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Validation of self-reported folic acid use in a multiethnic population: results of the Amsterdam Born Children and their Development study

Published online by Cambridge University Press:  16 February 2011

Jonne J Sikkens
Affiliation:
Department of Clinical Genetics, EMGO Institute for Health and Care Research, VU University Medical Center, BS7, D423, PO Box 7057, 1007 MB Amsterdam, The Netherlands
Manon van Eijsden
Affiliation:
Department of Epidemiology, Documentation and Health Promotion, Public Health Service of Amsterdam, The Netherlands Department of Social Medicine, Academic Medical Centre, University of Amsterdam, The Netherlands
Gouke J Bonsel
Affiliation:
Department of Public Health, Institute of Health Policy and Management, Erasmus University, Rotterdam, The Netherlands
Martina C Cornel*
Affiliation:
Department of Clinical Genetics, EMGO Institute for Health and Care Research, VU University Medical Center, BS7, D423, PO Box 7057, 1007 MB Amsterdam, The Netherlands
*
*Corresponding author: Email [email protected]
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Abstract

Objective

To assess folic acid supplementation rates and validate the self-reporting of folic acid supplement use among pregnant women in a multiethnic cohort.

Design

Secondary analysis of a prospective cohort study.

Setting

Self-reported folic acid supplement use in the Amsterdam Born Children and their Development study cohort was compared with serum folate concentrations using non-parametric trend analysis and linear and logistic regression.

Subjects

A total of 4234 pregnant women of various ethnic backgrounds.

Results

Serum folate levels showed a significant positive linear trend as reported use of folic acid increased (P < 0·001), which was supported by linear regression (r = 0·49). Odds of having low serum folate concentration decreased with reported early start of folic acid intake. Young, multiparous or non-Western women reported less pre-conception folic acid intake. Non-Western women showed lower serum folate concentrations. The overall rate of over-reporting, i.e. serum folate concentrations ≤20 nmol/l while reporting the use of folic acid supplements, was 20·7 %. Women of Surinamese and Moroccan ancestry had higher odds of over-reporting (OR = 2·3; 95 % CI 1·5, 3·5 and OR = 2·3; 95 % CI 1·3, 4·0, respectively). The odds for Surinamese women remained significant after adjusting for the onset of supplement use, parity and age (OR = 1·7; 95 % CI 1·1, 2·6).

Conclusions

Although self-reporting is a valid method for assessing folic acid supplement use in a multiethnic population, some participants do over-report. Surinamese and possibly Moroccan women appear to over-report more often. Rates of supplementation are low, especially in non-Western women. This suggests the need for intensifying current campaigns or perhaps even additional advice to start or continue to use folic acid post-conceptionally.

Type
Research paper
Copyright
Copyright © The Authors 2011

A low maternal serum folate concentration before conception and during the first weeks after conception is associated with an increased risk of fetal neural tube defects (NTD) and other non-NTD birth defects(Reference Wilcox, Lie and Solvoll1Reference Canfield, Collins and Botto3) and can be prevented by the intake of folic acid(4). Adequate folic acid supplementation has been shown to substantially increase folate serum levels(Reference Nelen, Blom and Thomas5). Although prophylactic use is widely recommended in public campaigns, recent studies suggest little or no improvement in NTD prevalence by self-intake(Reference Busby, Abramsky and Dolk6), which raises the question as to whether behavioural change did occur.

Ideally, adherence to the recommendations is measured by serum folate status in conjunction with reported use; however, most epidemiological studies rely on self-report only, as this is less invasive and cheap. Being a socially desirable behaviour, self-reported use is prone to response bias, which raises questions regarding the actual validity of this measure. A study by Burton et al.(Reference Burton, Wilson and Gillies7) showed that, although intake reports and folate levels are well correlated, over-reporting is present in 7 % of respondents. However, Burton et al.'s(Reference Burton, Wilson and Gillies7) study was limited to mainly white participants. Although evidence suggests that race or ethnicity does not influence socially desirable responding by itself, factors such as divorce rate, birth rate, level of education and rate of employment do influence socially desirable responding, and these factors are often not similar across ethnic groups(Reference Edwards8Reference Twenge and Im10). Therefore, ethnic differences in over-reporting of folic acid supplementation could be expected. Insight into these mechanisms is essential in order to improve public health policies. Using data from a multiethnic cohort in the Netherlands – the Amsterdam Born Children and their Development (ABCD) cohort – we investigated the rates of supplementation and the validity of self-reported folic acid supplementation in terms of over-reporting.

Methods

Data collection

Data were obtained from the ABCD study in 2003 and 2004. The present cohort study included pregnant women at their first antenatal control visit to a health professional. Consenting women had a questionnaire sent to their homes a few weeks later. In addition, women were asked to participate in a biomarker study. This entailed a blood sample being collected in conjunction with routine prenatal screening following the control visit. The blood sample collection procedure included samples sent by mail or courier, which could lead to a maximum delay of 28 h between collection and processing. However, this diminished precision of estimates did not jeopardise the integrity of epidemiological research(Reference van Eijsden, van der Wal and Hornstra11). Serum folate concentrations were measured by immunoassay with chemiluminescence detection on the Advia Centaur System (Bayer Group, Leverkusen, Germany)(Reference Owen and Roberts12). Values of serum folate above the detection limit of 63 nmol/l were set to 64 nmol/l.

Measures

Responses to the question ‘What is your country of birth?’ were used to classify women into groups according to their ethnic background. Responses to the question ‘Which community do you consider yourself to belong to?’ were available to further classify respondents into ethnic groups similar to the study by Burton et al.(Reference Burton, Wilson and Gillies7). The questionnaire contained the following three questions assessing folic acid supplement use (possible answers in brackets): (i) ‘Did you use folic acid supplements or folic acid containing multivitamins before or during your pregnancy?’ (yes; no), if yes: (ii) ‘When did you start taking folic acid?’ (before the pregnancy; as soon as I knew I was pregnant; later during the pregnancy) and (iii) ‘When did you stop taking folic acid?’ (before the pregnancy; as soon as I knew I was pregnant; later during the pregnancy; I have not stopped yet). The responses to these questions were combined into four groups according to the onset of folic acid supplement use (Table 1).

Table 1 Linear and logistic regression model for correlates of serum folate concentration among 4234 pregnant women of different ethnic backgrounds, Amsterdam Born Children and their Development study

IQR, interquartile range.

†Corrected for parity, age and ethnicity.

Analysis

The Wilcoxon-type test for trend was used to test for a linear trend in serum folate across groups(Reference Cuzick13). Linear regression was used to compare serum folate concentrations between folic acid supplement use groups, adjusting for parity, age and ethnicity. In addition, a dichotomous variable was created to indicate low serum folate status. For this we used a cut-off limit of 20 nmol/l because 2 months of adequate folic acid supplementation has been shown to lead to a minimum serum folate level of 20 nmol/l(Reference Nelen, Blom and Thomas5). Logistic regression was used to compare the odds of low serum folate status between folic acid supplement use groups, adjusting for parity, age and ethnicity.

To assess the effects of ethnicity, we first compared serum folate concentrations and the occurrence of low serum folate across ethnic groups. Using Levene's statistic, we assessed that variances of serum folate concentrations were not homogeneous across groups. Therefore, we compared serum folate concentrations over ethnic groups by testing for equality of means by Brown–Forsythe and we compared groups using the Tamhane test. A logistic regression model (adjusting for folic acid supplement use, age and parity) was used to compare odds of having low serum folate level (≤20 nmol/l).

To assess over-reporting, a variable was constructed by allocating women to one of two groups: (i) women reporting folic acid use while their serum folate concentration showed a value ≤20 nmol/l and (ii) all other women. Finally, to assess over-reporting in ethnic groups, a logistic regression model was used to compare the odds of having a low serum folate level ≤20 nmol/l in women who reported folic acid supplement use, adjusting for onset of folic acid supplement use, age and parity. Consequently, women not reporting folic acid use are missing from this specific analysis. OR was reported as the measure of association. All analyses were performed using the Statistical Package for the Social Sciences statistical software package for Windows version 15·0·1 (SPSS Inc., Chicago, IL, USA).

Results

Subjects

Of 12 373 pregnant women, 8266 (67 %) returned a completed questionnaire, and of these women 4389 (53 %) also provided a blood sample. Cases with incomplete information on folic acid supplement use or with an inconclusive blood sample were excluded, leaving 4234 cases for analysis. The median age was 32 (range: 15–44) years and 2452 (58 %) women were nulliparous. Median gestational age was 13 weeks at the time of blood collection and 16 weeks at questionnaire completion. Most women were born in the Netherlands (69 %), followed by Morocco (5 %), Suriname (5 %), Turkey (3 %), Ghana (1 %) and the Dutch Antilles and Aruba (1 %), with 9 % and 7 % being born in another Western or non-Western country, respectively. Using the question ‘Which community do you consider yourself to belong to?’ 69 % of women classified themselves as belonging to the indigenous, white population.

Reported folic acid supplement use

Only 39·9 % of women used folic acid as recommended: before conception or at least before they knew they were pregnant (Table 1). In all, 43% of nulliparous or primiparous women reported using folic acid as recommended, compared with 20 % of multiparous women. Women aged ≥25 years used folic acid as recommended in 45 % of cases, whereas this was the case in only 11 % of women aged <25 years. Rates of folic acid use as recommended were much lower in non-indigenous women compared with women born in the Netherlands, with rates among women of non-Western ancestry not exceeding 25 % (Table 2).

Table 2 Logistic regression model for serum folate levels according to maternal country of birth among 4234 pregnant women of different ethnic backgrounds, Amsterdam Born Children and their Development study

IQR, interquartile range.

Folic acid supplement use as recommended: onset before awareness of pregnancy.

*Mean values were significantly different from those of mothers born in the Netherlands (Tahmane test): P < 0·001.

†Corrected for parity and age.

‡Corrected for onset/start of supplement use, parity and age.

Validity of self-reported folic acid supplement use

There was a significant linear trend in serum folate levels as reported duration of use of folic acid supplements increased (Z = 36·5, P < 0·001). Use of folic acid supplements was positively correlated with serum folate concentration (r = 0·49, P < 0·001). After adjusting for parity, age and ethnicity, the positive correlation remained significant (r = 0·51, P < 0·001). Table 1 shows that folic acid supplement use before pregnancy, after being aware of pregnancy and later in pregnancy was associated with a lower prevalence of serum folate ≤20 nmol/l (P < 0·001), which remained significant after adjusting for parity, age and ethnicity (P < 0·001). Over-reporting was present in 20·7 % of cases.

Serum folate in ethnic groups

Serum folate concentrations varied significantly according to maternal country of birth (Brown–Forsythe (df = 7928), P < 0·001; for between-group comparisons see Table 2). Women of non-indigenous ancestry had significantly more frequent serum folate concentrations ≤20 nmol/l, except for women of Western ancestry. This remained significant after adjusting for parity and age (for OR, see Table 2). When adjusting for onset/start of supplement use, parity and age, women of Surinamese and Moroccan ancestry had significantly more frequent serum folate concentrations ≤20 nmol/l (OR = 2·0; 95 % CI 1·3, 2·8 and OR = 1·7; 95 % CI 1·1, 2·6, respectively).

Over-reporting in ethnic groups

Among women reporting folic acid supplement use, women of either Surinamese or Moroccan ancestry had serum folate level ≤20 nmol/l significantly more often, interpreted as over-reporting (OR = 2·3; 95 % CI 1·5, 3·5 and OR = 2·3; 95 % CI 1·3, 4·0, respectively). After adjusting for onset of supplement use, parity and age, this remained significant only for women of Surinamese ancestry (OR = 1·7; 95 % CI 1·1, 2·6). Complete results are shown in Table 3.

Table 3 Odds of over-reporting on folic acid supplementation (serum folate concentration ≤ 20 nmol/l) in women who reported folic acid supplement useFootnote according to maternal country of birth, Amsterdam Born Children and their Development study

Women not reporting folic acid supplement use are missing in this table.

Corrected for onset of folic acid supplement use, parity and age.

Discussion

Strengths and limitations

Folic acid supplementation use before conception is recommended because it provides health benefits for the unborn child. Questions have arisen regarding whether women are complying with this recommendation. Previous research in which folic acid supplement use was evaluated has generally used self-report measures for quantification. However, until now these measures have been validated in only one previous study. That study used non-parametric trend analysis and was conducted in a mainly white population(Reference Burton, Wilson and Gillies7). Self-report measures leave room for over-reporting. The present study aimed at validating a self-report questionnaire in a large multiethnic cohort using non-parametric trend analysis as well as linear and logistic regression. In the current cohort, 69 % of women classified themselves as belonging to the indigenous, white population compared with 80 % in the study by Burton et al.(Reference Burton, Wilson and Gillies7). Response rates in the present study were higher than the response rates in comparable multiethnic surveys(Reference Galea and Tracy14, Reference Jaddoe, Mackenbach and Moll15). Nevertheless, the possibility of selection bias exists. Because the blood sample procedure allowed for degradation of folate concentrations before analysis, exact levels could not be ascertained; however, as reported by van Eijsden et al.(Reference van Eijsden, van der Wal and Hornstra11), it still allowed for correct classification. Contrary to our study, the study from which our cut-off limit of ≤20 nmol/l originated was based on subjects with unexplained pregnancy loss who might have lower levels of serum folate than other women(Reference Nelen, Blom and Thomas5). This may have possibly caused the cut-off limit to be lower than it should have. Consequently, our over-reporting outcomes could be an underestimation. On the other hand, this would have led to fewer women being falsely labelled as over-reporting.

Reported folic acid supplement use

Only 39·9 % of women reported the use of folic acid supplements as recommended: before conception or at least before they knew they were pregnant. Rates were lower for women aged <25 years and for multiparous women, as described in the literature(Reference de Walle and de Jong-van den Berg16). Furthermore, non-Western women also showed low rates of reported folic acid supplement use as recommended, which has been reported previously(Reference Bakker, Cornel and de Walle17, Reference van Eijsden, van der Wal and Bonsel18).

Validity of self-reported folic acid supplement use

Both the linear relationship and the moderately strong positive association between serum folate levels and reported use of folic acid supplements suggest that as women take folic acid, their serum folate levels increase correspondingly. Combined with the lower probability of a serum folate concentration ≤20 nmol/l if women report supplement use, this suggests that the self-reported use of folic acid supplements is a valid measure of folate status. The latter effect is stronger with early start of use, which is a very important point because the majority of research focuses on the possible effects of folate deficiency and less so on the spectrum of serum folate concentrations.

Women reportedly using folic acid as recommended had an OR of 0·07 (95% CI 0·05, 0·08) for low serum folate concentration (≤20 nmol/l). However, serum folate concentration ≤20 nmol/l was found in 19·4 % of these women. Women who reported taking supplements only later during pregnancy (which could be for a very short period of time) presented with low serum folate level in 49·6 % of cases. These high proportions could perhaps be explained by the time gap between the moment of blood collection (median = 13 weeks) and questionnaire completion (median = 16 weeks), during which period women could have started and consequently reported using supplements. Over-reporting (present in 20·7 % of cases) could also add to this effect. However, over-reporting was similar to the report by Burton et al.(Reference Burton, Wilson and Gillies7) when comparing over-reporting rates using the cut-off limit used by that study (14 nmol/l): 8·9 % v. 7 %.

Serum folate in ethnic groups

Serum folate concentrations were significantly lower in all non-indigenous groups compared with those in indigenous women (except for women born in the Dutch Antilles and Aruba). In addition, non-Western women also had higher odds of having low serum folate concentration. We will discuss the following possible causes: folate consumption, folate degradation due to time gap, genetic differences and language skills. These low concentrations are not surprising considering the low supplementation rates among these women. However, when adjusting for supplementation, women of Surinamese and Moroccan ancestry still had higher odds of having a low serum folate concentration, even when adjusting for parity and age. A possible factor responsible for these findings is a diet low in folate. Women having either Moroccan or Turkish ancestry are reported to have a diet low in vegetables (which generally contain folate). However, the opposite is the case for women of Surinamese ancestry(Reference Palsma, Nicolaou and van Dam19, Reference Nicolaou, van Dam and Stronks20). Another factor could be the degradation of folic acid during the time gap between collection and processing. The length of this gap was determined by the location of the practice of the health professional where the blood was collected. Non-indigenous women consulted health professionals in hospitals more often, who processed the blood samples faster. However, in post hoc analysis no significant difference between hospital- and non-hospital-processed serum folate was found (P = 0·95). Recent research has shown that genetic polymorphisms such as the MTHFR 677C→T genotype are associated with low serum folate(Reference Yang, Botto and Gallagher21). Prevalence of these polymorphisms varies between ethnic groups but specific data on the non-indigenous groups in the Netherlands are not yet available. Finally, another factor could be over-reporting due to other reasons, which are discussed below.

Over-reporting in ethnic groups

Women having Surinamese or Moroccan ancestry over-reported significantly more frequently (OR = 2·3; 95 % CI 1·5, 3·5 and OR = 2·3; 95 % CI 1·3, 4·0, respectively), but the adjusted OR was significant only for women of Surinamese ancestry (OR = 1·7; 95 % CI 1·1, 2·6). Because the present analysis was performed in a smaller population (women reporting no use were excluded), it is possible that a small sample size caused the loss of significance for the already small group of women of Moroccan ancestry. A seemingly logical explanation for the higher odds of over-reporting by non-indigenous women would be insufficient language skills, which could have led to misinterpretation of the questionnaire. However, this is deemed very unlikely because questionnaires were available in their own language and translators were available for oral administration. In addition, women of Surinamese ancestry generally have good skills in Dutch, especially when compared with women of other non-Western ancestry. Nevertheless, the possible answers to the question ‘When did you start taking folic acid?’ in the questionnaire were not quantitatively exact and may have left room for error. A search of the literature yielded one article focusing on the validity of self-reported pneumococcal vaccination in the USA. That study found effects on the validity of reporting related to ethnicity, but differences in over-reporting between whites, blacks and Latinos were not significant(Reference Gordon, Wortley and Singleton22). This calls for more research to assess self-reporting by women of Surinamese ancestry.

Implications for health policy

The above findings suggest that self-reporting is a valid method of assessing folic acid supplementation in a multiethnic population. However, it should be taken into account that among women reporting supplement use as recommended, low serum folate levels are still present in 20 % of cases. However, over-reporting in the present study was similar to a previous result in the literature. The finding that Surinamese women tend to over-report more cannot yet be explained and requires further study, particularly into the role of dietary and genetic factors. The low rates of women taking folic acid supplements as recommended show that current public health campaigns are failing to reach their goals, especially among non-Western women, young women and multiparous women. These results call for improving or modifying current efforts. This may include advising women to take supplements after conception as well, as women who start taking supplements after knowing that they are pregnant were found to have relatively high concentrations of folic acid. Although this may not be beneficial for the prevention of NTD because the neural tube closes at approximately 4 weeks after conception, it may still have a positive influence on other unfavourable pregnancy outcomes such as placenta-mediated diseases (pre-eclampsia, placental abruption, spontaneous abortion), low birth weight or premature birth(Reference Ray and Laskin23Reference Siega-Riz, Savitz and Zeisel26). This suggests that pregnant women should be advised to start taking folic acid supplements or continue to use it, after conception. In addition, this may help to prevent adverse events in subsequent pregnancies, as past research has shown adverse outcomes in closely spaced pregnancies to be associated with folate deficiency(Reference van Eijsden, Smits and van der Wal27).

Acknowledgements

The study was approved by the medical ethics committee of the VU University Medical Center, Amsterdam, the Netherlands. The Amsterdam Born Children and their Development (ABCD) study is funded by the Netherlands Organisation for Health Research and Development (ZonMw). The authors have no conflict of interest to declare. J.J.S. is credited with creating the study design and with data processing, planning and performing all statistical analyses except parts of the regression analysis, as well as with processing and interpreting results and writing the article. M.v.E. contributed towards collecting the ABCD study data, designing the study, data processing, planning and performing parts of the regression analyses, and was also actively involved in interpreting the results and advising on and co-writing the article. G.J.B. advised on statistical analysis and design, interpreted the results and advised on and co-wrote parts of the article. M.C.C. provided valuable advice on statistical analysis and design, and is also credited with interpreting the results, co-writing the article and advising on and supervising the research project. The authors thank M.F. van der Wal for his contributions to previous versions of the present article, H.J. Blom for his useful comments and P.D. Bezemer for his valuable statistical advice.

References

1.Wilcox, AJ, Lie, RT, Solvoll, K et al. (2007) Folic acid supplements and risk of facial clefts: national population based case–control study. BMJ 334, 433434.CrossRefGoogle ScholarPubMed
2.Tamura, T & Picciano, MF (2006) Folate and human reproduction. Am J Clin Nutr 83, 9931016.CrossRefGoogle ScholarPubMed
3.Canfield, MA, Collins, JS, Botto, LD et al. (2005) Changes in the birth prevalence of selected birth defects after grain fortification with folic acid in the United States: findings from a multi-state population-based study. Birth Defects Res A Clin Mol Teratol 73, 679689.CrossRefGoogle ScholarPubMed
4.MRC Vitamin Study Research Group (1991) Prevention of neural tube defects: results of the Medical Research Council Vitamin Study. Lancet 338, 131137.CrossRefGoogle Scholar
5.Nelen, WLDM, Blom, HJ, Thomas, CMG et al. (1998) Methylenetetrahydrofolate reductase polymorphism affects the change in homocysteine and folate concentrations resulting from low dose folic acid supplementation in women with unexplained recurrent miscarriages. J Nutr 128, 13361341.CrossRefGoogle ScholarPubMed
6.Busby, A, Abramsky, L, Dolk, H et al. (2005) Preventing neural tube defects in Europe: a missed opportunity. Reprod Toxicol 20, 393402.CrossRefGoogle ScholarPubMed
7.Burton, A, Wilson, S & Gillies, AJ (2001) Folic acid: is self reported use of supplements accurate? J Epidemiol Community Health 55, 841842.CrossRefGoogle ScholarPubMed
8.Edwards, DW (1974) Blacks versus Whites: when is race a relevant variable? J Pers Soc Psychol 29, 3949.CrossRefGoogle Scholar
9.Hébert, JR, Peterson, KE, Hurley, TG et al. (2001) The effect of social desirability trait on self reported dietary measures among multi-ethnic female health center employees. Ann Epidemiol 11, 417427.CrossRefGoogle ScholarPubMed
10.Twenge, JM & Im, C (2007) Changes in the need for social approval, 1958–2001. J Res Pers 41, 171189.CrossRefGoogle Scholar
11.van Eijsden, M, van der Wal, MF, Hornstra, G et al. (2005) Can whole-blood samples be stored over 24 hours without compromising stability of C-reactive protein, retinol, ferritin, folic acid, and fatty acids in epidemiologic research? Clin Chem 51, 230232.CrossRefGoogle ScholarPubMed
12.Owen, WE & Roberts, WL (2003) Comparison of five automated serum and whole blood folate assays. Am J Clin Pathol 120, 121126.CrossRefGoogle ScholarPubMed
13.Cuzick, J (1985) A Wilcoxon-type test for trend. Stat Med 4, 8790.CrossRefGoogle ScholarPubMed
14.Galea, S & Tracy, M (2007) Participation rates in epidemiologic studies. Ann Epidemiol 17, 643653.CrossRefGoogle ScholarPubMed
15.Jaddoe, VWV, Mackenbach, JP, Moll, HA et al. (2006) The Generation R Study: design and cohort profile. Eur J Epidemiol 21, 475484.CrossRefGoogle ScholarPubMed
16.de Walle, HE & de Jong-van den Berg, LT (2008) Ten years after the Dutch public health campaign on folic acid: the continuing challenge. Eur J Clin Pharmacol 64, 539543.CrossRefGoogle ScholarPubMed
17.Bakker, MK, Cornel, MC & de Walle, HE (2003) Awareness and periconceptional use of folic acid among non-western and western women in the Netherlands following the 1995 publicity campaign. Ned Tijdschr Geneeskd 147, 24262430.Google ScholarPubMed
18.van Eijsden, M, van der Wal, MF & Bonsel, GJ (2006) Folic acid knowledge and use in a multi-ethnic pregnancy cohort: the role of language proficiency. BJOG 113, 14461451.CrossRefGoogle Scholar
19.Palsma, AH, Nicolaou, M, van Dam, RM et al. (2006) De Voeding van Turkse en Marokkaanse Nederlandse in de leeftijd van 18–30 jaar: prioriteiten voor voedingsinterventies. TSG 84, 415422.Google Scholar
20.Nicolaou, M, van Dam, RM & Stronks, K (2006) Acculturation and education level in relation to quality of the diet: a study of Surinamese South Asian and Afro-Caribbean residents of the Netherlands. J Hum Nutr Diet 19, 383393.CrossRefGoogle Scholar
21.Yang, QH, Botto, LD, Gallagher, M et al. (2008) Prevalence and effects of gene–gene and gene–nutrient interactions on serum folate and serum total homocysteine concentrations in the United States: findings from the third National Health and Nutrition Examination Survey DNA Bank. Am J Clin Nutr 88, 232246.CrossRefGoogle ScholarPubMed
22.Gordon, NP, Wortley, PM, Singleton, JA et al. (2008) Race/ethnicity and validity of self reported pneumococcal vaccination. BMC Public Health 8, 227.CrossRefGoogle Scholar
23.Ray, JG & Laskin, CA (1999) Folic acid and homocyst(e)ine metabolic defects and the risk of placental abruption, pre-eclampsia and spontaneous pregnancy loss: a systematic review. Placenta 20, 519529.CrossRefGoogle ScholarPubMed
24.Wen, SW, Chen, XK, Rodger, M et al. (2008) Folic acid supplementation in early second trimester and the risk of preeclampsia. Am J Obstet Gynecol 198, 45.e145.e7.CrossRefGoogle ScholarPubMed
25.Sram, RJ, Binkova, B, Lnenickova, Z et al. (2005) The impact of plasma folate levels of mothers and newborns on intrauterine growth retardation and birth weight. Mutat Res 591, 302310.CrossRefGoogle ScholarPubMed
26.Siega-Riz, AM, Savitz, DA, Zeisel, SHet al. (2004) Second trimester folate status and preterm birth. Am J Obstet Gynecol 191, 18511857.CrossRefGoogle ScholarPubMed
27.van Eijsden, M, Smits, LJM, van der Wal, MFet al. (2008) Association between short interpregnancy intervals and term birth weight: the role of folate depletion. Am J Clin Nutr 88, 147153.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Linear and logistic regression model for correlates of serum folate concentration among 4234 pregnant women of different ethnic backgrounds, Amsterdam Born Children and their Development study

Figure 1

Table 2 Logistic regression model for serum folate levels according to maternal country of birth among 4234 pregnant women of different ethnic backgrounds, Amsterdam Born Children and their Development study

Figure 2

Table 3 Odds of over-reporting on folic acid supplementation (serum folate concentration ≤ 20 nmol/l) in women who reported folic acid supplement use† according to maternal country of birth, Amsterdam Born Children and their Development study