Study participants and design

The current study used data from the Australian Longitudinal Study on Women’s Health (ALSWH) and Mothers’ and their Children’s Health (MatCH) study. For the ALSWH study, over 14 000 women born in 1973–1978 were recruited, who were randomly selected from the National Universal Health Insurance database, including all Australian citizens and permanent residents. Fuller details of the ALSWH have been described elsewhere^{(Reference Dobson, Hockey and Brown27)}.

The MatCH is a substudy of the ALSWH young cohort, born 1973–1978, investigating childcare/school, illness/disability, diets, quality of life, social/emotional development, and growth and physical developments. In 2016, this study invited 8929 women to provide information about their children, among those, 3039 women filled out the questionnaire about their children (up to three young children) (n 5780)^{(Reference Mishra, Moss and Loos28)}.

This study utilised data from the young Australian cohort, aged 18–23 years (born 1973–1978), who provided wide-ranging information about their offspring born between 2003 (Survey 3) and 2015 (Survey 7). Nulliparous and non-pregnant women at baseline Survey 3 and 5 were included in the study. Women who reported at least one live birth between Survey 3 and 7 were included. Only the first births born between 2003 and 2015 and were aged 5–12 years were included. We excluded women who had missing data on offspring behaviour, child diets and implausible energy intake (> 16 800 kJ/d or < 2100 kJ/d)^{(Reference Willett29)}. The current study included 1448 mother–child dyads in the final analysis (Fig. 1). Data from the ALSWH were used to assess exposure (maternal dietary consumption), while the MatCH study was used to assess outcome (childhood behavioural problems) and mediator (childhood dietary consumption). The ALSWH study was approved by the Human Research Ethics Committees at the University of Newcastle and the University of Queensland, and informed consent was received from all ALSWH participants.

Fig. 1 Flow chart of the final sample for the analysis of mediation by childhood diets in the association between pre-pregnancy diets and offspring behavioural problems

Maternal dietary assessment

Women’s dietary consumption was first assessed in 2003 (Survey 3, aged 25–30 years, n 9081) and again in 2009 (Survey 5, aged 31–36, n 8200) for Epidemiologic Study version 2^{(Reference Ireland, Jolley and Giles30)}. Women were asked to provide their habitual dietary intake of the previous 12 months using a validated and semi-quantitative 101-items FFQ. Validation of the FFQ against 7 d food diaries of sixty-three women of child-bearing age indicated moderate to strong energy-adjusted correlation coefficients for a wide range of nutrients and ranged from 0·28 for vitamin A to 0·78 for carbohydrates^{(Reference Hodge, Patterson and Brown31)}.

We computed the Healthy Eating Index (HEI-2015) score to assess pre-pregnancy diet quality, which includes thirteen components that sum to a total maximum score of 100 points. Each of the dietary components is scored on a density basis out of 1000 calories except fatty acids^{(Reference Krebs-Smith, Pannucci and Subar32,Reference Reedy, Lerman and Krebs-Smith33)} . Nine components, including total fruits, whole fruits, whole grains, total vegetables, greens and beans, dairy, seafood and plant proteins, total proteins, and fatty acids, were to be consumed adequately. However, four dietary components, such as refined grains, Na, saturated fats and added sugars, were to be consumed in moderation – in which mothers with lower intake receive higher scores. We categorised the HEI-2015 score was into the tertiles approach according to its distribution among the study participants: tertile 1 (low adherence), tertile 2 (moderate adherence) and tertile 3 (high adherence) to enable practical comparisons.

Childhood dietary assessment

This study used a validated and semi-quantitative twenty-eight-items Children’s Dietary Questionnaire (CDQ) to assess childhood dietary patterns, which measures childhood dietary consumption either in the previous week or 24 h^{(Reference Magarey, Golley and Spurrier34)}. The CDQ was developed according to the most recent national data on the dietary consumption of Australian children^{(Reference Bell, Kremer and Magarey35,Reference Gehling, Magarey and Daniels36)} and the Australian Dietary Guidelines^{(Reference Baghurst, Binns and Truswell37,Reference Smith, Kellett and Schmerlaib38)} .

Children’s dietary patterns based on twenty-five non-overlapping food groups (frequency of consumptions/day) were identified using principal component analysis (PCA) with the use of orthogonal (varimax) rotation. The number of childhood dietary patterns was chosen with the basis of eigenvalues > 1·35, the identification of a breakpoint in the scree plot and factor interpretability^{(Reference Kline39)}. We used the Bartlett test of sphericity (P < 0·001) to indicate statistically correlated variables. Kaiser–Meyer–Olkin test (0·71) was used to measure sampling adequacy. Food groups with factor loadings ≥ 0·30 on a factor were considered to have a strong association with that dietary pattern and be the most explanatory in describing the factors^{(Reference Yong and Pearce40)}.

Offspring behaviour assessment

Women were asked to provide their offspring’s behaviours over the previous 6 months using the SDQ. Total behavioural difficulties score consists of four subscales, ranging from 0 to 40: emotional (somatic, unhappy, worried, nervous and fears), hyperactivity (distractible, restless, fidgety, reflective and attentive), peer (solitary, popular, good friend, bullied and prefers adult) and conduct problems (fights, tempers, obedient, steals and lies). Each subscale comprises five items with three-point response scales (0 for ‘not true’, 1 for ‘somewhat true’ and 2 for ‘certainly true’), with a subscale score ranging from 0 to 10^{(Reference Goodman16)}. Each one-point increase in the total behavioural difficulties score corresponds to an increase in the risk of developing a mental health disorder.

The data on the total behavioural difficulties score were skewed. We, therefore, dichotomised total behavioural problems score based on Goodman classifications^{(Reference Goodman16)}, comparing children with abnormal or borderline scores with children with normal scores. In this study, the total behavioural problem is defined according to the cut-off on the total behavioural difficulties score (≥ 14 on the maternal reports).

Assessment of confounders and covariates

Baseline maternal confounders, such as marital status, education, income, smoking, alcohol intake and physical activity, were adjusted using the self-reported data before the index birth (Survey 3 or 5). Prenatal factors, including hypertensive disorder in pregnancy and gestational diabetes mellitus, were adjusted for using the same survey as the index birth (Survey 4–7).

Women’s alcohol consumption was classified as a non-drinker, low-risk drinker (≤ 14 drinks/week), risky drinker (15–28 drinks/week) and high-risk drinker (> 28 drinks/week)⁽⁴¹⁾. However, women with high-risk drinkers were merged with a risky drinker group due to very few women reported as high-risk drinkers (n 6, 0·42 %). We categorised the smoking status as never smoker, ex-smoker and current smoker⁽⁴²⁾. Mothers were asked to provide only activity that lasted 10 min or more using a mailed physical activity questionnaire before recording daily pedometer step counts for seven consecutive days. A physical activity score was calculated according to frequency and duration of walking and moderate and vigorous-intensity activity and categorised as sedentary/low (< 600 total metabolic equivalents (MET) min/week), moderate (600–1200 MET min/week) or high (≥ 1200 MET min/week)^{(Reference Brown, Burton and Marshall43)}.

Mothers also were invited to provide information on their children’s sex, height, weight, history of premature birth (live birth < 37 weeks of gestation) and low birth weight (live birth weight < 2·5 kg), multiple births, and breast-feeding status in the MatCH study. Child BMI was calculated using their weight (kg)/height (m²), then categorised into underweight, normal, overweight and obese according to sex and age-specific BMI classifications for children^{(Reference Cole, Bellizzi and Flegal44)}.

Statistical analyses

Maternal and childhood characteristics were described according to adherence to pre-pregnancy HEI-2015 score and offspring behavioural problems. Mean differences were examined using t test, Pearson’s chi-square and ANOVA.

Figure 2 provides a directed acyclic graph indicating potential pathways between pre-pregnancy diets, childhood diets and offspring behavioural problems. A mediation analysis was performed using the counterfactual approach to decompose the total effect of poor pre-pregnancy diet quality on offspring behavioural problems into natural direct and indirect effects through childhood diets^{(Reference VanderWeele45,Reference VanderWeele and Vansteelandt46)} . The mediation analysis was conducted by fitting a logistic regression model for the binary outcome (offspring behavioural problems, yes v. no) and a linear regression model for the continuous mediator (childhood diets). We did not include exposure–mediator interaction in any model, since it was not statistically significant (P > 0·05). From these combined models, we estimated OR of natural direct effects (OR^NDE) and natural indirect effects (OR^NIE), and total effects (OR^TE) for the binary outcomes. The proportion mediated was calculated as (OR^NDE (OR^NIE–1)] ÷ [OR^NDE × OR^NIE–1) × 100 % for the binary outcome^{(Reference VanderWeele45,Reference VanderWeele and Vansteelandt46)} . The proportion mediated estimates the extent to which the effect of the pre-pregnancy diets on the offspring’s behavioural problems is mediated through childhood diets relative to the overall effect of the pre-pregnancy diets. The maternal potential confounders were selected according to the known association from previous literature and then tested the associations with the exposure and outcome, the mediator and outcome, or/and the exposure and mediator. As shown in Table 2, two separate models were fitted to observe the difference of total proportion mediated by childhood diets after adjustments for baseline and post-covariates. The first model adjusted for baseline maternal potential confounders (maternal age, education, smoking and household income), since these variables might be associated with exposure, outcome and mediator. The second model further adjusted for pregnancy complications (gestational diabetes mellitus, hypertensive disorder in pregnancy and antenatal anxiety) and child characteristics (preterm birth, low birth weight, child age and sex). These variables are important post-covariates that might influence offspring behaviours (direct effect). We retained the confounders in the adjusted model if the P-value was < 0·2 in the simple model. We further performed a sensitivity analysis to observe changes in the HEI-2015 score from preconception to during pregnancy. We ran Spearman’s correlation and paired t tests to examine the stability and changes of the HEI-2015 score at the two time points. The paramed program in STATA version 16 (StataCorp) was employed to compute natural direct, indirect and total effects. P-value ≤ 0·05 was considered statistically significant.

Fig. 2 Directed acyclic graph showing potential pathways between pre-pregnancy diets, childhood diets and offspring behavioural problems