits, meats and beverages	10.5	Leaf vegetables, vegetables, and meats	09.8
5^th Factor		Fruits, milk, and dairy products	09.4	Pasta, milk and dairy products, and sweets	10.0	Tubers and beans	09.8
6^th Factor		Leaf vegetables and vegetables	09.1	-	-	-	-
Total variance (%)	61.4			53.7		51.7

Food Subgroups	All Participants (n=412; 100%)					Plausible Reporters (n=157; 38%)					Under-reporters (n=255; 62%)					p ^* * <0.05 according to the Mann-Whitney test between reported energy intake for plausible reporters and under-reporters;
	Energy (kcal/day)					Energy (kcal/day)					Energy (kcal/day)
	Mean	±	SD	Median	Quartiles	Mean	±	SD	Median	Quartiles	Mean	±	SD	Median	Quartiles
Bread and grains	385	±	192	367	240 -486	475	±	209^†† †† =p≤0.01.	457	321 – 612	330	±	157^†† †† =p≤0.01.	307	220 – 414	<0.001
Tubers and roots	83	±	120	40	0 – 114	117	±	146^†† †† =p≤0.01.	70	17 – 163	62	±	95^†† †† =p≤0.01.	25	0 – 88	<0.001
Pasta	85	±	116	40	0 - 133	104	±	128^† † Z-test of all participants in relation to the plausible reporters and under-reporters, where †=p≤0.05;	64	0 – 161	74	±	106	32	0 – 107	<0.020
Fruits	65	±	73	44	0 – 104	74	±	83	50	0 – 120	59	±	65	40	0 – 95	<0.170
Leaf vegetables	5	±	8	3	0 – 8	5	±	7	3	0 – 8	6	±	9	4	0 – 7	<0.750
Vegetables	13	±	22	9	2 – 17	15	±	21	9	2 – 18	12	±	22	7	1 – 15	<0.060
Beans and high-protein plants	94	±	112	62	22 – 121	127	±	132^†† †† =p≤0.01.	85	28 – 182	74	±	92^†† †† =p≤0.01.	49	21 – 91	<0.001
Meats, seafood, and eggs	383	±	235	340	219 – 520	497	±	269^†† †† =p≤0.01.	458	306 – 640	314	±	178^†† †† =p≤0.01.	279	195 – 430	<0.001
Milk and dairy products	127	±	130	107	48 – 174	167	±	174^†† †† =p≤0.01.	136	76 – 211	103	±	84^†† †† =p≤0.01.	93	40 – 148	<0.001
Fast foods	119	±	174	46	0 – 171	161	±	214^†† †† =p≤0.01.	88	0 – 226	94	±	138^†† †† =p≤0.01.	28	0 – 134	<0.010
Sweets	301	±	341	209	80 – 391	503	±	429^†† †† =p≤0.01.	412	228 – 646	176	±	185^†† †† =p≤0.01.	132	41 – 253	<0.001
Processed salty foods	188	±	172	142	71 – 258	259	±	217^†† †† =p≤0.01.	191	95 – 356	144	±	118^†† †† =p≤0.01.	123	52 – 201	<0.001
Beverages	161	±	154	118	63 – 204	229	±	196,	162	99 – 301	120	±	103^†† †† =p≤0.01.	98	50 – 155	<0.001
Energy and Nutrients	Mean	±	SD	Median	Quartiles	Mean	±	SD	Median	Quartiles	Mean	±	SD	Median	Quartiles	p ^* * <0.05 according to the Mann-Whitney test between reported energy intake for plausible reporters and under-reporters;
Reported energy intake (Kcal)	1984	±	646	1863	1543 – 2276	2563	±	611^†† †† =p≤0.01.	2474	2081 – 2912	1629	±	334^†† †† =p≤0.01.	1616	1410 – 1856	<0.001
Carbohydrates (g)	226	±	85	209	165 – 263	295	±	88^†† †† =p≤0.01.	282	234 – 346	183	±	46^†† †† =p≤0.01.	180	150 – 213	<0.001
Proteins (g)	99	±	28	93	80 – 114	119	±	28^†† †† =p≤0.01.	117	100 – 133	86	±	18^†† †† =p≤0.01.	86	74 – 96	<0.001
Fats (g)	76	±	26	71	59 – 88	97	±	27^†† †† =p≤0.01.	93	81 – 112	63	±	14^†† †† =p≤0.01.	62	54 – 72	<0.001
Fibers (g)	16	±	7	15	12 – 19	20	±	8^†† †† =p≤0.01.	18	15 – 22	14	±	4^†† †† =p≤0.01.	13	11 – 16	<0.001
Calcium (mg)	629	±	312	570	438 – 745	789	±	398^†† †† =p≤0.01.	703	553– 892	530	±	185^†† †† =p≤0.01.	506	400 – 644	<0.001
Vitamin C (mg)	81	±	42	69	53 – 96	88	±	49	73	58 – 105	77	±	37	65	52 – 90	<0.004

Brasil

Brasil

The under-reporting of energy intake influences the dietary pattern reported by obese women in the waiting list for bariatric surgery

A subnotificação do consumo energético influencia os resultados de padrão alimentar relatado por mulheres obesas na fila de espera para cirurgia bariátrica

ABSTRACT

Objective

Methods

Results

Conclusion

RESUMO

Objetivo

Métodos

Resultados

Conclusão

INTRODUCTION

CASES AND METHODS

Subjects and General Information Variables

Anthropometric and Energy Expenditure Variables

Food Intake Variables

Physical Activity Level-Related Variables

Determination of Energy Intake Under-reporting

Statistical Analysis

RESULTS

DISCUSSION

CONCLUSION

ACKNOWLEDGMENTS

Como citar este artigo/How to cite this article

REFERENCES

Publication Dates

History