Hostname: page-component-586b7cd67f-2brh9 Total loading time: 0 Render date: 2024-11-25T20:11:25.377Z Has data issue: false hasContentIssue false

Asthma control in pregnancy is associated with pre-conception dietary patterns

Published online by Cambridge University Press:  24 April 2015

Jessica A Grieger
Affiliation:
Robinson Research Institute, School of Paediatrics and Reproductive Health, University of Adelaide and Lyell McEwin Hospital, Haydown Road, Elizabeth Vale, SA 5112, Australia
Luke E Grzeskowiak
Affiliation:
Robinson Research Institute, School of Paediatrics and Reproductive Health, University of Adelaide and Lyell McEwin Hospital, Haydown Road, Elizabeth Vale, SA 5112, Australia
Lisa G Wood
Affiliation:
Hunter Medical Research Institute, School of Biomedical Science and Pharmacy, University of Newcastle, Kookaburra Circuit, New South Wales, Australia
Vicki L Clifton*
Affiliation:
Robinson Research Institute, School of Paediatrics and Reproductive Health, University of Adelaide and Lyell McEwin Hospital, Haydown Road, Elizabeth Vale, SA 5112, Australia
*
*Corresponding author: Email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Objective

To examine pre-conception dietary patterns in pregnant asthmatic women and to identify associations between maternal diet and asthma control during pregnancy.

Design

Cross-sectional study. Pre-conception food frequency data were collected retrospectively. Asthma control was assessed using the Global Initiative for Asthma guidelines. Dietary patterns were derived using factor analysis. Binary logistic regression analyses were used to test the association between uncontrolled asthma and each dietary pattern (Z-score), with values presented as odds ratio and 95 % confidence interval.

Setting

Antenatal clinic in a tertiary hospital, Adelaide, Australia, May 2009–July 2013.

Subjects

One hundred and fifty-eight asthmatic pregnant women.

Results

Three dietary patterns were identified: (i) ‘high protein/fruit’ (strong food group loadings for fish, meat, chicken, fruit); (ii) ‘high fat/sugar/takeaway’ (takeaway foods, crisps, refined grains); and (iii) ‘vegetarian-type’ (vegetables, fruit, soya milk, whole grains). A 1 sd increase in score on the high fat/sugar/takeaway pattern was associated with increased likelihood of uncontrolled asthma (adjusted OR=1·54; 95 % CI 1·07, 2·23; P=0·022). Women with uncontrolled asthma (n 115) had higher energy-adjusted intakes of saturated fat, monounsaturated fat, carbohydrate, sugar and fibre compared with women with controlled asthma (n 43, all P≤0·05).

Conclusions

Pre-pregnancy dietary patterns may influence maternal asthma control. Our work highlights the importance of achieving a healthy diet before pregnancy that is low in saturated fat, sugar and takeaway foods, and therefore higher in lean meats, poultry and fish, as well as fruits, vegetables and whole grains. A healthy dietary pattern should be encouraged in all asthmatic women who are of childbearing age, and should additionally be promoted before pregnancy and beyond.

Type
Research Papers
Copyright
Copyright © The Authors 2015 

Asthma is a heterogeneous and complex disease, involving alterations in airway structure and airway inflammation. Worldwide, asthma represents one of the most common chronic diseases to affect pregnancies, affecting between 8 and 13 % of the population( Reference Clark, Hulme and Devendrakumar 1 Reference Kwon, Belanger and Bracken 3 ). A meta-analysis from 2011 demonstrated that asthma in pregnancy was associated with up to 54 % increased risk for low birth weight, small for gestational age, preterm delivery and pre-eclampsia( Reference Murphy, Namazy and Powell 4 ). A subsequent meta-analysis revealed that asthma exacerbations in pregnancy increased the risk for low birth weight (relative risk (RR)=3·02; 95 % CI 1·87, 4·89) and compared with women with mild asthma, women with moderate to severe asthma were at increased risk for babies born with low birth weight (RR=1·15; 95 % CI 1·05, 1·26) or small for gestational age (RR=1·24; 95 % CI 1·15, 1·35)( Reference Namazy, Murphy and Powell 5 ). These studies suggest that worsening asthma during pregnancy may contribute to poor outcomes for the fetus and that approaches to improve asthma control may be of benefit( Reference Powell, Murphy and Taylor 6 ).

In non-pregnant asthmatics, unhealthy diets have been shown to be an underlying contributor to poorly controlled asthma and subsequent risk of asthma exacerbations. In healthy individuals, a single high-fat meal has been linked to increased exhaled nitric oxide( Reference Rosenkranz, Townsend and Steffens 7 ) and in non-obese asthmatics, a high-fat meal increased neutrophilic inflammation and attenuation of airway bronchodilator response( Reference Wood, Garg and Gibson 8 ). A low-fibre, high-fat diet has been linked to worse airway inflammation and lung function in severe asthmatics( Reference Berthon, Macdonald-Wicks and Gibson 9 ). Furthermore, a diet low in fruits and vegetables has been shown to increase the risk of asthma exacerbation by twofold( Reference Wood, Garg and Smart 10 ). In pregnancy, altered food patterns have previously been associated with excess gestational weight gain( Reference Uusitalo, Arkkola and Ovaskainen 11 ), risk for small for gestational age( Reference Thompson, Wall and Becroft 12 ), risk of preterm delivery( Reference Grieger, Grzeskowiak and Clifton 13 ) and development of childhood allergies( Reference Miyake, Okubo and Sasaki 14 ). However, the connection between dietary intake and asthma control in pregnancy is not clear.

Only one study to date has assessed dietary intakes in pregnant women with asthma in which nutrient intake was generally higher in mildly asthmatic women, yet lower in moderate to severe asthmatics, compared with pregnant women without asthma( Reference McLernon, Wood and Murphy 15 ). Moreover, little attention has been paid to maternal dietary intakes pre-conception and the potential impact this might have on maternal asthma control. If pre-conception diet is linked to asthma control, this would present an ideal time and opportunity to consume a healthy diet to control asthma during pregnancy, thus optimising subsequent perinatal outcomes.

The aims of the present study were to: (i) identify associations between pre-conception dietary patterns and maternal asthma control; and (ii) determine whether there are any differences in dietary intakes between women with controlled v. uncontrolled asthma. We hypothesise that pre-conception diet quality influences maternal asthma control during pregnancy.

Methods

Study setting and population

The current retrospective, cross-sectional study was part of a larger prospective cohort study from the Lyell McEwin Hospital, Adelaide, Australia, assessing the effects of asthma during pregnancy on the mother, placenta and baby. Pregnant women aged >18 years and attending their first antenatal visit were invited to participate. Recruitment and data collection for all women and their babies took place between May 2009 and July 2013. Of the 400 pregnant women who consented, ninety-one women withdrew from further participation due to the following: unable to be contacted (n 10), could not attend appointments/not interested (n 56), relocated (n 9), miscarriage (n 12) or voluntary termination of pregnancy (n 4), leaving 309 women to be analysed. The project was approved by The Queen Elizabeth Hospital and Lyell McEwin Hospital Human Research Ethics Committee and The University of Adelaide Human Research Ethics Committee. All women gave written informed consent. We have recently examined the relationship between pre-conception dietary patterns in a sample of 309 pregnant women( Reference Grieger, Grzeskowiak and Clifton 13 ). We now present data from a subgroup of asthmatic women (n 159), in whom we have used the same dietary pattern analysis.

Maternal data collection

At the first antenatal clinic visit, maternal body weight was measured to the nearest 0·1 kg using calibrated electronic scales (Professional Medical Scale, ScalesPlus, Australia) and height was measured by a wall-mounted stadiometer. BMI was calculated as [weight (kg)]/[height (m)]2. Previous obstetric history, medical, mental and surgical health information, and socio-economic status (Socio-Economic Indexes for Areas) were obtained from medical records. Gestational age was determined by date of the last menstrual period and confirmed at 18-week ultrasound. Smoking history was recorded: women who did not smoke at any stage during pregnancy or who were former smokers (i.e. quit a median of 3 years ago) were classified as non-smokers, while current smokers and those who quit smoking in pregnancy (median 5·5 weeks’ gestation) were classified as smokers.

Asthma assessment

Women attending their first booking visit at the Lyell McEwin Hospital antenatal clinic were identified as controls (non-asthmatic) or asthmatics, by the attending midwife. To determine asthma, the midwife asked ‘Have you been told by a doctor that you have asthma?’ and ‘Have you used any asthma medications in the last year like salbutamol or a preventer?’ Women identified as having asthma received a baseline assessment of their asthma during their first study visit (median 13 weeks’ gestation). Given the importance of evaluating asthma control, rather than asthma severity, to guide asthma management decisions( Reference Humbert, Holgate and Boulet 16 ), asthma control was assessed using the Global Initiative for Asthma (GINA) guidelines( 17 ). These guidelines define asthma control as: minimal or no daytime symptoms; no limitations of daily activities; no nocturnal symptoms; minimal or no need for rescue therapy and normal lung function( 17 ). Therefore, based on current symptoms women were identified as having either uncontrolled or partly controlled/controlled asthma. Lung function was assessed using an EasyOne diagnostic spirometer (Niche Medical, Zurich, Switzerland). Forced expiratory volume at one second (FEV1) and forced vital capacity (FVC) were measured before and after administration of salbutamol. Predicted values for lung function were calculated based on women’s height and age according to the equations of Gore et al. ( Reference Gore, Crockett and Pederson 18 ).

Dietary intakes and food group consumption

At the first antenatal visit (median 13 weeks’ gestation), the validated Cancer Council of Victoria’s Dietary Questionnaire for Epidemiological Studies FFQ was used to obtain dietary intake data covering the 12 months prior to pregnancy. One hundred different foods (g/d) were obtained from the FFQ and were assigned into thirty-three food groups (g/d), based on a previous Australian study( Reference Ambrosini, Oddy and Robinson 19 ) and used for analysis.

Factor analysis

Dietary patterns were derived using factor analysis with factor loadings extracted using the principal component method and varimax/orthogonal rotation. The number of dietary patterns identified was based on eigenvalues >1·5, on identification of a break point in the scree plot and on interpretability( Reference Schulze, Hoffmann and Kroke 20 ). Using these criteria, a three-factor solution was chosen and re-run with the resulting factor scores saved and converted to Z-scores for analysis. Items with factor loadings >0·25 were considered as the items of relevance for the identified factor. These items represent the foods most highly related to the identified factor( Reference Kline 21 ). Foods that cross-loaded on several factors were retained. Inter-item reliability for each factor was assessed using Cronbach’s α coefficients. Three hundred and nine women had complete FFQ data and the three major dietary patterns that were identified in the factor analysis have been published( Reference Grieger, Grzeskowiak and Clifton 13 ).

Energy adjustment

Due to the potential for confounding due to differences in total energy intake, we analysed the relationship between both absolute and energy-adjusted nutrient intakes and the presence of uncontrolled asthma. Energy adjustment of nutrient intake was performed using the residuals method, in accordance with previously published descriptions( Reference Willett and Stampfer 22 ). The residuals method involves performing a linear regression analysis with nutrient intake as the dependent variable and total energy intake as the independent variable for each nutrient. This regression equation calculates the expected mean nutrient intake of the study population according to the mean total energy intake of the study population. Subsequently, the energy-adjusted intake for each individual was calculated by adding the expected mean macronutrient intake of the study population to the residual derived from the regression analysis.

Statistical analysis

Frequencies and descriptive statistics are expressed as number and percentage and as mean and standard deviation, respectively. Prior to hypothesis testing, data were examined for normality. Distribution was normal except for α-carotene, β-carotene, lutein, lycopene and long-chain n-3 PUFA, which were normalised using natural logarithmic transformation. Calculation of BMI categories was carried out in accordance with the WHO criteria( 23 ). Pearson correlation coefficients were used to test the associations between dietary pattern scores and nutrient intakes. Binary logistic regression analyses were used to test the association between uncontrolled asthma and each dietary pattern (Z-score), with values presented as odds ratio and 95 % confidence interval. All analyses were undertaken adjusting for potential confounders, including maternal age, maternal BMI, smoking status (never/former, quit in pregnancy/current), socio-economic status (level 1 or ≥2), parity (0 or ≥1) and ethnicity (Caucasian or other). Multicollinearity was tested using the variance inflation factor, in which no multicollinearity was observed between any of the independent variables. Differences in mean nutrient intakes between women with controlled and uncontrolled asthma were compared using an unpaired t test. Binary logistic regression analyses were used to test the association between uncontrolled asthma and each nutrient, while adjusting for potential confounders including maternal age, smoking status, socio-economic status, BMI and parity. Statistical significance was considered at P<0·05. All statistical procedures were carried out using the statistical software package IBM SPSS Statistics version 19.

Results

Characteristics of the 158 asthmatic women in the current sample are reported in Table 1. There was no difference in mean weight gain during pregnancy between those with controlled v. uncontrolled asthma (11·13 (se 0·55) kg v. 9·03 (se 1·01) kg, P=0·084).

Table 1 Characteristics of the study population at the first visitFootnote *: asthmatic pregnant women (n 158), Adelaide, Australia, May 2009–July 2013

SABA, slow-acting β agonist; ICS, inhaled corticosteroid; LABA, long-acting β agonist; FEV1,, forced expiratory volume at one second, FVC, forced vital capacity.

* Median 13 weeks’ gestation.

Values presented are mean and standard deviation.

Values presented are number and percentage.

Three dietary patterns were identified (see online supplementary material, Supplemental Table 1). Factor 1 was labelled ‘high protein/fruit’ as there were several protein-rich food groups loading on the pattern (i.e. fish, meat, chicken) as well as fresh fruit and canned fruit. Factor 2 was labelled ‘high fat/sugar/takeaway’ as takeaway foods, crisps, fried potato, refined grains and cakes/pastries loaded on this pattern. Factor 3 was labelled ‘vegetarian-type’ as many of the food groups loading on this pattern were different types of vegetables, soya milk and whole grains. There were strong correlations between the high protein/fruit pattern and long-chain n-3 PUFA, protein, cholesterol and Zn; there were strong correlations between the high fat/sugar/takeaway pattern and total fat, α-linolenic acid, SFA and Na; and there were strong to moderate correlations between the vegetarian-type pattern and fibre, dietary folate and vitamin A retinol equivalents (Table 2).

Table 2 Pearson correlation coefficients (r) between dietary pattern scores and nutrient intakes among asthmatic pregnant women (n 158), Adelaide, Australia, May 2009–July 2013

Only correlations of r>0·40 are included.

All correlations are significant (P≤0·01).

Asthma control was measured at a median of 13 weeks’ gestation. In multivariate regression analysis, a 1 sd increase in the score on the high fat/sugar/takeaway pattern was associated with 50 % increased likelihood for uncontrolled asthma (adjusted OR=1·54; 95 % CI 1·07, 2·23; P=0·022; Table 3). After adjusting for total energy intake, women with uncontrolled asthma had higher intakes of SFA, MUFA, total carbohydrate, sugar and fibre (Table 4). For each additional 40 g of carbohydrate intake, the odds of uncontrolled asthma increased by 40 %, while for each additional 10 g increase in sugar, the odds of uncontrolled asthma increased by 10 % (Table 4).

Table 3 Odds ratios for likelihood of uncontrolled asthmaFootnote * at the first visit during pregnancy according to pre-conception dietary pattern among asthmatic pregnant women (n 158), Adelaide, Australia, May 2009–July 2013

ACQ, Asthma Control Questionnaire.

* According to Global Initiative for Asthma (GINA) classification measured in the first trimester( 17 ) at median 13 weeks’ gestation.

Adjusted for maternal age, maternal BMI, smoking status (never/former, quit in pregnancy/current), socio-economic status (level 1 or ≥2), parity (0 or ≥1) and ethnicity (Caucasian or other).

Indicates change in risk per 1 sd increase in factor score.

Table 4 Mean dietary intakes and nutrient density of the diet according to controlled and uncontrolled asthma status among asthmatic pregnant women (n 158), Adelaide, Australia, May 2009–July 2013

* P value represents differences between controlled asthma and uncontrolled asthma groups.

Logistic regression analysis for each dietary nutrient that included the following covariates in the model: maternal age, smoking status, socio-economic status, BMI and parity.

Indicates change in risk per unit of dietary intake.

Discussion

The current study represents the first piece of evidence linking pre-conception dietary patterns in pregnant women to asthma control. We identified that a dietary pattern containing higher consumption of takeaway foods, fried potato, crisps and refined grains was associated with uncontrolled asthma. Women with uncontrolled asthma had higher intakes of SFA, MUFA, total carbohydrate, sugar and fibre, such that for each additional 40 g of carbohydrate intake, equivalent to 2·5 slices of white bread per day, the odds of uncontrolled asthma increased by 40 %, while for each additional 10 g increase in sugar intake, equivalent to two teaspoons of added sugar per day, the odds of uncontrolled asthma increased by 10 %.

Our findings are important as human epidemiological studies have shown in asthmatic adults that higher fat and lower fibre intakes were associated with worse airway inflammation and lung function( Reference Berthon, Macdonald-Wicks and Gibson 9 ) and fast-food consumption ≥3 times per week was associated with increased risk of severe asthma in children and adolescents( Reference Ellwood, Asher and Garcia-Marcos 24 ). Most recently, in a meta-analysis of observational studies, total intake of fruit and vegetables was inversely associated with risk of asthma in adults (six studies: RR=0·64; 95 % CI 0·41, 1·01) and children (two studies: RR=0·57; 95 % CI 0·42, 0·77), but higher consumption of fruit and vegetables during pregnancy was not associated with risk of asthma in offspring( Reference Seyedrezazadeh, Moghaddam and Ansarin 25 ). Acute studies in human subjects have demonstrated that a single high-fat meal increased exhaled nitric oxide( Reference Rosenkranz, Townsend and Steffens 7 ), increased circulating fatty acid levels and percentage neutrophils in sputum, and attenuated airway bronchodilator responses( Reference Wood, Garg and Gibson 8 ). Comparatively, a randomised controlled trial showed that two servings of fruit and five servings of vegetables daily reduced the risk of asthma exacerbation in adults with stable asthma( Reference Wood, Garg and Smart 10 ). Animal studies have also shown that a high-fat diet can induce pro-inflammatory responses both systemically( Reference Chalkiadaki and Guarente 26 ) and in the lungs( Reference de Vries, Hazlewood and Fitch 27 ). SFA can induce an inflammatory response via activation of pattern recognition receptors( Reference Scott, Jensen and Wood 28 ) and by activation of downstream pro-inflammatory signalling pathways( Reference Kennedy, Martinez and Chuang 29 ). Worsening asthma in pregnancy could therefore be attributable in part to dietary intake.

Previous studies have shown that pre-conception diet does not differ significantly from dietary habits during pregnancy( Reference Crozier, Robinson and Godfrey 30 , Reference Cuco, Fernandez-Ballart and Sala 31 ). Although the mechanisms linking pre-conception diet with maternal and neonatal outcomes have not been investigated in human subjects, the Dutch famine studies that occurred during 1944–1945( Reference Hart 32 , Reference Lumey and Stein 33 ) are probably the closest data that show how the timing of nutrients from the mother to the fetus impacts perinatal outcomes in both the short and long term. It was identified that babies exposed to famine in late gestation had reduced growth compared with babies not exposed to famine, whereas babies who were exposed to famine in early gestation were heavier at birth( Reference Stein, Zybert and van de Bor 34 ). Interestingly, in adulthood, those who were exposed to famine in early gestation (and were heavier at birth) had a more atherogenic lipid profile( Reference Roseboom, van der Meulen and Osmond 35 ), a higher BMI( Reference Roseboom, van der Meulen and Osmond 35 , Reference Roseboom, van der Meulen and Ravelli 36 ) and typically had higher risk of CHD( Reference Ravelli, van Der Meulen and Osmond 37 , Reference Roseboom, van der Meulen and Osmond 38 ). The prevalence of obstructive airways disease was increased in people exposed to famine in mid-gestation (OR=1·7; 95 % CI 1·1, 2·6) and non-significantly higher in those exposed in early gestation (OR=1·5; 95 % CI 0.9, 2·6)( Reference Lopuhaa, Roseboom and Osmond 39 ). Thus, alterations in fetal nutritional supply can drive developmental adaptations influencing growth and metabolism. These results, and ours, demonstrate how nutritional challenges periconceptionally and in early gestation can influence maternal and perinatal outcomes.

A limitation of the present study includes the relative small sample size of asthmatic women, which is reflected in the relatively large confidence intervals generated in the multivariate analysis. As such, it is not possible to rule out a smaller, yet still clinically significant difference between the dietary patterns and asthma control, beyond those observed in the study. Therefore, the full effect of maternal diet on asthma control is still worthy of investigation in subsequent larger studies. The FFQ is a reliable tool covering long-term food intake and the FFQ used in the current study has been validated in women of childbearing age( Reference Hodge, Patterson and Brown 40 ), as well as in young( Reference Hebden, Kostan and O'Leary 41 ) and older( Reference Xinying, Noakes and Keogh 42 ) adults. However, use of the questionnaire also has limitations including memory recall, and several details of dietary intake are not measured; thus quantification of intake is not as accurate as with repeated 24 h recalls or food records. Inaccuracies may also result from an incomplete listing of all possible foods and from errors in frequency and usual serving size estimations. In addition, although women were informed of the dietary intake period to cover, it is possible that current (i.e. first trimester) dietary intakes might have influenced the records. However, as this was a retrospective report about dietary intakes prior to pregnancy, a food frequency approach was necessary. Unpublished data from our 24 h recalls, which were collected throughout gestation, indicated that similar foods (i.e. fruits, takeaways, butter, cereal-based dishes, vegetables) were consumed by a high percentage of women. In the literature, there is limited information on diet before pregnancy; however, the few studies that have been published reported minimal differences in dietary patterns just prior to and during pregnancy( Reference Crozier, Robinson and Godfrey 30 , Reference Cuco, Fernandez-Ballart and Sala 31 ), in which one of these studies identified the dietary patterns persisted 6 months postpartum( Reference Cuco, Fernandez-Ballart and Sala 31 ). Strengths of the present study include the detailed assessment of asthma control and the use of lung function tests to confirm asthma status. Further studies have the potential to expand on these findings by assessing dietary patterns and the relationship to asthma exacerbations, and conducting randomised controlled trials in asthmatic pregnant women to assess the positive effects of dietary manipulation on asthma outcomes.

Dietary intake is an important modifiable risk factor for asthma and our data suggest that nutrition pre-pregnancy influences maternal asthma control during pregnancy. This work highlights the importance of promoting a healthy diet that is low in saturated fat, sugar and takeaway foods, and therefore higher in lean meats, poultry and fish, as well as fruits, vegetables and whole grains. This dietary pattern needs to be encouraged to all asthmatic women who are of childbearing age, and should additionally be promoted during pregnancy and beyond.

Acknowledgements

Acknowledgements: The authors acknowledge Karen Rivers, Sarah Riley, Kate Roberts-Thomson, Jessica Forrest, Annette Osei-Kumah and Nicolette Hodyl for their contribution to the management of the study and collection of the data. Financial support: Funding support was provided by the National Health and Medical Research Council Senior Research Fellowship (ID 510703 to V.L.C.) and the National Health and Medical Research Council Early Career Fellowship (ID 1070421 to L.E.G.). The National Health and Medical Research Council had no role in the design, analysis or writing of this article. Conflict of interest: None. Authorship: J.A.G. was responsible for the conception and design and acquisition of data; L.E.G. was responsible for the analysis and interpretation of data; J.A.G. was responsible for drafting the article; all authors were responsible for revising the article critically for important intellectual content and providing final approval of the version to be published. Ethics of human subject participation: The project was approved by The Queen Elizabeth Hospital and Lyell McEwin Hospital Human Research Ethics Committee and The University of Adelaide Human Research Ethics Committee. All participants gave written informed consent.

Supplementary material

To view supplementary material for this article, please visit http://dx.doi.org/10.1017/S1368980015001226

References

1. Clark, JM, Hulme, E, Devendrakumar, V et al. (2007) Effect of maternal asthma on birthweight and neonatal outcome in a British inner-city population. Paediatr Perinat Epidemiol 21, 154162.Google Scholar
2. Kurinczuk, JJ, Parsons, DE, Dawes, V et al. (1999) The relationship between asthma and smoking during pregnancy. Women Health 29, 3147.Google Scholar
3. Kwon, HL, Belanger, K & Bracken, MB (2003) Asthma prevalence among pregnant and childbearing-aged women in the United States: estimates from national health surveys. Ann Epidemiol 13, 317324.Google Scholar
4. Murphy, VE, Namazy, JA, Powell, H et al. (2011) A meta-analysis of adverse perinatal outcomes in women with asthma. BJOG 118, 1314–123.Google Scholar
5. Namazy, JA, Murphy, VE, Powell, H et al. (2013) Effects of asthma severity, exacerbations and oral corticosteroids on perinatal outcomes. Eur Respir J 41, 10821090.CrossRefGoogle ScholarPubMed
6. Powell, H, Murphy, VE, Taylor, DR et al. (2011) Management of asthma in pregnancy guided by measurement of fraction of exhaled nitric oxide: a double-blind, randomised controlled trial. Lancet 378, 983990.Google Scholar
7. Rosenkranz, SK, Townsend, DK, Steffens, SE et al. (2010) Effects of a high-fat meal on pulmonary function in healthy subjects. Eur J Appl Physiol 109, 499506.CrossRefGoogle ScholarPubMed
8. Wood, LG, Garg, ML & Gibson, PG (2011) A high-fat challenge increases airway inflammation and impairs bronchodilator recovery in asthma. J Allergy Clin Immunol 127, 11331140.CrossRefGoogle ScholarPubMed
9. Berthon, BS, Macdonald-Wicks, LK, Gibson, PG et al. (2013) Investigation of the association between dietary intake, disease severity and airway inflammation in asthma. Respirology 18, 447454.Google Scholar
10. Wood, LG, Garg, ML, Smart, JM et al. (2012) Manipulating antioxidant intake in asthma: a randomized controlled trial. Am J Clin Nutr 96, 534543.Google Scholar
11. Uusitalo, U, Arkkola, T, Ovaskainen, ML et al. (2009) Unhealthy dietary patterns are associated with weight gain during pregnancy among Finnish women. Public Health Nutr 12, 23922399.CrossRefGoogle ScholarPubMed
12. Thompson, JM, Wall, C, Becroft, DM et al. (2010) Maternal dietary patterns in pregnancy and the association with small-for-gestational-age infants. Br J Nutr 103, 16651673.CrossRefGoogle ScholarPubMed
13. Grieger, JA, Grzeskowiak, LE & Clifton, VL (2014) Preconception dietary patterns in human pregnancies are associated with preterm delivery. J Nutr 144, 10751080.Google Scholar
14. Miyake, Y, Okubo, H, Sasaki, S et al. (2011) Maternal dietary patterns during pregnancy and risk of wheeze and eczema in Japanese infants aged 16–24 months: the Osaka Maternal and Child Health Study. Pediatr Allergy Immunol 22, 734741.Google Scholar
15. McLernon, PC, Wood, LG, Murphy, VE et al. (2012) Circulating antioxidant profile of pregnant women with asthma. Clin Nutr 31, 99107.Google Scholar
16. Humbert, M, Holgate, S, Boulet, LP et al. (2007) Asthma control or severity: that is the question. Allergy 62, 95101.CrossRefGoogle ScholarPubMed
17. Global Initiative for Asthma (2012) GINA Report. Global Strategy for Asthma Management Prevention. http://www.ginasthma.org/ (accessed March 2013).Google Scholar
18. Gore, CJ, Crockett, AJ, Pederson, DG et al. (1995) Spirometric standards for healthy adult lifetime nonsmokers in Australia. Eur Respir J 8, 773782.Google Scholar
19. Ambrosini, GL, Oddy, WH, Robinson, M et al. (2009) Adolescent dietary patterns are associated with lifestyle and family psycho-social factors. Public Health Nutr 12, 18071815.CrossRefGoogle ScholarPubMed
20. Schulze, MB, Hoffmann, K, Kroke, A et al. (2003) An approach to construct simplified measures of dietary patterns from exploratory factor analysis. Br J Nutr 89, 409419.CrossRefGoogle ScholarPubMed
21. Kline, PK (1994) An Easy Guide to Factor Analysis. London/New York: Routledge.Google Scholar
22. Willett, WC & Stampfer, M (1998) Implications of total energy intake for epidemiologic analysis. In Nutritional Epidemiology, 2nd ed., pp. 273301 [WC Willett, editor]. New York: Oxford University Press, Inc. Google Scholar
23. World Health Organization (2013) Obesity and Overweight. Fact Sheet no. 311. Geneva: WHO; available at http://www.who.int/mediacentre/factsheets/fs311/en/ Google Scholar
24. Ellwood, P, Asher, MI, Garcia-Marcos, L et al. (2013) Do fast foods cause asthma, rhinoconjunctivitis and eczema? Global findings from the International Study of Asthma and Allergies in Childhood (ISAAC) phase three. Thorax 68, 351360.Google Scholar
25. Seyedrezazadeh, E, Moghaddam, MP, Ansarin, K et al. (2014) Fruit and vegetable intake and risk of wheezing and asthma: a systematic review and meta-analysis. Nutr Rev 72, 411428.CrossRefGoogle ScholarPubMed
26. Chalkiadaki, A & Guarente, L (2012) High-fat diet triggers inflammation-induced cleavage of SIRT1 in adipose tissue to promote metabolic dysfunction. Cell Metab 16, 180188.Google Scholar
27. de Vries, A, Hazlewood, L, Fitch, PM et al. (2009) High-fat feeding redirects cytokine responses and decreases allergic airway eosinophilia. Clin Exp Allergy 39, 731739.CrossRefGoogle ScholarPubMed
28. Scott, HA, Jensen, ME & Wood, LG (2014) Dietary interventions in asthma. Curr Pharm Des 20, 10031010.CrossRefGoogle ScholarPubMed
29. Kennedy, A, Martinez, K, Chuang, CC et al. (2009) Saturated fatty acid-mediated inflammation and insulin resistance in adipose tissue: mechanisms of action and implications. J Nutr 139, 14.Google Scholar
30. Crozier, SR, Robinson, SM, Godfrey, KM et al. (2009) Women’s dietary patterns change little from before to during pregnancy. J Nutr 139, 19561963.Google Scholar
31. 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.Google Scholar
32. Hart, N (1993) Famine, maternal nutrition and infant mortality: a re-examination of the Dutch hunger winter. Popul Stud 47, 2746.Google Scholar
33. Lumey, LH & Stein, AD (1997) In utero exposure to famine and subsequent fertility: the Dutch Famine Birth Cohort Study. Am J Public Health 87, 19621966.Google Scholar
34. Stein, AD, Zybert, PA, van de Bor, M et al. (2004) Intrauterine famine exposure and body proportions at birth: the Dutch Hunger Winter. Int J Epidemiol 33, 831836.CrossRefGoogle ScholarPubMed
35. Roseboom, TJ, van der Meulen, JH, Osmond, C et al. (2000) Plasma lipid profiles in adults after prenatal exposure to the Dutch famine. Am J Clin Nutr 72, 11011106.CrossRefGoogle Scholar
36. Roseboom, TJ, van der Meulen, JH, Ravelli, AC et al. (2000) Plasma fibrinogen and factor VII concentrations in adults after prenatal exposure to famine. Br J Haematol 111, 112117.CrossRefGoogle ScholarPubMed
37. Ravelli, AC, van Der Meulen, JH, Osmond, C et al. (1999) Obesity at the age of 50 y in men and women exposed to famine prenatally. Am J Clin Nutr 70, 811816.Google Scholar
38. Roseboom, TJ, van der Meulen, JH, Osmond, C et al. (2000) Coronary heart disease after prenatal exposure to the Dutch famine, 1944–45. Heart 84, 595598.Google Scholar
39. Lopuhaa, CE, Roseboom, TJ, Osmond, C et al. (2000) Atopy, lung function, and obstructive airways disease after prenatal exposure to famine. Thorax 55, 555561.Google Scholar
40. Hodge, A, Patterson, AJ, Brown, WJ et al. (2000) The Anti Cancer Council of Victoria FFQ: relative validity of nutrient intakes compared with weighed food records in young to middle-aged women in a study of iron supplementation. Aust N Z J Public Health 24, 576583.Google Scholar
41. Hebden, L, Kostan, E, O'Leary, F et al. (2013) Validity and reproducibility of a food frequency questionnaire as a measure of recent dietary intake in young adults. PLoS One 8, e75156.Google Scholar
42. Xinying, PX, Noakes, M & Keogh, J (2004) Can a food frequency questionnaire be used to capture dietary intake data in a 4 week clinical intervention trial? Asia Pac J Clin Nutr 13, 318323.Google Scholar
Figure 0

Table 1 Characteristics of the study population at the first visit*: asthmatic pregnant women (n 158), Adelaide, Australia, May 2009–July 2013

Figure 1

Table 2 Pearson correlation coefficients (r) between dietary pattern scores and nutrient intakes among asthmatic pregnant women (n 158), Adelaide, Australia, May 2009–July 2013

Figure 2

Table 3 Odds ratios for likelihood of uncontrolled asthma* at the first visit during pregnancy according to pre-conception dietary pattern among asthmatic pregnant women (n 158), Adelaide, Australia, May 2009–July 2013

Figure 3

Table 4 Mean dietary intakes and nutrient density of the diet according to controlled and uncontrolled asthma status among asthmatic pregnant women (n 158), Adelaide, Australia, May 2009–July 2013

Supplementary material: File

Grieger supplementary material

Table S1

Download Grieger supplementary material(File)
File 53.2 KB