Study design and population

This is a cross-sectional study, part of the base project entitled ‘Population-Based Health Survey (ISAD-PI)’, carried out from August 2018 to December 2019, in the cities of Teresina and Picos, in the state of Piauí.

This research included adults from 20 to 59 years of age and elderly people aged 60 years and over from the city of Teresina, Piauí. Individuals residing in private households were eligible for the study, except individuals residing in collective households, pregnant women and those with a disability that would make it impossible to carry out the research.

Sample size

The study sample was selected through a cluster sampling process in two stages: primary sampling units (UPA), composed of census sectors, and in the second stage, households, based on IBGE census data for the year of 2010⁽¹⁰⁾.

To calculate the sample size, we considered the size of the population and the number of private households in Teresina (767 557 inhabitants; 210 093 households)⁽¹⁰⁾. From these data, the mean number of individuals for both sexes, per household, in each of the following age groups was calculated: children under 2 years of age; children aged 3–4 years; children aged 5–9 years; adolescents aged 10–14 years; adolescents aged 15–19 years; adults aged 20–59 and elderly people over 60. A necessary total number of 578 households were then estimated. The final sample size for this study was adjusted using n = n₀/0·90, assuming a response rate of 90 %, resulting in n ≅ 642 households.

Following the same sampling plan, 50 % of the households were selected, forming a subsample for the collection of food consumption data, through the application of 24-h recalls, as well as for blood analysis. More details about the sample size and sampling plan of the ISAD-PI were published in the study by Rodrigues et al. ^{(Reference Rodrigues, Costa e Silva and Oliveira11)}

After completing the survey, the final sample included 497 households in Teresina, and the subsample consisted of 248 households. In the end, data were obtained from 229 individuals, 90 participants aged 20–39 years and 139 aged 40 years or older, who had food consumption and biochemical data (Fig. 1). The present study was approved by the Ethics and Research Committee of the Federal University of Piauí, under Opinion 2,552,426.

Fig. 1. Study sample flow chart.

Fig. 2. Energy contribution (%) of unprocessed or minimally processed and ultra-processed foods according to serum levels of vitamin D.

Fig. 3. Energy contribution (%) of unprocessed or minimally processed and ultra-processed foods according to serum levels of vitamin D and sex.

Data collection and anthropometric measurements

Demographic, socio-economic, anthropometric, lifestyle, skin colour, sun exposure, vitamin D supplementation, physical activity, chronic kidney disease and food consumption data were collected using structured questionnaires applied by trained interviewers using the Epicollect 5^® application on mobile devices.

Anthropometry was performed according to the recommendations by Cameron^{(Reference Cameron and Cameron12)} and Jelliffe & Jelliffe^{(Reference Jelliffe, Jelliffe, Jelliffe and Jelliffe13)}. To weigh the participants, a portable electronic scale (SECA^®, model 803) with a precision of 100 g was used, and a stadiometer (SECA^®, model messband 206) was used to measure height, with an accuracy of 0·1 cm. The BMI for adults was classified according to the WHO⁽¹⁴⁾ and for the elderly, the values established by Lipschitz et al. ^{(Reference Lipschitz15)}

Dietary assessment

The food consumption of the studied population was obtained through the application of the 24-h food recall (24hR), based on the multiple-pass method^{(Reference Moshfegh, Rhodes and Baer16)}. A second 24hR was applied to 40 % of the population, in a 2-month interval, in which the same procedures that were used during the first interview were performed, with the aim of correcting intrapersonal variability. The replication rate was chosen based on the research by Verly-Júnior et al. ^{(Reference Verly-Júnior, Castro and Fisberg17)}, in which it can be observed that the application of a second 24hR in 40 % of the sample did not mean loss of accuracy for estimating food consumption, regardless of sample size.

Home measurements reported by interviewers were transformed into g or ml using the Table for the Evaluation of Food Consumption in Home Measurements, based on the study by Pinheiro et al. ^{(Reference Pinheiro, Lacerda and Benzecry18)} Energy intake was calculated based on the Brazilian Food Composition Table⁽¹⁹⁾, the Nutritional Composition Table of Food Consumed in Brazil⁽²⁰⁾ and the Food Composition Table: Support for Nutritional Decisions^{(Reference Philippi21)}.

The reported food items were categorised according to the NOVA food classification^{(Reference Monteiro, Cannon and Levy22)} based on the extent and purpose of the applied food processing, including unprocessed or minimally processed foods and UPP for the analyses. Unprocessed (or natural) foods are edible parts of plants (seeds, fruits, leaves, stems, roots) or of animals (muscle, offal, eggs, milk), and also fungi, algae and water, after separation from nature.

Minimally processed foods are unprocessed foods submitted to processes such as removal of inedible or unwanted parts of the food, drying, dehydration, crushing or grinding, fractioning, roasting, cooking with water only, pasteurisation, refrigeration or freezing, packaging, vacuum packaging, non-alcoholic fermentation and other processes that do not involve the addition of substances such as salt, sugar, oils or fats to unprocessed food, for example, wheat grains are transformed into flour, couscous and pasta, maize grains into flour and polenta, coffee beans are roasted and ground, milk is pasteurised and meat is chilled or frozen^{(Reference Monteiro, Cannon and Levy22,23)} .

The NOVA classification system defined UPP as industrial formulations typically made with five or more ingredients. These ingredients often include substances and additives used in the manufacture of processed foods such as sugar, oils, fats and salt, as well as antioxidants, stabilisers and preservatives, including soft drinks, milk drinks, fruit nectar, powder mixes for making drinks with fruit flavour, packaged snacks, sweets and chocolates, ‘cereal’ bars and ice cream^{(Reference Monteiro, Cannon and Levy22,23)} . Consumption of food groups was evaluated as a percentage of the total energy value of the participants’ diets, and all food consumption analyses were performed using the Stata software (version 13.0).

Nutrients were adjusted for intrapersonal variability, using the statistical modelling technique of the Multiple Source Method software version 1.0.1, from the Department of Epidemiology of the German Institute of Human Nutrition Potsdam-Rehbrücke (DIfE), Nuthetal, Brandenburg, Germany, 2011^{(Reference Harttig, Haubrock and Knüppel24)}.

Usual food consumption is estimated by the Multiple Source Method through short-term measurement data, such as the 24hR, through statistical modelling that consists of three steps^{(Reference Haubrock, Nöthlings and Volatier25)}, simplified as follows: In the first step, it is estimated the individual’s probability of consuming a food or nutrient ( $p_i^*$ ) and the intrapersonal and interpersonal variance by logistic regression, where ${m_{i/z}}$ is the individual’s consumption probability prediction model, ${g_{back}}$ is the corresponding residue after inverse transformation and ${\hat t_i}$ is the variance correction of the individual’s consumption probability^{(Reference Haubrock, Nöthlings and Volatier25)}: ${\rm{\;}}p_i^* = {m_{i/z}} + {g_{back}} + \left( {{{\widehat t}_i}} \right).{\rm{\;}}$

The second step is to estimate the individual’s observed consumption ( $Y_i^*$ ) and the intra-individual and inter-individual variance by means of linear regression, where ${M_{i/z}}$ is the prediction model of the day of observed consumption, ${F_{back}}$ is the residual corresponding after inverse transformation and ${\widehat T_i}\;is\;$ the variance correction of the individual’s observed consumption (Haubrock et al. ^{Reference Haubrock, Nöthlings and Volatier25} ): $Y_i^* = {M_{i/z}} + {F_{back}} + \left( {{{\widehat T}_i}} \right).$ Finally, in the last step, the usual food consumption for the individual is estimated by multiplying the data obtained in the previous steps, that is, $p_i^*$ and $Y_i^*$ ^{(Reference Haubrock, Nöthlings and Volatier25)}: $p_i^*\; \times \;Y_i^*.{\rm{\;}}$

Vitamin D analysis

Blood samples (15 ml) were collected by a trained professional and subsequently the plasma was separated and transported to the Micronutrient Laboratory of the São Paulo School of Public Health (FSP/USP), where the plasma concentrations of calcidiol–25 were determined. (OH) D3 by HPLC, according to the Vitamin D Standardisation Program, and as adapted from the method described by Neyestani et al. ^{(Reference Neyestani, Gharavi and Kalayi26)}. Calcidiol values ≤ 20 ng/ml were classified as vitamin D deficient, according to the Endocrinology Society of the United States^{(Reference Holick27)}.

Statistical analysis

The STATA program version 13.0 (Stata Corporation) was used for statistical analysis. Pearson’s χ ² test was used to determine socio-demographic and anthropometric characteristics according to the serum concentrations of vitamin D. The Shapiro Wilk test was used to assess data distribution, and Student’s t test was used to compare means. To verify the association between the consumption of UPP and the vitamin D biomarker, the population was distributed according to tertiles of the contribution of UPP to the diet (percentage of energy intake). Crude and adjusted binary logistic regression was applied to estimate the association between the consumption of UPP and vitamin D deficiency. To control for confounding, the independent variables included in the adjusted model were identified through the construction of the directed acyclic graph in DaGitty software version 3.0. Based on the backdoor criterion^{(Reference Textor, Hardt and Knuppel28)}, the need for a minimum adjustment for age, sex, skin colour, sun exposure, vitamin D supplementation, physical activity, BMI and chronic kidney disease was identified. The significance level adopted was 5 %.