Hostname: page-component-cd9895bd7-hc48f Total loading time: 0 Render date: 2024-12-25T06:41:43.949Z Has data issue: false hasContentIssue false

Identification and reproducibility of dietary patterns assessed with a FFQ among women planning pregnancy

Published online by Cambridge University Press:  22 March 2021

Shan Xuan Lim
Affiliation:
Saw Swee Hock School of Public Health, National University of Singapore and National University Health System, Singapore, Singapore
Marjorelee T Colega
Affiliation:
Singapore Institute for Clinical Sciences, Agency for Science, Technology and Research (A*STAR), Singapore, Singapore
M Na’im M Ayob
Affiliation:
Singapore Institute for Clinical Sciences, Agency for Science, Technology and Research (A*STAR), Singapore, Singapore
Sian M Robinson
Affiliation:
AGE Research Group, Newcastle University Institute for Translational and Clinical Research, Newcastle upon Tyne, UK NIHR Newcastle Biomedical Research Centre, Newcastle University and Newcastle upon Tyne NHS Foundation Trust, Newcastle upon Tyne, UK
Keith M Godfrey
Affiliation:
Medical Research Council Lifecourse Epidemiology Unit, University of Southampton, Southampton, UK NIHR Southampton Biomedical Research Centre, University Hospital Southampton, NHS Foundation Trust, Southampton, UK
Jonathan Y Bernard
Affiliation:
Singapore Institute for Clinical Sciences, Agency for Science, Technology and Research (A*STAR), Singapore, Singapore Université de Paris, Centre for Research in Epidemiology and StatisticS (CRESS), Inserm, INRAE, Paris, France
Yung Seng Lee
Affiliation:
Singapore Institute for Clinical Sciences, Agency for Science, Technology and Research (A*STAR), Singapore, Singapore Department of Paediatrics, Yong Loo Lin School of Medicine, National University of Singapore, Singapore, Singapore Khoo Teck Puat-National University Children’s Medical Institute, National University Hospital, National University Health System, Singapore, Singapore
Kok Hian Tan
Affiliation:
Duke-NUS Medical School, Singapore, Singapore Department of Maternal Fetal Medicine, KK Women’s and Children’s Hospital, Singapore, Singapore
Fabian Yap
Affiliation:
Duke-NUS Medical School, Singapore, Singapore Department of Paediatrics, KK Women’s and Children’s Hospital, Singapore, Singapore Lee Kong Chian School of Medicine, Nanyang Technological University, Singapore, Singapore
Lynette PC Shek
Affiliation:
Singapore Institute for Clinical Sciences, Agency for Science, Technology and Research (A*STAR), Singapore, Singapore Department of Paediatrics, Yong Loo Lin School of Medicine, National University of Singapore, Singapore, Singapore Khoo Teck Puat-National University Children’s Medical Institute, National University Hospital, National University Health System, Singapore, Singapore
Yap Seng Chong
Affiliation:
Singapore Institute for Clinical Sciences, Agency for Science, Technology and Research (A*STAR), Singapore, Singapore Department of Obstetrics and Gynaecology, Yong Loo Lin School of Medicine, National University of Singapore, Singapore, Singapore
Johan G Eriksson
Affiliation:
Singapore Institute for Clinical Sciences, Agency for Science, Technology and Research (A*STAR), Singapore, Singapore Department of Obstetrics and Gynaecology, Yong Loo Lin School of Medicine, National University of Singapore, Singapore, Singapore Department of General Practice and Primary Health Care, University of Helsinki and Helsinki University Hospital, Helsinki, Finland Folkhälsan Research Center, University of Helsinki, Helsinki, Finland
Jerry KY Chan
Affiliation:
Duke-NUS Medical School, Singapore, Singapore Department of Reproductive Medicine, KK Women’s and Children’s Hospital, Singapore, Singapore
Shiao Yng Chan
Affiliation:
Singapore Institute for Clinical Sciences, Agency for Science, Technology and Research (A*STAR), Singapore, Singapore Department of Obstetrics and Gynaecology, Yong Loo Lin School of Medicine, National University of Singapore, Singapore, Singapore
Mary FF Chong*
Affiliation:
Saw Swee Hock School of Public Health, National University of Singapore and National University Health System, Singapore, Singapore Singapore Institute for Clinical Sciences, Agency for Science, Technology and Research (A*STAR), Singapore, Singapore
*
*Corresponding author: Email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Objective:

To identify a posteriori dietary patterns among women planning pregnancy and assess the reproducibility of these patterns in a subsample using two dietary assessment methods.

Design:

A semi-quantitative FFQ was administered to women enrolled in the Singapore PREconception Study of long-Term maternal and child Outcomes study. Dietary patterns from the FFQ were identified using exploratory factor analysis (EFA). In a subsample of women (n 289), 3-d food diaries (3DFD) were also completed and analysed. Reproducibility of the identified patterns was assessed using confirmatory factor analysis (CFA) in the subsample, and goodness of fit of the CFA models was examined using several fit indices. Subsequently, EFA was conducted in the subsample and dietary patterns of the FFQ and the 3DFD were compared.

Setting:

Singapore.

Participants:

1007 women planning pregnancy (18–45 years).

Results:

Three dietary patterns were identified from the FFQ: the ‘Fish, Poultry/Meat and Noodles’ pattern was characterised by higher intakes of fish, poultry/meat and noodles in soup; ‘Fast Food and Sweetened Beverages’ pattern was characterised by higher intakes of fast food, sweetened beverages and fried snacks; ‘Bread, Legumes and Dairy’ pattern was characterised by higher intakes of buns/ethnic breads, nuts/legumes and dairy products. The comparative fit indices from the CFA models were 0·79 and 0·34 for the FFQ and 3DFD of the subsample, respectively. In the subsample, three similar patterns were identified in the FFQ while only two for the 3DFD.

Conclusions:

Dietary patterns from the FFQ are reproducible within this cohort, providing a basis for future investigations on diet and health outcomes.

Type
Research paper
Copyright
© The Author(s), 2021. Published by Cambridge University Press on behalf of The Nutrition Society

As milestones of a woman’s reproductive lifespan, the stages of preconception, pregnancy and postpartum may bring about distinct dietary changes(Reference Chen, Low and Fok1Reference Tovar, Kaar and McCurdy5). In general, increased intakes of healthier foods (e.g., fruits and vegetables) may be observed when women transit from preconception to pregnancy(Reference Hillier and Olander2), while a sharp decline in consumption of these foods tended to occur at postpartum, although these remained at higher levels compared with the preconception stage(Reference Olson4,Reference Tovar, Kaar and McCurdy5) . A similar trend has been observed locally in Singapore, such that women increased fruit and vegetable intakes but decreased tea/coffee, soft drinks and seafood intakes during pregnancy, while at postpartum they consumed more ginger, garlic, fish and milk-based drinks but less of sweets, chocolate and seafood(Reference Chen, Low and Fok1). These dietary changes, seemingly unique to the local Asian population, were found to differ by ethnicity and were based on traditional beliefs, particularly at postpartum(Reference Chen, Low and Fok1). However, these data were collected from short questionnaires with pre-defined food items. In order to systematically observe changes in dietary patterns across several time points of a woman’s reproductive lifespan and enable diet comparisons to be made, a culturally relevant and validated maternal FFQ is required.

Integrative approaches of examining diets in their entirety have been increasingly used(Reference Hu6,Reference Reedy, Subar and George7) , such as a posteriori or a priori dietary patterns. Although limited by their population specificity, a posteriori dietary patterns are valuable as they depict actual dietary intakes of populations at different stages across the lifespan(Reference Edefonti, De Vito and Dalmartello8). Additionally, these unique and well-defined patterns provide realistic representations of consumption patterns in ethnically heterogeneous populations(Reference Edefonti, De Vito and Dalmartello8). Studies examining a posteriori dietary patterns have observed that the patterns derived were generally qualitatively similar and reasonably valid across different dietary assessment methods(Reference Edefonti, De Vito and Dalmartello8Reference Togo, Heitmann and Sorensen15). In patterns identified among women planning pregnancy, a posteriori healthy dietary patterns (e.g., ‘Vegetables and Meat’(Reference Cuco, Fernandez-Ballart and Sala3), ‘Fruit and Low-fat Dairy’(Reference Schoenaker, Soedamah-Muthu and Callaway16)) and less healthy dietary patterns (e.g., ‘Sweetened Beverages and Sugars’(Reference Cuco, Fernandez-Ballart and Sala3), ‘High-fat/sugar/takeaway’(Reference Grieger, Grzeskowiak and Clifton17)) were observed, but the reproducibility of these patterns has not been examined. The few reproducibility studies on dietary patterns of Europeans have shown that the FFQ-derived patterns were reproducible in smaller samples of the same cohort(Reference Judd, Letter and Shikany18,Reference Lau, Glümer and Toft19) and similar dietary patterns were identified using two different dietary assessment methods(Reference Togo, Heitmann and Sorensen15).

To bridge the gap, we aimed to (1) identify a posteriori dietary patterns among an Asian cohort of women planning pregnancy using exploratory factor analysis (EFA) and (2) assess the reproducibility of these patterns in a subsample using two different dietary assessment methods (food frequency questionnaire (FFQ) and 3-d food diary (3DFD)). We hypothesised that the identified patterns would be reproducible in both dietary assessment methods, in a subsample.

Methods

Study design and participants

We used data from the Singapore PREconception Study of long-Term maternal and child Outcomes (S-PRESTO) study, a prospective cohort study, which aims to examine the role of exposures before conception and during pregnancy on maternal and offspring metabolic health outcomes in later life(Reference Loo, Soh and Loy20). In the S-PRESTO study, non-pregnant women actively trying to conceive were enrolled between February 2015 and October 2017, from the community (through social media and radio advertisements, door to door leaflets, posters in public places and general practitioners clinics) and at the largest local public maternity unit (KK Women’s and Children’s Hospital, Singapore). They were of Chinese, Malay, Indian ethnicity or any combination of these three ethnicities, aged 18–45 years, planned to conceive within 1 year from recruitment and to reside in Singapore for the next 5 years. Women were excluded if (1) diagnosed with type I or type II diabetes, (2) on systemic steroids, anticonvulsants or treatment for HIV, hepatitis B or C in the past month prior to enrolment, (3) already pregnant at the first screening visit, (4) had already been trying to conceive for over 18 months and (5) were on assisted fertility treatment (except clomiphene and letrozole) or on hormonal contraception treatment in the past month prior to enrolment. Further details of the current study have been published elsewhere(Reference Loo, Soh and Loy20).

Socio-demographic, lifestyle and other measures

At enrolment, trained research staff conducted in-person interviews with participants and collected information including socio-demographic (e.g., age, highest educational attainment) and lifestyle behaviours (e.g., physical activity for the past 7 d and daily total sitting time (at work and during leisure), alcohol consumption)(Reference Bernard, Ng and Natarajan21). Taken in triplicates, mean values for anthropometry measures were recorded. These measures included weight (measured to the nearest 0·1 kg using a SECA 803 weighing machine) and height (measured to the nearest 0·1 cm using a SECA 213 Portable Stadiometer), for the calculation of BMI(Reference Loy, Cheung and Soh22). BMI (expressed in kg/m2) was calculated by dividing weight (in kg) by squared height (in m2).

Development of a maternal FFQ for the Singapore PREconception Study of long-Term maternal and child Outcomes study

A FFQ was developed based on locally validated FFQ previously used in nationally representative samples of adults(Reference Deurenberg-Yap, Li and Tan23,Reference Neelakantan, Whitton and Seah24) . Additionally, food items commonly consumed during pregnancy and at postpartum were included. This information was obtained from a previous mother–offspring cohort (the Growing Up in Singapore Towards healthy Outcomes study – GUSTO), where food diaries and 24-h recalls from mothers during pregnancy and at postpartum were collected(Reference Chia, de Seymour and Colega25). The semi-quantitative, interviewer-administered FFQ consisted of food and beverage items which captured details of cooking methods (such as boiled and deep fried) for certain food groups (e.g., vegetables, poultry, red meat and fish). Participants were instructed to consider their dietary intakes for the past month (prior to enrolment) when responding. For each food and beverage item, participants were asked to quantify their frequency of consumption in an open-ended format (using one of the four options: never/rarely, frequency per month, frequency per week or frequency per day)(Reference Block, Hartman and Dresser26) before specifying the average amount consumed at each instance. Picture aids of various food portion sizes (for items such as vegetables, poultry) and standard-sized household tableware were used during the interview. Frequencies of the various food and beverage items were standardised to daily intakes and multiplied by standard portions of food/beverage (in g).

To estimate daily energy and nutrient intakes, a FFQ nutrient database was used. This database was generated using information from local food composition databases as well as information from the GUSTO maternal dietary records. For example, to obtain nutrient data for a FFQ item, a weighted average (weighting based on consumption frequency) was calculated based on the top three most commonly consumed foods under that item, from the GUSTO dietary records.

Upon completion of the FFQ during the enrolment visit, participants were given a 3DFD and guided on the recording of dietary intakes on two weekdays and one weekend day at home. To facilitate quantification of dietary intakes, picture aids of various food portion sizes and standard household tableware were included. Completed diaries were collected from participants at the subsequent study visit (second preconception visit occurring about 2–3 weeks later) and entered into a nutrient analysis software, Dietplan 7 (Forestfield Software Ltd), which contains local food composition databases.

Food grouping (FFQ and 3-d food diary)

The FFQ items were aggregated into forty-four pre-defined food groups (online supplementary material, Supplemental Table 1). To distinguish among the differing types of local staple consumed, distinct food groups for ‘rice’ (e.g., ‘White rice’, ‘Flavoured rice’ and ‘Brown rice’) and for ‘noodles’ (e.g., ‘Noodles in soup’ and ‘Flavoured noodles’) were created. Methods of cooking were also considered by differentiating foods cooked using healthier methods (lower fat content) (H) such as boiled, steamed from those cooked using less healthy (higher fat content) (LH) methods such as deep fried, in coconut curry, and accordingly noted (e.g., poultry and meat (H) v. poultry and meat (LH)). Food items recorded in the 3DFD were also classified into the identical forty-four food groups. For composite dishes, individual food items were identified and assigned to their respective food groups(Reference Ambrosini, O’Sullivan and de Klerk27). For all analyses involving the 3DFD, the averaged consumption of each food group was calculated across the 3 d.

Statistical analyses

For the current study, 1007 women with completed FFQ and a subsample of 289 participants (29 % of 1007 women), who also completed 3DFD, were selected for analyses. To examine if the subsample (n 289) was representative of the larger sample (n 1007), the socio-demographic and lifestyle characteristics between the two groups were compared using Pearson χ 2 tests.

Dietary patterns were first identified using EFA on the FFQ of the 1007 women with completed FFQ (Fig. 1, Step 1). Next, the reproducibility of these patterns was assessed using confirmatory factor analysis (CFA) in the FFQ and 3DFD of the subsample (Fig. 1, Step 2). To explain the suboptimal fit indices of the CFA models, exploratory factor analyses were next conducted and identified patterns from FFQ and 3DFD of the subsample were compared (Fig. 1, Steps 3 and 4). Further details are provided in the subsequent paragraphs.

Fig. 1 Schematic of the analyses (Steps 1–4). Step 1: EFA was used for the generation of the dietary patterns from women with completed FFQ (n 1007). Step 2: The reproducibility of the identified patterns was assessed using CFA in the subsample (n 289). Step 3: EFA was used for the generation of dietary patterns in the subsample. This was conducted due to suboptimal global fit indices from the CFA analyses (especially the 3DFD). Step 4: Dietary patterns identified from each dietary assessment method are compared using congruence coefficients, quantifying the magnitudes of factor similarity between two patterns compared. EFA, exploratory factor analysis; CFA, confirmatory factor analysis

Identification of dietary patterns from the FFQ (n 1007)

Suitability of the data for factor analysis was first assessed by the Kaiser–Meyer–Olkin measure of sampling adequacy and the Bartlett’s test of sphericity(Reference Alvin28,Reference Hair, Black and Babin29) . EFA was used to identify a posteriori dietary patterns based on the forty-four food groups from women with completed FFQ (n 1007). To ensure that the dietary patterns derived were independent of one another and to improve interpretability(Reference Newby and Tucker30), varimax rotation was next performed. Based on the break point of the Scree plot, eigenvalue of more than one and factor interpretability(Reference Newby and Tucker30), an optimal number of factors was retained. Factor loadings, estimated using the principal factor method, represent correlation coefficients between food groups and their related dietary patterns; hence, a higher factor loading of a particular food group indicates greater contribution to a particular pattern. Subsequently, dietary pattern scores were calculated by summing the standardised daily intake of food groups weighted by the respective regressed factor loadings. Each participant had a score for each dietary pattern derived. Greater adherence to a particular pattern was indicated by a higher dietary pattern score.

Coefficients of congruence were determined to examine whether the patterns are congruent across socio-demographic factors(Reference Judd, Letter and Shikany18,Reference Lorenzo-Seva and Ten Berge31) . These coefficients quantify the level of similarity between two dietary patterns compared, with values of above 0·50 considered as acceptable and values of close to 1 considered as excellent(Reference Cuco, Fernandez-Ballart and Sala3,Reference Judd, Letter and Shikany18) .

Reproducibility of identified dietary patterns in the subsample using two dietary assessment methods (n 289)

To assess the reproducibility of the identified patterns from the FFQ, CFA was applied on the FFQ and 3DFD of the subsample(Reference Togo, Heitmann and Sorensen15,Reference Lau, Glümer and Toft19,Reference Newby, Weismayer and Akesson32,Reference Schulze, Hoffmann and Kroke33) . To retain the significant core of each identified pattern and ensure convergence is achieved, only food groups with factor loadings of at least 0·40 from the EFA from Step 1 were included(Reference Lau, Glümer and Toft19,Reference Schulze, Hoffmann and Kroke33) . Commonly reported fit indices of the CFA models (root mean square error of approximation (RMSEA), standardised root mean square residual, goodness of fit index, comparative fit index (CFI), Bayesian information criterion) were evaluated(Reference Hooper, Coughlan and Mullen34). The recommended cut-offs, indicating a good model fit, are values of RMSEA < 0·08, standardised root mean square residual < 0·08, goodness of fit index ≥ 0·95, CFI ≥ 0·90 and smaller Bayesian information criterion values(Reference Hooper, Coughlan and Mullen34).

Dietary patterns in the subsample (n 289)

EFA was subsequently conducted to identify dietary patterns derived from each dietary assessment method (FFQ and 3DFD) in the subsample. Coefficients of congruence were also determined to compare the identified patterns from each dietary assessment method. Additionally, Spearman correlation coefficients of the forty-four food groups (used for EFA) were calculated to compare intakes between the two dietary assessment methods.

Statistical analyses were conducted using STATA 14·0 (StataCorp LP) and the ‘lavaan’ package in R for CFA. A two-sided P-value of < 0·05 indicates statistical significance.

Results

Characteristics of participants

Among the 1007 participants with available FFQ, a large proportion was below 35 years of age (85·6 %), of Chinese ethnicity (71·7 %), had higher educational attainment (62·4 %) and nulliparous (64·8 %) (online supplementary material, Supplemental Table 2). Participants who have never consumed alcohol or have never smoked made up 31·3 % and 89·4 % of the sample, respectively. While the majority had BMI within the normal range of 18·5–24·9 kg/m2 (62·2 %), a large proportion of participants led sedentary lifestyles as reflected by the low overall physical activity levels (66·5 % were inactive or minimally active) and long sitting hours (40·1 % sat for >11 h daily). The subsample (n 289) is representative of the cohort with FFQ data (n 1007) with largely similar characteristics, except the subsample having a larger proportion of older women (P < 0·001) and a larger proportion who were physically inactive (P = 0·003) (online supplementary material, Supplemental Table 2).

Dietary patterns identified from FFQ (n 1007)

The Kaiser–Meyer–Olkin measure of sampling adequacy was 0·73 for FFQ. The Bartlett’s test of sphericity indicated that there was more than one underlying factor in the FFQ (P < 0·001). Both tests showed that the study sample was suitable for factor analysis. Three dietary patterns were identified from the FFQ: ‘Fish, Poultry/Meat and Noodles’, ‘Fast Food and Sweetened Beverages’ and ‘Bread, Legumes and Dairy’ (Table 1). These dietary patterns collectively explained 74 % of the common variation in dietary intakes. The ‘Fish, Poultry/Meat and Noodles’ pattern was characterised by higher intakes of soups, fish, poultry/meat and noodles. The ‘Fast Food and Sweetened Beverages’ pattern was characterised by higher intakes of fast food, sweetened beverages and processed meat, and lower intakes of cooked vegetables and fresh fruits. The ‘Bread, Legumes and Dairy’ pattern consisted of mainly plant-based foods and dairy products such as higher intakes of nuts, legumes, full fat milk, yogurt and dairy-based drinks. These patterns were reasonably congruent across socio-demographic factors such as maternal age and ethnicity among the 1007 women (online supplementary material, Supplemental Table 3).

Table 1 Factor loadings for the dietary patterns identified from FFQ using exploratory factor analysis for women with completed FFQ (n 1007) and the subsample (n 289)

* Only factor loadings with absolute values of 0·30 and above were shown.

Only factor loadings with absolute values of 0·20 and above were shown.

Reproducibility of identified dietary patterns in the subsample using two dietary assessment methods (n 289)

On the basis of several fit indices (especially the CFI and Bayesian information criterion), the identified patterns (‘Fish, Poultry/Meat and Noodles’, ‘Fast Food and Sweetened Beverages’ and ‘Bread, Legumes and Dairy’) had a better model fit in the FFQ as compared with the 3DFD of the subsample (CFI for FFQ = 0·79; CFI for 3DFD = 0·34 and smaller Bayesian information criterion value for the FFQ compared with the 3DFD) (Table 2). To explain the poorer reproducibility of the identified patterns in the 3DFD, dietary patterns were identified for each dietary assessment method in the subsample.

Table 2 Measures of global fit for confirmatory factor analysis of the identified patterns in the validation subsample (n 289)

Dietary patterns in the subsample (n 289)

Dietary patterns (‘Fish, Poultry/Meat and Noodles’, ‘Fast Food and Sweetened Beverages’ and ‘Bread, Legumes and Dairy’) similar to those in the FFQ of the large sample were identified in the FFQ of the subsample. They explained 51 % of the common variance in dietary intakes. Conversely, two patterns, explaining 32 % of the common variance in dietary intakes, were observed from the 3DFD of the subsample. They appeared to be variants of two dietary patterns found in the FFQ and have been named as ‘Vegetables, Fruits, Poultry/Meat and Soups’ and ‘Bread, Pasta and Dairy’ (Table 1). In this subsample, a third 3DFD pattern was omitted due to poor interpretability. The third FFQ ‘Fast Food and Sweetened Beverages’ pattern did not resemble any of those identified from the 3DFD.

The ‘Vegetables, Fruits, Poultry/Meat and Soups’ pattern of the 3DFD appeared somewhat similar to the FFQ ‘Fish, Poultry/Meat and Noodles’ pattern except that it included additional key food groups such as vegetables, fruits and soya products. Similarly, the ‘Bread, Pasta and Dairy’ of the 3DFD shared similarities with the FFQ ‘Bread, Legumes and Dairy’ pattern in the subsample, except that pasta, white bread and cheese were included as additional food groups. However, the congruence coefficients of patterns identified in the subsample were below the acceptable cut-off of 0·50 (ranged from −0·64 (FFQ ‘Fast Food and Sweetened Beverages’ and 3DFD ‘Vegetables, Fruits, Poultry/Meat and Soups’) to 0·31 (FFQ ‘Bread, Legumes and Dairy’ and 3DFD ‘Bread, Pasta and Dairy’)] (Table 3), suggesting that patterns identified from the FFQ and 3DFD of the subsample cannot be considered similar.

Table 3 Factor congruence between dietary patterns identified from the FFQ and 3DFD of the subsample (n 289)

In the subsample, a comparison of the food group intakes from the two dietary assessment methods explained the dissimilar patterns identified from the FFQ and 3DFD (Table 4). In general, the FFQ captured a wider variety of foods consumed as compared with the 3DFD, with a larger number of food groups having median intakes of null in the latter. Spearman correlation coefficient was lowest for desserts in soup (0·12) and highest for coffee/tea/decaffeinated drinks (0·66).

Table 4 Comparison of intakes of food groups for women with completed FFQ (n 1007) and the subsample (n 289)

IQR, interquartile range; H, healthy, LH, less healthy.

* P > 0·05.

Spearman correlation coefficients were calculated between intakes from the FFQ and 3DFD in the subsample (n 289)

Discussion

Three dietary patterns (‘Fish, Poultry/Meat and Noodles’, ‘Fast Food and Sweetened Beverages’ and ‘Bread, Legumes and Dairy’) were identified from the FFQ. In the subsample, these patterns were reproducible in the FFQ, but less so in the 3DFD, where two variant patterns emerged. In this cohort, a posteriori dietary patterns identified from the FFQ were reproducible and reasonably congruent across several socio-demographic factors within this cohort of women planning pregnancy.

Dietary patterns identified from FFQ (n 1007)

The ‘Fish, Poultry/Meat and Noodles’ pattern in the S-PRESTO cohort is in line with our local diets consisting of higher carbohydrates and protein, with low intakes of fruits and vegetables(35,36) . This contrasts to the patterns reported among Spanish or Australian women planning pregnancy where vegetables or fruits tended to be eaten in combination with animal protein (e.g., ‘Vegetables and Meat’ pattern (consisting of a variety of vegetables, meat)(Reference Cuco, Fernandez-Ballart and Sala3), ‘High-protein/fruit’ (consisting of fish, meat, fresh fruits) and ‘Fruit and Low-fat Dairy’ (consisting of fresh fruits, yogurt)(Reference Schoenaker, Soedamah-Muthu and Callaway16,Reference Grieger, Grzeskowiak and Clifton17) ).

The ‘Fast Food and Sweetened Beverages’ pattern in the S-PRESTO cohort consisted of discretionary foods which are high in fat and sugar (e.g., fast food, sweetened beverages, fried snacks). This is similar to the ‘Sweetened Beverages and Sugars’ (consisting of sweetened beverages, sugars, low intakes of vegetables, fresh fruits), ‘Meat, High-fat and Sugar’ (consisting of cakes, sweet biscuits, meat pies) and ‘High-fat/sugar/takeaway’ (consisting of takeaway foods, potato chips, refined grains) patterns observed among Australian and Spanish women planning pregnancy(Reference Cuco, Fernandez-Ballart and Sala3,Reference Schoenaker, Soedamah-Muthu and Callaway16,Reference Grieger, Grzeskowiak and Clifton17) .

A unique ‘Bread, Legumes and Dairy’ pattern, made up of foods mainly from plant sources (e.g., nuts and legumes, buns and ethnic bread and a variety of cooked vegetables prepared using coconut curry), was observed in the S-PRESTO cohort. To our knowledge, this combination of foods has not been reported in other preconception cohorts to date, probably due to the lack of sampling on minority ethnic groups (e.g., Malay and Indian ethnicities). Taken together, while the dietary patterns of S-PRESTO women shared common foods that were identified in other populations of women planning pregnancy, they highlighted diverse consumption patterns within an Asian setting.

Reproducibility of identified dietary patterns in the subsample using two dietary assessment methods (n 289)

CFA has been used in nutrition studies to examine the robustness of empirically derived patterns(Reference Togo, Heitmann and Sorensen15,Reference Lau, Glümer and Toft19,Reference Newby, Weismayer and Akesson32,Reference Maskarinec, Novotny and Tasaki37) , and by reducing the subjectivity and ambiguity involved in exploratory approaches(Reference Lau, Glümer and Toft19,Reference Schulze, Hoffmann and Kroke33,Reference Maskarinec, Novotny and Tasaki37) . In line with these studies with reported CFI values of 0·64–0·71 and RMSEA values of 0·105–0·805(Reference Togo, Heitmann and Sorensen15,Reference Judd, Letter and Shikany18) , we found that the identified patterns from the large sample were reproducible in the subsample when the same dietary assessment method (FFQ) was used (CFI = 0·787, RMSEA = 0·070). Unlike two other studies, where 7-d weighed diet record readily identified patterns obtained from the FFQ(Reference Togo, Heitmann and Sorensen15), the identified patterns were less reproducible when 3DFD was used in the current study (CFI = 0·343, RMSEA = 0·065). A shorter, limited reference period (3 d) and a less precise measurement of intakes (non-weighed) in the current study could have contributed to the poorer reproducibility of the identified patterns in the 3DFD of the subsample. An exploration of the dietary patterns captured by each dietary assessment method in the subsample further substantiated these findings.

Dietary patterns in the subsample (n 289)

Differences in the patterns identified could be largely due to the fundamental differences between the two dietary assessment methods. Firstly, the FFQ is a closed-ended checklist of foods that captured estimated intakes of each given item, while the 3DFD is a detailed, open-ended record of the actual foods consumed. During the 3DFD dietary analyses, recorded foods and individual components of composite foods are often re-coded to match the closest corresponding FFQ food items. This lack of ‘one-to-one correspondence’ between foods captured by the FFQ and those in the 3DFD could have led to the differing patterns observed(Reference Willett and Hatch38).

Secondly, the dietary assessment methods had differing reference periods for the recording of intakes (FFQ: intakes in the past month; 3DFD: 3 d of a selected week after FFQ administration), which is likely to have resulted in a larger variation of foods captured by the FFQ in the subsample (FFQ: 51 %; 3DFD: 32 % of the variation explained). As changes in diet were unlikely within the short interval between the administration of the FFQ and 3DFD, differences in intakes captured could be largely due to the dietary assessment methods used(Reference Willett and Hatch38).

Thirdly, women planning pregnancy could have reduced their intakes of discretionary foods (such as fast food, fried snacks) upon intending to conceive(Reference Wise, Wesselink and Hatch39). These foods (mainly found in the FFQ ‘Fast Food and Sweetened Beverages’ pattern) are thus less likely to be consumed over the course of 3 d, hence were not captured by the 3DFD. In view of the differences between the two dietary assessment methods, we suggest the use of the FFQ-derived dietary patterns (instead of 3DFD ones), based on their better reproducibility and ability to reflect habitual intakes, for future diet-related investigations on health outcomes in this cohort.

Strengths of the current study include having a relatively large sample size (n 289) as compared with other dietary validation studies with sample sizes ranging from 92 to 203 participants(Reference Asghari, Rezazadeh and Hosseini-Esfahani9,Reference Loy and Jan Mohamed13,Reference Okubo, Murakami and Sasaki14,Reference Beck, Kruger and Conlon40Reference Liu, Wang and Lin42) and the reproducibility of these patterns was examined using CFA, giving additional credence to the results(Reference Cade, Burley and Warm43). However, several limitations are worth noting. Firstly, we regarded the FFQ patterns to be reflective of the habitual dietary intakes in this cohort, though it is also prone to reporting errors and biases. Nonetheless, the FFQ has been widely used as a measure for diet association studies(Reference Willett and Hatch38). Secondly, it is possible that the behavioural effect of reporting dietary intakes may obscure the true dietary intakes of participants and hence the patterns identified (e.g., socially desirable reporting of diets during interviewer-administered FFQ or simplifying food intakes to reduce reporting burden for the 3DFD)(Reference Livingstone and Black44). While this cannot be avoided entirely, we expect both dietary assessment methods to be similarly affected. Thirdly, no or low intakes for specific food groups could be a concern when identifying the patterns, especially so for the 3DFD. To address this, we performed EFA on the thirteen food groups where at least 50 % of the women had intakes recorded in the 3DFD. However, only two patterns were identified and they provided little information on the overall diets. As such, the number of food groups used in all analyses was standardised for consistency, an approach that was adopted by similar studies(Reference Edefonti, De Vito and Dalmartello8).

Conclusion

We have identified three dietary patterns (‘Fish, Poultry/Meat and Noodles’, ‘Fast Food and Sweetened Beverages’ and ‘Bread, Legumes and Dairy’) among Asian women planning pregnancy. In general, the three dietary patterns assessed by the FFQ were reproducible and reasonably congruent across several socio-demographic characteristics, providing a basis for future investigations on the overall diet and health outcomes in this cohort.

Acknowledgements

Acknowledgements: We would like to extend our gratitude to the S-PRESTO participants and the S-PRESTO study group, which includes Anne Eng Neo Goh, Anne Rifkin-Graboi, Anqi Qiu, Bee Wah Lee, Bernard Chern, Bobby Cheon, Christiani Jeyakumar Henry, Ciaran Gerard Forde, Claudia Chi, Doris Fok, Elaine Quah, Elizabeth Tham, Evelyn Chung Ning Law, Evelyn Xiu Ling Loo, Fabian Yap, Faidon Magkos, Falk Mueller-Riemenschneider, George Seow Heong Yeo, Helen Yu Chen, Heng Hao Tan, Hugo PS van Bever, Izzuddin Bin Mohd Aris, Jerry Kok Yen Chan, Joanne Yoong, Joao N Ferreira., Jonathan Tze Liang Choo, Jonathan Y Bernard, Keith M Godfrey, Kenneth Kwek, Kok Hian Tan, Kuan Jin Lee, Lieng Hsi Ling, Ling Wei Chen, Lourdes Mary Daniel, Lynette Pei-Chi Shek, Marielle V. Fortier, Mary Foong-Fong Chong, Mei Chien Chua, Melvin Leow, Michael Meaney, Mya Thway Tint, Neerja Karnani, Ngee Lek, Oon Hoe Teoh, Peter D Gluckman, Queenie Ling Jun Li, See Ling Loy, Sendhil Velan, Seng Bin Ang, Sharon Ng, Shephali Tagore, Shiao-Yng Chan, Shirong Cai, Shu E Soh, Sok Bee Lim, Stella Tsotsi, Stephen Chin-Ying Hsu, Sue Anne Toh, Teng Hong Tan, Tong Wei Yew, Victor Samuel Rajadurai, Wee Meng Han, Wei Wei Pang, Yap Seng Chong, Yin Bun Cheung, Yiong Huak Chan, Yung Seng Lee. Financial support: This research is supported by the Singapore National Research Foundation (NRF) under its Translational and Clinical Research (TCR) Flagship Programme and administered by the Singapore Ministry of Health’s National Medical Research Council (NMRC), Singapore-NMRC/TCR/004-NUS/2008; NMRC/TCR/012-NUHS/2014. Additional funding is provided by the Singapore Institute for Clinical Sciences, Agency for Science, Technology and Research (A * STAR), Singapore. K.M.G. is supported by the National Institute for Health Research through the NIHR Southampton Biomedical Research Centre and the European Union’s Seventh Framework Programme (FP7/2007–2013), project EarlyNutrition (n°289346). J.K.Y.C. is supported by the NMRC Clinician Scientist Award (NMRC/CSA(SI)/008/2016). Conflict of interest: Y.S.C., K.M.G. and S.Y.C. are part of an academic consortium that has received research funding from Abbott, Nutrition, Nestle and Danone. No conflict of interest was declared by the other authors. Authorship: Y.S.C., K.M.G., L.P.C.S., S.Y.C. and J.K.Y.C. designed and led the S-PRESTO cohort study. M.T.C. and M.N.M.A. contributed to the FFQ and 3DFD dietary data collection, cleaning and analysis. Hiromi Koh provided statistical advice for this manuscript. S.X.L. contributed to the FFQ data cleaning, analysed the data and wrote the paper with intellectual inputs from M.F.F.C. All authors read and approved the manuscript. Ethics of human subject participation: The S-PRESTO study is conducted according to the guidelines as stated in the Declaration of Helsinki and all procedures involving research study participants were approved by the local SingHealth Centralized Institutional Review Board (reference 2019/2143). The study is registered on the ClinicalTrials.gov database provided by the US National Library of Medicine under the identifier NCT03531658. Written consent was obtained from all participants.

Supplementary material

For supplementary material accompanying this paper visit https://doi.org/10.1017/S1368980021001178

References

Chen, L-W, Low, YL, Fok, D et al. (2014) Dietary changes during pregnancy and the postpartum period in Singaporean Chinese, Malay and Indian women: the GUSTO birth cohort study. Public Health Nutr 17, 19301938.CrossRefGoogle ScholarPubMed
Hillier, SE & Olander, EK (2017) Women’s dietary changes before and during pregnancy: a systematic review. Midwifery 49, 1931.CrossRefGoogle ScholarPubMed
Cuco, G, Fernandez-Ballart, J, Sala, J et al. (2006) Dietary patterns and associated lifestyles in preconception, pregnancy and postpartum. Eur J Clin Nutr 60, 364371.CrossRefGoogle ScholarPubMed
Olson, CM (2005) Tracking of food choices across the transition to motherhood. J Nutr Educ Behav 37, 129136.CrossRefGoogle ScholarPubMed
Tovar, A, Kaar, JL, McCurdy, K et al. (2019) Maternal vegetable intake during and after pregnancy. BMC Pregnancy Childbirth 19, 267.CrossRefGoogle ScholarPubMed
Hu, FB (2002) Dietary pattern analysis: a new direction in nutritional epidemiology. Curr Opin Lipidol 13, 39.CrossRefGoogle ScholarPubMed
Reedy, J, Subar, AF, George, SM et al. (2018) Extending methods in dietary patterns research. Nutrients 10, 571.CrossRefGoogle ScholarPubMed
Edefonti, V, De Vito, R, Dalmartello, M et al. (2020) Reproducibility and validity of a posteriori dietary patterns: a systematic review. Adv Nutr 11, 293326 .CrossRefGoogle ScholarPubMed
Asghari, G, Rezazadeh, A, Hosseini-Esfahani, F et al. (2012) Reliability, comparative validity and stability of dietary patterns derived from an FFQ in the Tehran Lipid and Glucose Study. Br J Nutr 108, 11091117.CrossRefGoogle ScholarPubMed
Crozier, SR, Inskip, HM, Godfrey, KM et al. (2008) Dietary patterns in pregnant women: a comparison of food-frequency questionnaires and 4 d prospective diaries. Br J Nutr 99, 869875.CrossRefGoogle ScholarPubMed
Hu, FB, Rimm, E, Smith-Warner, SA et al. (1999) Reproducibility and validity of dietary patterns assessed with a food-frequency questionnaire. Am J Clin Nutr 69, 243249.CrossRefGoogle ScholarPubMed
Khani, BR, Ye, W, Terry, P et al. (2004) Reproducibility and validity of major dietary patterns among Swedish women assessed with a food-frequency questionnaire. J Nutr 134, 15411545.CrossRefGoogle ScholarPubMed
Loy, SL & Jan Mohamed, HJ (2013) Relative validity of dietary patterns during pregnancy assessed with a food frequency questionnaire. Int J Food Sci Nutr 64, 668673.CrossRefGoogle ScholarPubMed
Okubo, H, Murakami, K, Sasaki, S et al. (2010) Relative validity of dietary patterns derived from a self-administered diet history questionnaire using factor analysis among Japanese adults. Public Health Nutr 13, 10801089.CrossRefGoogle ScholarPubMed
Togo, P, Heitmann, BL, Sorensen, TI et al. (2003) Consistency of food intake factors by different dietary assessment methods and population groups. Br J Nutr 90, 667678.CrossRefGoogle ScholarPubMed
Schoenaker, DA, Soedamah-Muthu, SS, Callaway, LK et al. (2015) Prepregnancy dietary patterns and risk of developing hypertensive disorders of pregnancy: results from the Australian Longitudinal Study on Women’s Health. Am J Clin Nutr 102, 94101.CrossRefGoogle ScholarPubMed
Grieger, JA, Grzeskowiak, LE & Clifton, VL (2014) Preconception dietary patterns in human pregnancies are associated with preterm delivery. J Nutr 144, 10751080.CrossRefGoogle ScholarPubMed
Judd, SE, Letter, AJ, Shikany, JM et al. (2015) Dietary patterns derived using exploratory and confirmatory factor analysis are stable and generalizable across race, region, and gender subgroups in the REGARDS study. Front Nutr 1, 2929.CrossRefGoogle ScholarPubMed
Lau, C, Glümer, C, Toft, U et al. (2008) Identification and reproducibility of dietary patterns in a Danish cohort: the Inter99 study. Br J Nutr 99, 10891098.CrossRefGoogle Scholar
Loo, EXL, Soh, SE, Loy, SL et al. (2021) Cohort profile: Singapore preconception study of long-term maternal and child outcomes (S-PRESTO). Eur J Epidemiol 36, 129142.CrossRefGoogle Scholar
Bernard, JY, Ng, S, Natarajan, P et al. (2019) Associations of physical activity levels and screen time with oral glucose tolerance test profiles in Singaporean women of reproductive age actively trying to conceive: the S-PRESTO study. Diabet Med 36, 888897.Google ScholarPubMed
Loy, SL, Cheung, YB, Soh, SE et al. (2018) Female adiposity and time-to-pregnancy: a multiethnic prospective cohort. Hum Reprod 33, 21412149.CrossRefGoogle ScholarPubMed
Deurenberg-Yap, M, Li, T, Tan, WL et al. (2000) Validation of a semiquantitative food frequency questionnaire for estimation of intakes of energy, fats and cholesterol among Singaporeans. Asia Pac J Clin Nutr 9, 282288.CrossRefGoogle ScholarPubMed
Neelakantan, N, Whitton, C, Seah, S et al. (2016) Development of a semi-quantitative food frequency questionnaire to assess the dietary intake of a multi-ethnic urban Asian population. Nutrients 8, 528.CrossRefGoogle ScholarPubMed
Chia, AR, de Seymour, JV, Colega, M et al. (2016) A vegetable, fruit, and white rice dietary pattern during pregnancy is associated with a lower risk of preterm birth and larger birth size in a multiethnic Asian cohort: the Growing Up in Singapore Towards healthy Outcomes (GUSTO) cohort study. Am J Clin Nutr 104, 14161423.CrossRefGoogle Scholar
Block, G, Hartman, AM, Dresser, CM et al. (1986) A data-based approach to diet questionnaire design and testing. Am J Epidemiol 124, 453469.CrossRefGoogle ScholarPubMed
Ambrosini, GL, O’Sullivan, TA, de Klerk, NH et al. (2011) Relative validity of adolescent dietary patterns: a comparison of a FFQ and 3 d food record. Br J Nutr 105, 625633.CrossRefGoogle ScholarPubMed
Alvin, RC (2002) Factor analysis. In Methods of Multivariate Analysis, 2nd ed, pp. 408450. New York: John Wiley and Sons, Inc.Google Scholar
Hair, JF, Black, WC & Babin, BJ (2010) Chapter 3 – Factor analysis. In Multivariate Data Analysis: A Global Perspective. London: Pearson Education.Google Scholar
Newby, PK & Tucker, KL (2004) Empirically derived eating patterns using factor or cluster analysis: a review. Nutr Rev 62, 177203.CrossRefGoogle ScholarPubMed
Lorenzo-Seva, U & Ten Berge, JM (2006) Tucker’s congruence coefficient as a meaningful index of factor similarity. Methodology (Gott) 2, 5764.CrossRefGoogle Scholar
Newby, PK, Weismayer, C, Akesson, A et al. (2006) Long-term stability of food patterns identified by use of factor analysis among Swedish women. J Nutr 136, 626633.CrossRefGoogle ScholarPubMed
Schulze, MB, Hoffmann, K, Kroke, A et al. (2003) Risk of hypertension among women in the EPIC-Potsdam Study: comparison of relative risk estimates for exploratory and hypothesis-oriented dietary patterns. Am J Epidemiol 158, 365373.CrossRefGoogle ScholarPubMed
Hooper, D, Coughlan, J & Mullen, M (2008) Structural equation modelling: guidelines for determining model fit. EJBRM 6, 5359.Google Scholar
Health Promotion Board Singapore (2018) National Nutrition Survey 2018 Shows Gradual Improvements in Singaporeans’ Dietary Habits; available at https://www.hpb.gov.sg/article/national-nutrition-survey-2018-shows-gradual-improvements-in-singaporeans-dietary-habits (accessed January 2021).Google Scholar
Health Promotion Board Singapore (2011) Report of the National Nutrition Survey 2010; available at https://www.hpb.gov.sg/docs/default-source/pdf/nns-2010-report.pdf?sfvrsn=18e3f172_2 (accessed February 2021).Google Scholar
Maskarinec, G, Novotny, R & Tasaki, K (2000) Dietary patterns are associated with body mass index in multiethnic women. J Nutr 130, 30683072.CrossRefGoogle ScholarPubMed
Willett, W & Hatch, E (2013) Chapter 6: Reproducibility and validity of food frequency questionnaires. In Nutritional Epidemiology, 3rd ed. [electronic resource] Oxford: Oxford University Press.Google Scholar
Wise, LA, Wesselink, AK, Hatch, EE et al. (2020) Changes in behavior with increasing pregnancy attempt time: a prospective cohort study. Epidemiology 31, 659667.CrossRefGoogle ScholarPubMed
Beck, KL, Kruger, R, Conlon, CA et al. (2012) The relative validity and reproducibility of an iron food frequency questionnaire for identifying iron-related dietary patterns in young women. J Acad Nutr 112, 11771187.CrossRefGoogle ScholarPubMed
Hong, X, Ye, Q, Wang, Z et al. (2016) Reproducibility and validity of dietary patterns identified using factor analysis among Chinese populations. Br J Nutr 116, 842852.CrossRefGoogle ScholarPubMed
Liu, X, Wang, X, Lin, S et al. (2015) Reproducibility and validity of a food frequency questionnaire for assessing dietary consumption via the dietary pattern method in a Chinese rural population. PLoS One 10, e0134627.CrossRefGoogle Scholar
Cade, JE, Burley, VJ, Warm, DL et al. (2004) Food-frequency questionnaires: a review of their design, validation and utilisation. Nutr Res Rev 17, 522.CrossRefGoogle ScholarPubMed
Livingstone, MBE & Black, AE (2003) Markers of the validity of reported energy intake. J Nutr 133, 895S920S.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1 Schematic of the analyses (Steps 1–4). Step 1: EFA was used for the generation of the dietary patterns from women with completed FFQ (n 1007). Step 2: The reproducibility of the identified patterns was assessed using CFA in the subsample (n 289). Step 3: EFA was used for the generation of dietary patterns in the subsample. This was conducted due to suboptimal global fit indices from the CFA analyses (especially the 3DFD). Step 4: Dietary patterns identified from each dietary assessment method are compared using congruence coefficients, quantifying the magnitudes of factor similarity between two patterns compared. EFA, exploratory factor analysis; CFA, confirmatory factor analysis

Figure 1

Table 1 Factor loadings for the dietary patterns identified from FFQ using exploratory factor analysis for women with completed FFQ (n 1007) and the subsample (n 289)

Figure 2

Table 2 Measures of global fit for confirmatory factor analysis of the identified patterns in the validation subsample (n 289)

Figure 3

Table 3 Factor congruence between dietary patterns identified from the FFQ and 3DFD of the subsample (n 289)

Figure 4

Table 4 Comparison of intakes of food groups for women with completed FFQ (n 1007) and the subsample (n 289)

Supplementary material: File

Lim et al. supplementary material

Lim et al. supplementary material

Download Lim et al. supplementary material(File)
File 46 KB