Study design and scope

SEANUTS II Malaysia was designed as a cross-sectional study to obtain comprehensive nutrition information of children aged 0·5 to 12·9 years from six regions of Malaysia, namely Central, East Coast, Northern, and Southern regions of Peninsular Malaysia, as well as Sabah and Sarawak. Data collection, employing multistage cluster sampling approach, was conducted from May 2019 to March 2020.

The first stage of sampling was the selection of districts. In each region, two districts (one urban and one rural) from different states were randomly selected by the Department of Statistics of Malaysia (DOSM) to represent the respective regions. The selected urban areas are gazetted areas with their adjoining built-up areas that have a combined population of 10 000 and above⁽¹³⁾, including: Kuala Lumpur Federal Territory (Central region); Kuantan, Pahang (East Coast region); the Northeast district of Penang Island (Northern region); Seremban, Negeri Sembilan (Southern region); Kota Kinabalu (Sabah); and Kuching (Sarawak). As for the rural areas, gazetted or non-gazetted areas with population less than 10 000⁽¹³⁾ were selected: the districts of Kuala Langat, Selangor (Central region); Pasir Mas, Kelantan (East Coast region); Kerian, Perak (Northern region); Kota Tinggi, Johor (Southern region); Kinabatangan (Sabah); and Serian (Sarawak).

The second stage was sampling within the selected districts. In each district, DOSM provided a list of randomly selected enumeration blocks for the sampling of home-based participants. Subjects were recruited from all districts within a 5 km radius from each selected enumeration block, using either home-based or school-based approaches. A home-based approach was conducted for children aged 0·5 to 6·9 years who were not attending primary schools. The children were recruited primarily through home visits. For young children who were attending preschools, data collection was conducted at their nurseries or kindergartens. Children aged 7·0 to 12·9 years were recruited from primary schools within the selected areas.

Sample size estimation

To ensure that the sample size (based on prevalence) was adequate, the following formula was used^{(Reference Suresh and Chandrashekara14)}:

$$n = {{{{\left( {{Z_{1 - { \propto \over 2}}}} \right)}^2}\rho \left( {1 - \rho } \right)} \over {{d^2}}}\; \times \rm DEFF\;$$

The power analysis for estimating the number of children (n) was based on the six regions of study location. Obesity prevalence ( $\rho$ ) of Malaysian children was taken from SEANUTS I Malaysia^{(Reference Poh, Ng and Haslinda7)}. The obesity prevalence was 11·8 %^{(Reference Poh, Ng and Haslinda7)}, $\rho $ was set to 0·12. $Z$ was the critical value of 1·96 for the corresponding 95 % confidence level ( $ \propto $ : 0·05), while $d$ was the tolerable error of 6 %. The calculated number was 113 and was adjusted for design effect (DEFF) of 2, resulting in a sample of 225 for each region. In anticipation of a 70 % completion rate (based on unpublished results from SEANUTS I), the final sample for each region was calculated (225 × 100/70) and the final sample size for each region was determined to be 322. For the six regions, a total of (322 × 6) or 1932 children were required for each recruitment approach (i.e. the home- and school-based approaches). Therefore, the final required sample for this study was doubled (1932 × 2) to 3864.

A subsample of children aged 4 years and above was recruited for nutritional biomarkers analysis. According to SEANUTS I Malaysia, of all the nutritional biomarkers, the prevalence of vitamin D deficiency was the highest^{(Reference Poh, Ng and Haslinda7)}. Hence, this prevalence was used to calculate the size of the SEANUTS II Malaysia subsample for the nutritional biomarkers study. Using the same formula as above, based on the prevalence of vitamin D deficiency, $\rho $ was 0·04^{(Reference Poh, Ng and Haslinda7)}, $ \propto $ was 0·05, z was 1·96, $d$ was 9 % and design effect was 2. The sample of each region was 36. In anticipation of a 50 % response rate, the final sample of each region was determined to be (36 × 100/50) or 72. A total of 432 children were required for each of the two recruitment approaches. Thus, a final subsample of 864 was needed for the nutritional biomarker study.

In early 2020, SEANUTS II Malaysia was in the midst of data collection when the COVID-19 pandemic began. Recruitment of subjects was halted. Data collection of subjects from two regions in East Malaysia, namely Sabah and Sarawak, was not yet conducted at that point in time. Data collection from children in four regions of Peninsular Malaysia, namely the Central, Northern, Southern and East Coast regions, had been completed just a couple of weeks prior to the announcement on 16 March 2020 of the COVID-19 pandemic movement control order in Malaysia. Hence, the final pool of subjects in this study consisted only of children aged 6 months to 12 years in Peninsular Malaysia. Figure 1 shows the flow diagram of subject recruitment, including response rate, subject exclusion and the final number of valid subjects for data analysis.

Fig. 1 Flow diagram of subject recruitment

Subjects

Children must be of Malaysian nationality and aged between 6 months and 12 years to be included in this study. The number of boys and girls recruited were in accordance with the national gender ratio for their area of residence (urban/rural). Children who were unwell on the measurement day, had a physical disability, or presented with medical history or illness that could have impacted their usual diet and physical activity were excluded from the study. If there were two or more siblings who fulfilled the study inclusion criteria, only one of the siblings was recruited to participate in the study. Based on the age of the subjects at the time of measurement, they were then categorised as either infants (0·5–0·9 years), toddlers (1·0–3·9 years), preschoolers (4·0–6·9 years) or school-aged children (7·0–12·9 years).

Ethics approval and permission for data collection

The protocols and materials of the present study were reviewed and approved by the Universiti Kebangsaan Malaysia Research Ethics Committee. Written informed consent was obtained from a parent or guardian prior to a child’s participation in the study, and verbal assent was obtained from each child before data collection. This study was conducted according to the principles set forth in the Declaration of Helsinki. It is registered in the Dutch Trial Registry (Reference: NL7975). Permission to conduct data collection was obtained from all relevant parties, including the Malaysian Ministry of Education, Departments of Education at the state level, the Department of Community Development (KEMAS) under the Ministry of Rural Development, the Department of National Unity and Integration under the Ministry of National Unity, school principals, kindergartens, and nurseries, as well as community leaders.

Data collection procedure

A detailed description of the study protocol is described in the SEANUTS II study design paper^{(Reference Tan, Poh and Sekartini15)}. Prior to the commencement of data collection, all research team members and enumerators underwent comprehensive training on all assessment methods and study procedures. Data collection of all measurements were scheduled after a parent or guardian gave consent and completed the sociodemographic questionnaire. Prior to the day of data collection, parents or guardians were reminded and asked to ensure their children were dressed in sports attire on the day of measurement. On the day of data collection, the children were assigned to stations for anthropometric measurement and dietary recall. Child anthropometric measurements were measured by trained researchers. Dietary recall interviews were conducted with parents/caregivers for children below 10 years old and directly with children aged 10 to 12 years. When necessary, telephone calls to a parent or guardian were made to verify and complete the questionnaire, as well as to conduct dietary recall interviews for children aged below 10 years. Blood withdrawal was conducted among a subsample on a separate day. Subjects who completed the physical measurements and questionnaires were given a health report, a certificate of participation and a small token of appreciation.

Anthropometric measurements

All anthropometric measurements were done using standardised procedures by trained researchers. Bi-yearly technical error of measurement for anthropometric assessment was also conducted to ensure intra- and inter-observer variations were minimal among researchers. Measurements were taken in duplicates, and the average value was used as the final value. In cases where deviation between the two readings was higher than the maximum allowable difference, a third measurement was taken, and the median was used as the final value. Children were asked to dress in light clothing, with shoes not worn during measurement.

Body weight was measured using SECA 354 digital weighing scale (seca GmbH) to the nearest 0·005 kg for infants, or SECA 874 (seca GmbH) to the nearest 0·05 kg for older children. Recumbent length for children aged below 2 years was measured using SECA 210 measuring mat (seca GmbH) or SECA 417 infantometer (seca GmbH) to the nearest 0·1 cm. Standing height of older children was measured using SECA 213 stadiometer (seca GmbH) to the nearest 0·1 cm. The maximum allowable difference was set at less than 0·1 kg for body weight and less than 0·5 cm for height or recumbent length. BMI was calculated by dividing the measured weight (in kg) by the square of height (in metre).

The anthropometric status of subjects was classified using the WHO child growth standards for 0–5 years⁽¹⁶⁾ and the WHO growth reference for 5–19 years⁽¹⁷⁾. Z-scores for weight-for-age (WAZ), height-for-age (HAZ), BMI-for-age (BAZ) and weight-for-height (WHZ) were determined using WHO Anthro version 3.2.2 (WHO) software for children aged below 5 years⁽¹⁸⁾. For children aged 5 years and above, the WHO AnthroPlus version 1.0.4 (WHO) software was used to determine the WAZ, HAZ and BAZ⁽¹⁹⁾. The cut-off values for wasting, stunting and thinness for all children are -2 sd. The cut-off values for overweight and obesity among children aged below 5 years are +2 sd and +3 sd, respectively, whereas the cut-off among children aged 5 years and above are +1 sd and +2 sd, respectively, as defined by the WHO^(16,17) . Sixteen children with implausible Z-score values were excluded, when WAZ < -5 sd or WAZ > 5 sd, HAZ < -6 sd or HAZ > 6 sd, WHZ < -6 sd or WHZ > 5 sd, or BAZ < -5 sd or BAZ > 5 sd ^(19,20) .

Assessment of dietary intake

Dietary intake was assessed using 1-d triple-pass 24-h dietary recall interview from 12 am to 12 am the following day^{(Reference Nightingale, Walsh and Olupot-Olupot21)}. Parents, guardians or caregivers were encouraged to capture images of all food consumed by the children on the day prior to the dietary recall interview. Additionally, a probing guide was used to help recollect foods that might typically be overlooked or forgotten during the interview. In cases where children encountered difficulties recalling, any uncertainties were resolved through seeking clarifications from parents/guardians/caregivers. Household measures were used as portion size estimation aid during the interviews. For subjects aged 6 months to 9 years, dietary recall was proxy-reported by either parents, guardians or caregivers through face-to-face or telephone interview (with a soft copy of the household measurement booklet for reference). Dietary intake for children aged 10 to 12 years old was self-reported through face-to-face interviews conducted during school visit days. Nutrient analysis was conducted using Nutritionist Pro software (Axxya Systems), with nutrient values obtained mainly from the Malaysian Food Composition Database^{(Reference Tee, Ismail and Mohd Nasir22)}, and supported by USDA⁽²³⁾, UK^{(Reference Greenfield and Southgate24)}, FOCOS⁽²⁵⁾, and food product labels.

Energy and nutrient intake values were compared with estimated average requirement (EAR) and recommended nutrient intake (RNI) 2017 for Malaysia⁽²⁶⁾. EAR was derived from the Malaysian RNI by subtracting twice the CV provided by the Institute of Medicine (IOM)^{(27–Reference Ross, Manson and Abrams30)}. If RNI and EAR were unavailable, adequate intake as reported in the Malaysian RNI⁽²⁶⁾ was used. The EAR for Fe was calculated from the total absolute requirement at the median level provided by the WHO/FAO (2004)⁽³¹⁾ as shown below:

$${{\rm{EAR}}\ {\mkern 1mu} {\rm{for}}\ {\mkern 1mu} {\rm{iron}} = {{{\rm{Total\ absolute\ requirement}}\ \left( {{\rm{median}}} \right)} \over {\% \ {\rm{bioavailability}}}} \times 100}$$

where Total absolute requirement = Requirement for growth, basal losses + menstrual losses⁽³¹⁾, % bioavailability =15 %

Prior to dietary data analysis, the ratio of reported energy intake (EI) and predicted energy expenditure (EE) was calculated based on the Black and Cole formula^{(Reference Black and Cole32)} to exclude implausible data reporting. EE was estimated on the multiplication of BMR^{(Reference Schofield33–Reference Poh, Ismail and Ong35)} and physical activity level (PAL)^{(Reference Torun, Davies and Livingstone36)}. For PAL value in the formula, children were assumed to have a moderate level of physical activity (children aged 0·5–5·9 years: PAL 1·60; boys aged 6·0–12·9 years: PAL 1·75; girls aged 6·0–12·9 years: PAL 1·70)^{(Reference Torun, Davies and Livingstone36)}. According to the formula proposed by Black and Cole^{(Reference Black and Cole32)}, 99 % CI, 8·2 % of within-subject variation in EE and 23 % of within-subject variation in EI were applied in the present study^{(Reference Black37)}:

$$99\% {\rm{CI}} = \pm 3 \times \sqrt {\left( {{\rm {CVwE{I^2}} \over d} + (\rm CVw{EE^2})} \right)} $$

where CV wEE = within-subject variation in of EE, 8·2 %, CV wEI = within-subject variation in EI, 23 %, and d = number of days of diet assessment.

The final acceptable reporting range was 0·27–1·73, and only subjects with EI:EE ratio within this range were included for further dietary analysis. A total of 108 children with under- or over-reporting were excluded. Nutrient analysis did not include intake of dietary supplements.

Sociodemographic questionnaire

A questionnaire was used to collect data regarding sociodemographic background. All questions were self-administered by parents or guardians in Malay–English or Mandarin–English language versions. The sociodemographic questionnaire (SES) comprised thirty-three items requesting both child and parents’ or guardians’ information, as well as total household monthly income information.

Analysis of nutritional biomarkers

The nutritional biomarkers investigated in SEANUTS II Malaysia included full blood count, Hb, Fe, ferritin, transferrin saturation, alpha-1-acid glycoprotein (AGP), C-reactive protein (CRP), vitamin B₁₂, vitamin A, vitamin D, and fasting blood glucose levels, as well as lipid profile and metabolomics, as described by Tan et al.^{(Reference Tan, Poh and Sekartini15)}, though this paper will focus only selected parameters. In a subsample of children aged 0·5 to 3·9 years, Hb was measured using the finger-prick method following standardised protocols. Approximately 10 μL of capillary blood was collected in the microcuvette for measurement by HemoCueHb201+ system (HemoCue AB).

Venous blood was drawn by trained phlebotomists from a subsample of children aged 4 years and above for nutritional biomarkers analysis. The children who were involved in nutritional biomarkers analysis were required to fast overnight for 8–10 h before blood withdrawal the following morning. Approximately 13 mL of venous blood were drawn and aliquoted into BD Vacutainer^® SST^TM, EDTA and fluoride tubes. The collected blood samples were kept at 4°C in a standard storage box with ice packs and transported immediately to an accredited lab. Standard methods of lab analysis, such as flow cytometry (Hb), spectrophotometry (CRP and ferritin), ECLIA [vitamin B₁₂ and vitamin D (25(OH)D)] and liquid–liquid extraction (vitamin A), were conducted. Serum AGP was measured according to the manufacturer’s instructions using commercial ELISA kit (Immunology Consultants Laboratory, Inc.).

Anaemia was defined as Hb level < 110 g/L for children aged < 5 years, < 115 g/L for children aged 5–11·9 years and < 120 g/L for children aged ≥ 12 years⁽³⁸⁾. Fe deficiency was defined as ferritin level < 12 µg/L for children < 5 years and < 15 µg/L for children ≥ 5 years⁽³⁹⁾. Ferritin level was adjusted by multiplying a correction factor of 0·77 for incubation stage (CRP > 5 mg/L; AGP ≤ 1 g/L), 0·53 for early convalescence stage (CRP > 5 mg/L; AGP > 1 g/L) and 0·75 for late convalescence stage (CRP ≤ 5 mg/L; AGP > 1 g/L)^{(Reference Thurnham, McCabe and Haldar40)}. Serum retinol level 0·35–0·70 µmol/L was defined as mild vitamin A deficiency and < 0·35 µmol/L as severe vitamin A deficiency⁽⁴¹⁾. Serum 25(OH)D < 50 nmol/L and < 25 nmol/L were defined as vitamin D insufficiency and deficiency^{(Reference Misra, Pacaud and Petryk42)}, respectively, while vitamin B₁₂ level < 150 pmol/L was defined as vitamin B₁₂ deficiency^{(Reference de Benoist43)}.

Data management and statistical analysis

Data were transferred from paper forms and questionnaires into an online electronic data capture system (Viedoc Technologies). The quality of data collected was checked in two steps: first, by data checking all entries in Viedoc against paper forms and questionnaires and then rechecking 20 % of the Viedoc entries against paper forms to validate the first-round data entry.

Statistical analyses were performed using IBM SPSS Statistics for Windows version 22.0 (IBM Corp.), employing the complex sampling module. Weight factor was calculated based on the projected Malaysian population aged 6 months to 12 years in 2019, using the Malaysian census database in 2010⁽⁴⁴⁾. Descriptive analysis was performed and presented as mean and standard error. ANCOVA after adjusting for age was used to examine the mean difference of anthropometric measurements, dietary intake, and nutritional biomarkers between sexes and between areas of residence. Nutritional status, nutritional biomarkers deficiency and children not achieving dietary recommendations were reported in percentages. Pearson’s Chi-square was performed to examine the percentage difference in nutritional status, nutritional biomarkers deficiency, and achievement of dietary intake recommendations between boys and girls, as well as between urban and rural children. Significance was determined using two-sided tests, where p-value less than 0·05 indicated statistical significance.