The 1993 Pelotas Birth Cohort Study

Pelotas is a medium city in southern Brazil with a population of approximately 330 000 inhabitants, being located near the Uruguayan border. Its main economic activities are rice production, commerce and education. The 1993 Pelotas Birth Cohort Study is a population-based study of which the initial sample comprised 99 % of all live births that occurred in the urban area of the city from 1 January to 31 December in 1993 (n 5265)^{(Reference Victora, Araujo and Menezes9)}. The initial cohort comprised of 5249 eligible children (99·7 %). Follow-ups have been conducted periodically since 3 months of age to assess several socioeconomic, health and nutritional features of the participants. The Pelotas Birth Cohorts provide a complete coverage of the Pelotas city population, which has characteristics similar to other Brazilian cities in terms of demographic, socioeconomic and behavioural characteristics (e.g., maternal skin colour, education and obesity rates)^{(10,Reference Goncalves, Wehrmeister and Assuncao11)} . The methodological aspects of the study protocol and follow-ups have guaranteed its internal validity. More details about the cohort can be found elsewhere^{(Reference Victora, Araujo and Menezes9,Reference Goncalves, Wehrmeister and Assuncao11,Reference Goncalves, Assuncao and Wehrmeister12)} .

At the 22-year follow-up (2015), all participants were invited to attend an appointment at the research clinic. A total of 3810 participants attended, provided informed consent and underwent a series of assessments, which consisted of questionnaires, anthropometric measurements and blood sample collection. Identification of mortality among cohort participants was based on official records. The final cohort follow-up rate was estimated at 76·3 %, including 164 known deaths.

Validation study protocol

The 3810 participants individually answered a computer-based, self-administered, semi-quantitative FFQ^{(Reference Schneider, Motta and Muniz13)}. Immediately afterwards, a 24HR was administered in-person to a random sample of participants. Follow-up for a second recall by telephone occurred 14–28 d later without prior notice. To this end, participants confirmed their telephone numbers and a suitable time and day of the week for the call to be made, but the interview was not scheduled for a specific day. Up to three telephone calls were made to obtain recall information. Participants who did not answer the telephone were considered losses. Five research assistants received training that consisted of a theoretical course followed by a practical application of in-person and telephone 24HR. Two trained assistants conducted in-person interviews, and a further three did telephonic interviews. All recalls were reviewed by two research dietitians to check for missing information and ensure quality control. The sample size of this validation study (n 200) was based on the recommendation of validation studies^{(Reference Willet1)}. The inclusion of an additional 100 subjects was allowed to overcome possible inconsistencies between recalls and loss to follow-up. The final sample comprised of 301 subjects.

Semi-quantitative FFQ

A computer-based, semi-quantitative FFQ was developed to be used on the 18th year of follow-up of the 1993 Pelotas Birth Cohort^{(Reference Schneider, Motta and Muniz13)} based on the paper version of a validated Brazilian FFQ^{(Reference Sichieri and Everhart14)}, adapted to the cohort after carrying out a sub-study when the participants were 15 years of age. That previous study has been reported elsewhere^{(Reference Gigante, Reichert and Hallal15)}. The electronic platform comprises all the food items included in the paper version of the FFQ^{(Reference Gigante, Reichert and Hallal15)}. Four additional food items were included in the new version, considering current changes in the food market (e.g., soya milk, cereal bars, raw fish), and one item was split into two (sodas with or without caffeine) to allow additional investigations. The methodological description of the revised FFQ has been reported elsewhere^{(Reference Schneider, Motta and Muniz13)}.

Participants used the FFQ platform in a room with computers at the research clinic. A trained research assistant individually explained how subjects should use the platform, even though the initial part of the platform provides instructions on how to fill out the questionnaire. This was done with the aim of minimising data entry errors and maximising data quality. For each food item, participants were asked first about the frequency of intake. When the consumption of a given item was confirmed, the platform provided photographic images to identify the usual portion size (small, medium or large). The FFQ recall period was the previous 12 months.

The FFQ comprised ninety-two food items clustered into eleven food groups (bread, biscuits and cereals; rice; beans and other legumes; milk and dairy products; fruit; vegetables and potatoes; meat and eggs; sweets and candies; beverages; fats (butter, margarine, mayonnaise), and eight frequency options were given: (i) five or more times a day, (ii) two to four times a day, (iii) once a day, (iv) five to six times a week, (v) two to four times a week, (vi) once a week, (vii) one to three times a month and (viii) never or less than once a month. Fruit seasonality was taken into consideration in the annual estimation of consumption by dividing the reported consumption by four. The options for daily frequencies were as follows: (i) 5, (ii) 2, (iii) 1, (iv) 0·7, (v) 0·28, (vi) 0·14, (vii) 0·03, (viii) 0 times per day.

24-h diet recalls

To conduct both in-person and telephonic 24HR, a structured interview guide was developed based on the Automated Multiple-Pass Method^{(Reference Moshfegh, Rhodes and Baer16,Reference Blanton, Moshfegh and Baer17)} . A paper version of the 24HR was created for both recall interviews. The dietary recall steps were as follows: (i) request a quick recall of foods and beverages consumed in the last 24 h, starting from the morning of the previous day; (ii) prompt the respondent to food and meal events possibly forgotten during quick recall; (iii) go through each food item recalled requesting details using a standardised list of possible ingredients (e.g., added oils, cream, sugar), food brand, preparation and portion size; (iv) read the list of all foods and meal events as a final reminder and ask if they consumed anything else. The day and time of each telephone attempt were also recorded.

Information on time, meal event (breakfast, morning snack, lunch, afternoon snack, dinner, supper, dawn snack) and place (home, restaurant, snack bar, lunch bag) was obtained for each food item reported. Portion sizes were converted into grams or millilitres using a standard reference table^{(Reference Pinheiro, Lacerda and Benzecry18)}. All these data (food item, meal event, place, portion size) from the 24HR were coded and entered twice by two research assistants onto an Excel spreadsheet. The two data entries were compared with search for possible inconsistencies and typing mistakes (e.g. number of food items by participants, portion size and food codes). All inconsistencies identified were solved by reviewing the paper recall by the research dietitian coordinator. The final version of the dataset was exported to STATA 15.0 (StataCorp).

Energy, nutrient and food group intake estimation

For both the FFQ and the average of two 24HR, daily energy and fifteen nutrient intakes were estimated using mainly the Brazilian Food Composition Table⁽¹⁹⁾, complemented with food items from the US Department of Agriculture’s National Nutrient Database for Standard Reference⁽²⁰⁾. In addition to energy and macronutrients, we estimated dietary fibre, Ca, Fe, thiamine, riboflavin, niacin, vitamin C, Na and cholesterol, as these nutrients are widely assessed in validation studies due to their importance in chronic nutritional deficiencies^{(Reference Willet1)}. Energy and nutrients from dietary supplements were excluded. Food groups were estimated by converting daily portion sizes reported of each food item into grams and combining individual items into the eleven FFQ food groups (described above).

Characteristics of the participants

Participants were described according to sex (female, male), current marital status (single, married), employment status (employed, unemployed), education (years of completed formal schooling) and current smoking habit (no, yes). These data were obtained via questionnaires applied during the cohort’s 22-year follow-up^{(Reference Goncalves, Wehrmeister and Assuncao11)}. Nutritional status was classified by the cut-offs of BMI (kg/m²): underweight (<18·5), normal weight (18·5–24·9), overweight (25–29·9) and obese (≥30). BMI was calculated using the weight measured to the nearest 0·1 kg (using an electronic digital scale coupled with the BOD POD system; COSMED) divided by the height measured to the nearest 0·1 com (using a portable stadiometer; C.M.S. Weighting Equipment Ltd).

Statistical analyses

Crude medians (interquartile ranges, IQR) of energy, nutrients and food groups (in grams) were estimated for FFQ as was the average of the two 24HR. To compare the dietary estimates between methods, test comparisons were conducted using the Wilcoxon rank test, considering that most nutrient and food group distributions were skewed. The relative difference between daily intake according to FFQ and the average of the two 24HR for energy, nutrients and food groups was estimated according to the formula: ((FFQ – 24HR)/24HR) × 100.

Data were transformed (log₁₀) to optimise distribution normality. Nutrient intakes were energy-adjusted using Willet’s residual method^{(Reference Willet1)}. To correct for within-individual errors in the measurement of the average of two 24HR, which tends to reduce correlation coefficients towards zero, the correlation coefficient found was multiplied by the de-attenuation factor $$\left( 1 + \left( \sigma _w^2/\sigma _b^2 \right) /n\right)^{0 \cdot 5}$$ , where $$\sigma _w^2$$ is within-individual variance, $$\sigma _b^2$$ is between-individual variance and n represents the number of replicate measurements (N 2)^{(Reference Willet1)}. Within- and between-individual variance components were determined by a random-effects model with recorded intake as a dependent variable and subject identification number as an independent variable^{(Reference Beaton, Milner and Corey21)}. The corrections of between- and within-individual variances are presented as de-attenuated correlation values.

Pearson correlation coefficients and Lin’s concordance correlation coefficients of log-transformed crude and energy-adjusted nutrient intakes were calculated. Person correlation coefficient is a measure of linear relation between two variables, without specifying any degree of correspondence between the two sets of values^{(Reference Cade, Thompson and Burley22)}. Lin’s concordance coefficient is devised to provide a measure of reliability that is based on covariation and correspondence. It takes into account bias, the element that distinguishes agreement from correlation, that is, a good agreement (reproducibility) not only requires good correlation, it also requires small bias^{(Reference Lin23)}. The following cut-offs were applied to interpret Pearson correlation coefficients: <0·30 (low), 0·3–0·5 (moderate), 0·51–0·7 (good), 0·71–0·9 (very good) and 0·9–1·0 (high)^{(Reference Willet, Lenart and Willet8)}.

Energy, nutrient and food group quartiles were calculated, and the degree of gross misclassification in the FFQ in relation to the average of two 24HR was evaluated using contingency tables, including weighted κ to test whether the FFQ ranked participants according to the magnitude of food groups and nutrient intakes by comparison with the mean of two 24HR. The proportions of individuals who were classified correctly within the same quartile or opposite quartile (lowest quartile according to one dietary method and the highest quartile according to the other) were determined. Weighted Kappa (κ) statistics were calculated to quantify the agreement of energy-adjusted nutrient intakes, and food group quartiles as measured by the FFQ and two 24HR. The following κ interpretation proposed by Landis & Koch^{(Reference Landis and Koch24)} was applied: 0·0–0·20 (slight), 0·21–0·40 (fair), 0·41–0·60 (moderate), 0·61–0·80 (substantial) and 0·81–1·0 (almost perfect).

Bland–Altman analysis was performed to provide a visual inspection of the systematic difference between methods. We plotted the differences of estimated energy and nutrients between FFQ and the average of two 24HR against the means of energy and nutrient estimates in both methods. The plots include lines for the mean difference and the so-called ‘limits of agreement’, defined as mean ± 1·96 sd of the mean. Graphs for energy and macronutrients, dietary fibre, Na, Fe and Ca are presented.

We performed further analyses of participants included in the sub-sample and those in the main cohort using the t test and χ ² test of proportions for selected sociodemographic variables (sex, schooling, total monthly family income, nutritional status and smoking status) with the aim of ruling out possible selection bias.

All statistical analyses were performed using STATA 15.0 (StataCorp).