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Validation of FFQ-based assessment of dietary lignans compared with serum enterolactone in Swedish women

Published online by Cambridge University Press:  25 September 2012

Yulan Lin*
Affiliation:
Unit of Upper Gastrointestinal Research, Department of Molecular Medicine and Surgery, Karolinska Institutet, Norra Stationsgatan 67, 2nd Floor, SE-171 76 Stockholm, Sweden
Alicja Wolk
Affiliation:
Division of Nutritional Epidemiology, The National Institute of Environmental Medicine, Karolinska Institutet, Stockholm, Sweden
Niclas Håkansson
Affiliation:
Division of Nutritional Epidemiology, The National Institute of Environmental Medicine, Karolinska Institutet, Stockholm, Sweden
Jose Luis Peñalvo
Affiliation:
Department of Epidemiology and Populations Genetics, National Center for Cardiovascular Research (CNIC), Madrid, Spain
Jesper Lagergren
Affiliation:
Unit of Upper Gastrointestinal Research, Department of Molecular Medicine and Surgery, Karolinska Institutet, Norra Stationsgatan 67, 2nd Floor, SE-171 76 Stockholm, Sweden Division of Cancer Studies, King's College London, London, UK
Herman Adlercreutz
Affiliation:
Institute for Preventive Medicine, Nutrition and Cancer, Folkhälsan Research Center and Division of Clinical Chemistry, Biomedicum, University of Helsinki, Helsinki, Finland
Yunxia Lu
Affiliation:
Unit of Upper Gastrointestinal Research, Department of Molecular Medicine and Surgery, Karolinska Institutet, Norra Stationsgatan 67, 2nd Floor, SE-171 76 Stockholm, Sweden
*
*Corresponding author: Y. Lin, fax +46 8 517 76280, email: yulan.lin@ki.se
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Abstract

The validity of using FFQ to assess dietary lignans is uncertain. We aimed to validate the use of FFQ for the assessment of dietary intake of lignans compared to the serum biomarker enterolactone, the main product of dietary lignans' metabolism in human subjects. A random sample of women, aged 55–75 years, from the Swedish Mammography Cohort was selected. Information from two FFQ, the FFQ-87 (sixty-seven food items) and the FFQ-97 (ninety-three food items), and blood samples were collected. Dietary intake of lignans (secoisolariciresinol, matairesinol, lariciresinol, pinoresinol, medioresinol and syringaresinol) was assessed by the FFQ. Serum concentrations of enterolactone were analysed by time-resolved fluoroimmunoassay. The correlation coefficient between energy-adjusted lignan intake and serum enterolactone was estimated in crude and multivariable-adjusted models, taking into account the factors potentially influencing the serum enterolactone. Among the 135 participants aged 55–75 years, with a mean BMI of 26·7 kg/m2, the average energy-adjusted intake of total lignans was 1616 (sd 424) and 1516 (sd 409) μg/d according to the FFQ-87 (forty-five food items containing lignans) and the FFQ-97 (sixty-five food items containing lignans), respectively. The mean concentration of serum enterolactone was 23·2 (sd 15·4) nmol/l. The adjusted Pearson's correlation between dietary intake of lignans assessed by the FFQ-97 and serum enterolactone was statistically significant (r 0·22, P= 0·01). No significant correlation was observed for the FFQ-87 (r 0·09, P= 0·30). The present study indicates that the FFQ-97 might be better than the FFQ-87 for assessing dietary intake of lignans, although the correlation was low.

Type
Full Papers
Copyright
Copyright © The Authors 2012 

Phyto-oestrogens are naturally occurring polyphenolic plant compounds with hormone-like activity(Reference Adlercreutz, Bannwart and Wahala1, Reference Adlercreutz and Mazur2). Lignans, present in, for example, wholegrain products, berries, fruits, vegetables, flaxseed and sesame seed, are the most abundant phyto-oestrogens in Western diets(Reference Adlercreutz3). After consumption, lignans are converted by the gut microflora into the so-called enterolignans, enterolactone and its immediate precursor enterodiol(Reference Adlercreutz and Mazur2, Reference Borriello, Setchell and Axelson4, Reference Setchell, Lawson and Borriello5). Until now, six plant lignans have been identified as precursors of enterolactone, including secoisolariciresinol (SEC), matairesinol (MAT), lariciresinol (LAR), pinoresinol (PIN), medioresinol (MED) and, to a minimal extent, syringaresinol (SYR)(Reference Adlercreutz3). Some studies have indicated that dietary phyto-oestrogens protect against CVD(Reference Vanharanta, Voutilainen and Lakka6, Reference Reynolds, Chin and Lees7), breast cancer(Reference Yamamoto, Sobue and Kobayashi8Reference Pietinen, Stumpf and Mannisto10), prostate cancer(Reference Hedelin, Klint and Chang11Reference Severson, Nomura and Grove13) and menopause-related symptoms(Reference Nagata, Takatsuka and Kawakami14Reference Murkies, Lombard and Strauss16), but not all(Reference Hedelin, Lof and Olsson17, Reference Stattin, Adlercreutz and Tenkanen18). A possible reason for this inconsistency is the measurement error of phyto-oestrogen intake based on FFQ(Reference Keinan-Boker, van Der Schouw and Grobbee19Reference dos Santos Silva, Mangtani and McCormack24). For instance, the long-term intake estimation of lignans based on FFQ might be subject to with-person random error due to the day-to-day fluctuation in dietary intake. In addition, systematic between-person errors might also have been produced due to the omission of lignan-containing food items in a standardised FFQ or the lack of a complete lignan composition database. Due to these measurement errors, the estimated level of lignan intake among study subjects might be inaccurate and therefore dilute the true association with disease(Reference Willett and Willett25). Four validation studies of dietary phyto-oestrogens have compared FFQ with relevant biomarkers(Reference Hedelin, Klint and Chang11, Reference Kilkkinen, Valsta and Virtamo26Reference Bhakta, dos Santos Silva and Higgins28). One Finnish study and one Swedish study of men indicated significant correlations (both r 0·19) when comparing the FFQ-based estimate with the serum concentration of enterolactone, the biomarker of lignan intake(Reference Hedelin, Klint and Chang11, Reference Kilkkinen, Valsta and Virtamo26). However, two English studies did not observe a correlation between dietary intake of lignan and serum concentration of enterolactone(Reference Bhakta, Higgins and Sevak27, Reference Bhakta, dos Santos Silva and Higgins28). The purpose of the present study was to assess the validity of two versions of FFQ, the FFQ-87 with a shorter and the FFQ-97 with a longer list of food items containing lignans, in the measurement of dietary intake of lignans, as compared to serum concentrations of enterolactone, among Swedish women.

Method

Study subjects and study design

The present validation study included women randomly drawn from the Swedish Mammography Cohort. The Swedish Mammography Cohort was established between 1987 and 1990. All 90 303 women born between 1914 and 1948 and residing in the Västmanland and Uppsala counties in central Sweden were invited by mail to participate in a population-based mammography-screening programme. Enclosed with this invitation was the FFQ-87 that elicited information on diet, weight, height and education. The participation rate was 74 %. In 1997, a more comprehensive dietary questionnaire, the FFQ-97, was sent to the 56 030 Swedish Mammography Cohort members who were residing in the study area, and 70 % of them returned the completed questionnaire. During 2003–4, 140 women aged 55–75 years were randomly selected from the cohort for the present validation study. None of them had used antibiotics in the past year. This exclusion was necessary as antibiotics are known to influence phyto-oestrogens' metabolism(Reference Adlercreutz, Fotsis and Bannwart29). All 140 participants answered the FFQ-87 and the FFQ-97 in 2003–2004, and fasting blood samples were collected within 3 months of completing these questionnaires. The information on history of gastrointestinal disease was obtained from the National Patient Register, while the diabetes data was collected from the combination of the National Patient Register, the National Diabetes Register and self-reported questionnaires. The study was approved by the Regional Ethics Committee at the Karolinska Institutet in Stockholm, Sweden.

Assessment of dietary phyto-oestrogen intake using FFQ

The FFQ-87 and the FFQ-97 included sixty-seven and ninety-three food items, respectively. In the FFQ-87, participants were asked to report their average frequency of consumption for each type of food or beverage using eight predefined frequency categories: ‘never/seldom’, ‘one to three times/month’, ‘one time/week’, ‘two to three times/week’, ‘four to six times/week’, ‘one time/d’, ‘two to three times/d’ or ‘four times/d’. In the FFQ-97, close-ended questions with similar response categories were set for most food items, but open-ended questions (open answers, not pre-specified categories) were designed for some commonly consumed foods including bread, milk, cheese, soft drinks, beer, coffee, tea and sugar. Energy content was obtained from the Swedish National Food Administration database(Reference Bergström, Kylberg and Hagman30). Total lignan intake was estimated using published content values of the six most prevalent dietary precursors of enterolactone: SEC, MAT, LAR, PIN, MED and SYR(Reference Adlercreutz and Mazur2, Reference Milder, Arts and van de Putte31Reference Mazur, Fotsis and Wahala37). Of the sixty-seven and ninety-three food items listed in the FFQ-87 and the FFQ-97, forty-five (69·2 %) and sixty-five (69·9 %) items were assigned lignan values, respectively. The remaining had no values assigned because the lignan content was assumed to be negligible. Nutrient intake was computed by multiplying the frequency of food items by the nutrient content of the age-specific servings. The estimations of total intake of lignans were adjusted for total energy intake, using the residual method(Reference Willett and Stampfer38). As the activity of the gut microflora influences the metabolism of dietary lignans to enterolactone(Reference Borriello, Setchell and Axelson4, Reference Setchell, Lawson and Borriello5, Reference Setchell, Adlercreutz and Rowland39), we also used a formula based on experimental results to calculate the expected amount of mammalian lignans, which had been converted from dietary lignans(Reference Heinonen, Nurmi and Liukkonen40):

$$\begin{eqnarray} Estimate\,of\,enterolactone = 0\cdot 62\times MAT + 0\cdot 72\times SEC + 1\cdot 01\times LAR + 0\cdot 55\times PIN + 0\cdot 04\times SYR + 0\cdot 8\times MED. \end{eqnarray}$$

Analysis of serum enterolactone

Blood samples were processed and separated for sera that were stored at − 80°C until analysis. Samples were shipped frozen to the Folkhälsan Institute for Preventive Medicine, Nutrition and Cancer (Helsinki, Finland), where they were thawed and subjected to overnight enzymatic hydrolysis and diethyl ether extraction. Sample extracts were then diluted in assay buffer, with europium label, internal standards and subsequently analysed by time-resolved fluoroimmunoassay according to previously reported protocols for assessment of enterolactone(Reference Wang, Lapcik and Hampl41Reference Stumpf, Uehara and Nurmi43). The intra- and inter-assay CV % of the time-resolved fluoroimmunoassay method was low (3·3–6·0 and 6·9–9·9 % for enterolactone, depending upon the serum concentrations)(Reference Wang, Lapcik and Hampl41Reference Stumpf, Uehara and Nurmi43). Serum isoflavone genistein was analysed using the same method, but only forty of the total 140 women had a detectable serum concentration within the range 0–48 (median 3) nmol/l, indicating low consumption of the isoflavone genistein in the Swedish diet. Therefore, genistein was not included in the final analysis.

Statistical analysis

Lignan values were not normally distributed; therefore, the log-transformed values of lignan intake and serum enterolactone were used in the Pearson's correlation analyses. A total of five observations outside the 95 % CI of the corresponding values were excluded, leaving 135 participants for final analysis. The following variables were considered as potential confounders, as they might influence the metabolism of dietary lignans: age (categorised into three groups: 55–61, 62–69 and >69 years), BMI ( ≤ 24·9, 25–29·9 and ≥ 30 kg/m2), constipation (yes or no), gastrointestinal disease history (yes or no) and diabetes (yes or no). The analyses were implemented in both crude and multivariable models. The basic model included adjustment for age only, while the full multivariable model included all variables listed earlier. The partial Pearson's correlation was used to calculate the adjusted correlation coefficients in the full model. Test of linear trend across BMI categories was conducted by assigning the median of BMI in each BMI category and then treating these values as a continuous variable in the model. As previous studies have indicated BMI as an important determinant of the serum enterolactone concentration(Reference Kilkkinen, Stumpf and Pietinen44), additional analyses stratified by BMI subgroups were also conducted. ANOVA and t tests were used to compare the mean values of serum concentration of enterolactone in the subgroups when appropriate. All statistical analyses were performed using SAS 9.0 (Statistical Analysis System, version 9.0; SAS Institute).

Results

Dietary intake of lignans and serum enterolactone

Among the 135 study participants aged 55–75 years, with a mean BMI of 26·7 kg/m2, the average energy-adjusted dietary intake of total lignans was 1616 (sd 424) μg/d according to the FFQ-87 and 1516 (sd 409) μg/d for the FFQ-97 (Table 1). The estimates of dietary lignan intake were different for the two FFQ (t= 3·2, P= 0·002). The average intake of lignans using the FFQ-97 in obese subjects (BMI ≥ 30 kg/m2) was 1634 (sd 589) μg/d and 1464 (sd 368) μg/d in normal-weight (BMI < 24·9 kg/m2) subjects (t= − 1·42, P= 0·16). The mean concentration of serum enterolactone was 23·2 (sd 15·4) nmol/l (Table 2). No statistically significant difference of serum enterolactone was observed among subgroups of BMI, age groups, constipation, diabetes and gastrointestinal disease history. Approximately 60 % of the daily intake of total lignans was derived from bread, while fruit and vegetable intake accounted for 25 % (Table 3). Lignan LAR (32·4 %) and PIN (33·3 %) were the main contributors of total lignan intake (data not shown).

Table 1 Dietary lignan intake among 135 Swedish women (Mean values and standard deviations; medians and ranges)

* FFQ-87: FFQ, 1987 version (forty-five food items containing lignans); FFQ-97: FFQ, 1997 version (sixty-five food items containing lignans).

Nutrient intakes are energy-adjusted via the residual method.

Five outliers (95 % CI) were excluded.

§ Two subjects had missing BMI values.

Expected amount of dietary lignans was converted to enterolactone in the intestine using conversion factors: matairesinol = 0·62, secoisolariciresinol = 0·72, lariciresinol = 1·01, pinoresinol = 0·55, syringaresinol = 0·44, pinoresinol = 0·55, syringaresinol = 0·04 and medioresinol = 0·8.

Table 2 Serum concentration of enterolactone by characteristics of study subjects (Mean values and standard deviations; medians and ranges)

* Five outliers (95 % CI) were excluded.

ANOVA was used to compare the mean values.

Two subjects had missing BMI values.

§ The t test was used to compare the mean values.

Table 3 Food sources for major contribution of dietary intake of lignans among 135 Swedish women

Correlation between dietary lignans and serum enterolactone

Pearson's correlation coefficients between lignan intake and serum concentration of enterolactone are presented in Table 4. Dietary lignans assessed by the FFQ-97 were statistically significantly correlated with serum enterolactone in the crude and multivariable-adjusted models (r 0·16, P= 0·06; r 0·22, P= 0·01, respectively), as well as when converted lignan values were used (r 0·17, P= 0·04; r 0·24, P= 0·006, respectively) (Table 4). However, no such correlation was found for the FFQ-87 with lignan intake (r 0·09, P= 0·30), nor with converted lignans (r 0·12, P= 0·19). The correlation between the two FFQ was statistically significant (r 0·59, P< 0·0001).

Table 4 Pearson's correlation between energy-adjust dietary intake of lignans based on the FFQ and serum concentration of enterolactone*

* All dietary intakes of lignans and serum enterolactone were log-transformed.

FFQ-87: FFQ, 1987 version (forty-five food items containing lignans); FFQ-97: FFQ, 1997 version (sixty-five food items containing lignans).

Adjusted for age, BMI ( < 25, 25–29·9, ≥ 30) kg/m2, constipation (yes/no), gastrointestinal disease history (yes/no) and diabetes (yes/no).

§ Five outliers (95 % CI) were excluded.

Expected amount of dietary lignans was converted to enterolactone in the intestine using conversion factors: matairesinol = 0·62, secoisolariciresinol = 0·72, lariciresinol = 1·01, pinoresinol = 0·55, syringaresinol = 0·44, pinoresinol = 0·55, syringaresinol = 0·04 and medioresinol = 0·8.

Pearson's correlations between intake of total lignans and of converted lignans and serum enterolactone in BMI subgroups are shown in Table 5. The highest correlation was observed in obese women (BMI ≥ 30 kg/m2). A borderline positive trend between increasing BMI and increasing correlation coefficients for lignans was indicated, but due to the limited sample size, chance errors cannot be ruled out.

Table 5 Pearson correlations between energy-adjusted dietary intake of lignans based on the FFQ and serum concentration of enterolactone stratified by BMI*

* All dietary intakes of lignans and serum enterolactone were log-transformed.

FFQ-87: FFQ, 1987 version (forty-five food items containing lignans); FFQ-97: FFQ, 1997 version (sixty-five food items containing lignans).

Expected amount of dietary lignans could be converted to enterolactone in the intestine.

§ Adjusted for age, constipation (yes/no), gastrointestinal disease history (yes/no) and diabetes (yes/no), when applicable.

Two subjects had missing BMI values.

Test for trend across BMI categories was conducted by assigning the median of BMI in each BMI category and then treating these values as a continuous variable.

Discussion

The present study shows that the validity of FFQ-based estimates of dietary lignan intake depends on the number of food items containing lignans in the FFQ, and potentially the BMI of the study subjects.

Limitations of the present study include the small sample size, although it was not smaller than that of other phyto-oestrogen validation studies(Reference Hedelin, Klint and Chang11, Reference Bhakta, dos Santos Silva and Higgins28, Reference Heald, Bolton-Smith and Ritchie45). A limitation of the serum enterolactone assessment was that only a single fasting blood sample was used. The high intra-individual variation with poor precision when using a single measurement might lead to misclassification of the enterolactone exposure(Reference Sonestedt and Wirfalt46). However, the concentration of serum enterolactone in the present study was in line with the concentrations observed in other Swedish studies(Reference Sonestedt, Ericson and Gullberg47, Reference Hulten, Winkvist and Lenner48). Among strengths were the adjustments for confounders, including diabetes and gastrointestinal diseases, that might interact with phyto-oestrogens' metabolism through enzymatic modification and gut microflora(Reference Barnes, Sfakianos and Coward49Reference Takaishi, Matsuki and Nakazawa51). Furthermore, none of the participants had used antibiotics during the previous 12 months, which might otherwise be a matter of concern(Reference Adlercreutz, Fotsis and Bannwart29). The use of antibiotics is known to reduce the amount of gut bacteria and subsequently serum concentrations of enterolactone(Reference Kilkkinen, Pietinen and Klaukka52). Additionally, the use of fasting blood samples was an advantage, as non-fasting samples might have lower reliability regarding enterolactone measurements(Reference Sonestedt and Wirfalt46, Reference Sonestedt, Ericson and Gullberg47, Reference Hausner, Johnsen and Hallund53). Another strength was the inclusion of four newly identified enterolactone precursors (LAR, PIN, SYR and MED) in the calculation of total dietary lignan intake, while most of the previous studies included only SEC and MAT for such calculations(Reference Kilkkinen, Valsta and Virtamo26Reference Bhakta, dos Santos Silva and Higgins28).

Few studies(Reference Hedelin, Klint and Chang11, Reference Kilkkinen, Valsta and Virtamo26Reference Bhakta, dos Santos Silva and Higgins28) have investigated the correlation between lignan intake estimates and serum enterolactone as a biomarker (Table 6). In a study of 140 women in England, the correlation between dietary intake measured by FFQ and serum enterolactone was low (r 0·10, P= 0·20)(Reference Bhakta, Higgins and Sevak27). However, a Finnish study showed better validity of 24 h recalls (r 0·19, P< 0·0001) in a large study population (n 1784), but they assessed only the precursors SEC and MAT to estimate lignan intake(Reference Kilkkinen, Valsta and Virtamo26). The only previous study that estimated total lignan intake based on all six precursors of plant lignans was performed in Swedish men, and showed a correlation of 0·19 (P= 0·09)(Reference Hedelin, Klint and Chang11). The correlation observed in the present study of the FFQ-97 (r 0·22, P= 0·01) was similar.

Table 6 Summary of papers investigating correlation between dietary intake of lignans and serum concentration of enterolactone

The reasons for the low correlation between lignan intake and serum enterolactone might be diverse. FFQ might overestimate the consumption of a number of food groups, particularly lignan intake from fruits and vegetables(Reference Willett and Stampfer38), and the FFQ were not designed specifically for lignan intake; thus, it was difficult to obtain full coverage of related food sources. On the other hand, concentration of enterolactone might vary substantially over the course of a single day, or different seasons. Furthermore, potentially large inter-individual variation in the metabolism of plant lignans into mammalian enterolactone cannot be ignored(Reference Rowland, Wiseman and Sanders54). Upon ingestion, plant lignans are transformed into their immediate precursor enterodiol and then to enterolactone by certain gut microflora(Reference Borriello, Setchell and Axelson4, Reference Setchell, Lawson and Borriello5, Reference Setchell, Adlercreutz and Rowland39). Therefore, lack of certain gut microflora can result in different enterodiol:enterolactone ratios. Moreover, persons regularly consuming certain lignan-rich foods, such as fruits, vegetables and fibre-rich foods have more efficient transformation of plant lignans into mammalian enterolactone(Reference Nurmi, Mursu and Penalvo55, Reference Hutchins, Lampe and Martini56). Smoking and high BMI might decrease the serum concentration of enterolactone, while constipation might enhance the production of enterolactone due to the decrease of intestinal motility(Reference Kilkkinen, Stumpf and Pietinen44, Reference Johnsen, Hausner and Olsen57).

To improve the assessment of phyto-oestrogens using FFQ, some modifications might be warranted. For example, some improvements might be needed to develop a lignan-specific questionnaire, in which important exposures such as age, education, height and weight (to calculate BMI) will also be included. Furthermore, several criteria should be considered when adopting a biomarker to calibrate dietary assessment, e.g. by obtaining serum samples at several time points. Although hampered by low statistical power, it was interesting that obese participants seemed to show a higher correlation between estimate of plant lignan intake and serum concentration of enterolactone. Speculatively, obese people might be more prone to recall healthy dietary habits, such as intake of fruits and vegetables, compared to non-obese people. The difference in assessment of dietary lignan intake using the FFQ-97 and the FFQ-87 might be due to the fact that the FFQ-97 (sixty-five food items containing lignans) evaluated more lignan-containing food items than the FFQ-87 (forty-five food items containing lignans), and the fact that some questions in the FFQ-97 were more precise than those in the FFQ-87. Participants were asked to report food intake frequency within eight categories ranging from ‘never/seldom’ to ‘four times/d’ in the FFQ-87, whereas they were asked about the precise frequency (open answers, not pre-specified categories) for commonly consumed food items, e.g. tea, in the FFQ-97. In fact, there were differences between the FFQ-87 and the FFQ-97 in terms of assessment of tea.

In summary, the present study indicates that the correlation between plant lignan intake based on assessment with the FFQ and serum concentration of enterolactone is limited, which can partly depend on varying metabolism of lignans. Therefore, interpretation of FFQ-based results regarding lignan exposure should be very cautious, and direct measurement of serum enterolactone should be recommended.

Acknowledgements

The present work was supported by research grants from the Swedish Cancer Foundation, the Swedish Research Council/Committee for Infrastructure and the Faculty Funds for Partial Financing of New Doctoral Students from Karolinska Institutet (12059012/KID-medel 2010). None of authors has conflicts of interest to disclose. The authors' contributions to the present study were as follows: A. W. designed the study; A. W. carried out the data collection; J. L. P. and H. A. performed the laboratory analysis; N. H., Y. L. and Y. L. performed the statistical analysis; and Y. L., Y. L., J. L., J. L. P., H. A. and A. W. wrote the manuscript.

References

1Adlercreutz, H, Bannwart, C, Wahala, K, et al. (1993) Inhibition of human aromatase by mammalian lignans and isoflavonoid phytoestrogens. J Steroid Biochem Mol Biol 44, 147153.CrossRefGoogle ScholarPubMed
2Adlercreutz, H & Mazur, W (1997) Phyto-oestrogens and Western diseases. Ann Med 29, 95120.Google Scholar
3Adlercreutz, H (2007) Lignans and human health. Crit Rev Clin Lab Sci 44, 483525.Google Scholar
4Borriello, SP, Setchell, KD, Axelson, M, et al. (1985) Production and metabolism of lignans by the human faecal flora. J Appl Bacteriol 58, 3743.Google Scholar
5Setchell, KD, Lawson, AM, Borriello, SP, et al. (1981) Lignan formation in man–microbial involvement and possible roles in relation to cancer. Lancet ii, 47.CrossRefGoogle Scholar
6Vanharanta, M, Voutilainen, S, Lakka, TA, et al. (1999) Risk of acute coronary events according to serum concentrations of enterolactone: a prospective population-based case–control study. Lancet 354, 21122115.Google Scholar
7Reynolds, K, Chin, A, Lees, KA, et al. (2006) A meta-analysis of the effect of soy protein supplementation on serum lipids. Am J Cardiol 98, 633640.Google Scholar
8Yamamoto, S, Sobue, T, Kobayashi, M, et al. (2003) Soy, isoflavones, and breast cancer risk in Japan. J Natl Cancer Inst 95, 906913.CrossRefGoogle ScholarPubMed
9Shu, XO, Jin, F, Dai, Q, et al. (2001) Soyfood intake during adolescence and subsequent risk of breast cancer among Chinese women. Cancer Epidemiol Biomarkers Prev 10, 483488.Google ScholarPubMed
10Pietinen, P, Stumpf, K, Mannisto, S, et al. (2001) Serum enterolactone and risk of breast cancer: a case–control study in eastern Finland. Cancer Epidemiol Biomarkers Prev 10, 339344.Google Scholar
11Hedelin, M, Klint, A, Chang, ET, et al. (2006) Dietary phytoestrogen, serum enterolactone and risk of prostate cancer: the Cancer Prostate Sweden Study (Sweden). Cancer Cause Control 17, 169180.Google Scholar
12Strom, SS, Yamamura, Y, Duphorne, CM, et al. (1999) Phytoestrogen intake and prostate cancer: a case–control study using a new database. Nutr Cancer J 33, 2025.CrossRefGoogle ScholarPubMed
13Severson, RK, Nomura, AM, Grove, JS, et al. (1989) A prospective study of demographics, diet, and prostate cancer among men of Japanese ancestry in Hawaii. Cancer Res 49, 18571860.Google Scholar
14Nagata, C, Takatsuka, N, Kawakami, N, et al. (2001) Soy product intake and hot flashes in Japanese women: results from a community-based prospective study. Am J Epidemiol 153, 790793.Google Scholar
15Albertazzi, P, Pansini, F, Bonaccorsi, G, et al. (1998) The effect of dietary soy supplementation on hot flushes. Obstet Gynecol 91, 611.Google Scholar
16Murkies, AL, Lombard, C, Strauss, BJ, et al. (1995) Dietary flour supplementation decreases post-menopausal hot flushes: effect of soy and wheat. Maturitas 21, 189195.Google Scholar
17Hedelin, M, Lof, M, Olsson, M, et al. (2008) Dietary phytoestrogens are not associated with risk of overall breast cancer but diets rich in coumestrol are inversely associated with risk of estrogen receptor and progesterone receptor negative breast tumors in Swedish women. J Nutr 138, 938945.CrossRefGoogle ScholarPubMed
18Stattin, P, Adlercreutz, H, Tenkanen, L, et al. (2002) Circulating enterolactone and prostate cancer risk: a Nordic nested case-control study. Int J Cancer 99, 124129.Google Scholar
19Keinan-Boker, L, van Der Schouw, YT, Grobbee, DE, et al. (2004) Dietary phytoestrogens and breast cancer risk. Am J Clin Nutr 79, 282288.Google Scholar
20Horn-Ross, PL, Hoggatt, KJ, West, DW, et al. (2002) Recent diet and breast cancer risk: the California Teachers Study (USA). Cancer Causes Control 13, 407415.Google Scholar
21Key, TJ, Sharp, GB, Appleby, PN, et al. (1999) Soya foods and breast cancer risk: a prospective study in Hiroshima and Nagasaki, Japan. Br J Cancer 81, 12481256.CrossRefGoogle Scholar
22Lee, HP, Gourley, L, Duffy, SW, et al. (1991) Dietary effects on breast-cancer risk in Singapore. Lancet 337, 11971200.Google Scholar
23den Tonkelaar, I, Keinan-Boker, L, Veer, PV, et al. (2001) Urinary phytoestrogens and postmenopausal breast cancer risk. Cancer Epidemiol Biomarkers Prev 10, 223228.Google Scholar
24dos Santos Silva, I, Mangtani, P, McCormack, V, et al. (2004) Phyto-oestrogen intake and breast cancer risk in South Asian women in England: findings from a population-based case–control study. Cancer Causes Control 15, 805818.Google Scholar
25Willett, WC (1998) Correction for the effects of measurement error. In Nutritional Epidemiology, chapter 2, pp. 302320 [Willett, WC, editor]. Oxford: University Press.Google Scholar
26Kilkkinen, A, Valsta, LM, Virtamo, J, et al. (2003) Intake of lignans is associated with serum enterolactone concentration in Finnish men and women. J Nutr 133, 18301833.Google Scholar
27Bhakta, D, Higgins, CD, Sevak, L, et al. (2006) Phyto-oestrogen intake and plasma concentrations in South Asian and native British women resident in England. Br J Nutr 95, 11501158.CrossRefGoogle ScholarPubMed
28Bhakta, D, dos Santos Silva, I, Higgins, C, et al. (2005) A semiquantitative food frequency questionnaire is a valid indicator of the usual intake of phytoestrogens by south Asian women in the UK relative to multiple 24-h dietary recalls and multiple plasma samples. J Nutr 135, 116123.Google Scholar
29Adlercreutz, H, Fotsis, T, Bannwart, C, et al. (1986) Determination of urinary lignans and phytoestrogen metabolites, potential antiestrogens and anticarcinogens, in urine of women on various habitual diets. J Steroid Biochem 25, 791797.Google Scholar
30Bergström, L, Kylberg, E, Hagman, U, et al. (1991) The food composition database KOST: the National Food Administration's information system for nutritive values of food. Vår Föda 43, 439447.Google Scholar
31Milder, IEJ, Arts, ICW, van de Putte, B, et al. (2005) Lignan contents of Dutch plant foods: a database including lariciresinol, pinoresinol, secoisolariciresinol and matairesinol. Br J Nutr 93, 393402.Google Scholar
32Valsta, LM, Kilkkinen, A, Mazur, W, et al. (2003) Phyto-oestrogen database of foods and average intake in Finland. Br J Nutr 89, S31S38.Google Scholar
33Mazur, W & Adlercreutz, H (1998) Natural and anthropogenic environmental oestrogens: the scientific basis for risk assessment. Naturally occurring oestrogens in food. Pure Appl Chem 70, 17591776.CrossRefGoogle Scholar
34Mazur, WM, Uehara, M, Wahala, K, et al. (2000) Phyto-oestrogen content of berries, and plasma concentrations and urinary excretion of enterolactone after a single strawberry-meal in human subjects. Br J Nutr 83, 381387.Google ScholarPubMed
35Mazur, WM, Duke, JA, Wahala, K, et al. (1998) Isoflavonoids and lignans in legumes: nutritional and health aspects in humans. J Nutr Biochem 9, 193200.Google Scholar
36Mazur, WM, Wahala, K, Rasku, S, et al. (1998) Lignan and isoflavonoid concentrations in tea and coffee. Br J Nutr 79, 3745.Google Scholar
37Mazur, W, Fotsis, T, Wahala, K, et al. (1996) Isotope dilution gas chromatographic–mass spectrometric method for the determination of isoflavonoids, coumestrol, and lignans in food samples. Anal Biochem 233, 169180.Google Scholar
38Willett, W & Stampfer, MJ (1986) Total energy intake: implications for epidemiologic analyses. Am J Epidemiol 124, 1727.Google Scholar
39Setchell, K & Adlercreutz, H (1998) Mammalian lignans and phytoestrogens: recent studies on their formation, metabolism and biological rols in health and disease. In The Role of Gut Microflora in Toxicity and Cancer, pp. 315345 [Rowland, IR, editor]. London: Academic Press.Google Scholar
40Heinonen, S, Nurmi, T, Liukkonen, K, et al. (2001) In vitro metabolism of plant lignans: new precursors of mammalian lignans enterolactone and enterodiol. J Agric Food Chem 49, 31783186.Google Scholar
41Wang, GJ, Lapcik, O, Hampl, R, et al. (2000) Time-resolved fluoroimmunoassay of plasma daidzein and genistein. Steroids 65, 339348.Google Scholar
42Adlercreutz, H, Wang, GJ, Lapcik, O, et al. (1998) Time-resolved fluoroimmunoassay for plasma enterolactone. Anal Biochem 265, 208215.CrossRefGoogle ScholarPubMed
43Stumpf, K, Uehara, M, Nurmi, T, et al. (2000) Changes in the time-resolved fluoroimmunoassay of plasma enterolactone. Anal Biochem 284, 153157.Google Scholar
44Kilkkinen, A, Stumpf, K, Pietinen, P, et al. (2001) Determinants of serum enterolactone concentration. Am J Clin Nutr 73, 10941100.Google Scholar
45Heald, CL, Bolton-Smith, C, Ritchie, MR, et al. (2006) Phyto-oestrogen intake in Scottish men: use of serum to validate a self-administered food-frequency questionnaire in older men. Eur J Clin Nutr 60, 129135.Google Scholar
46Sonestedt, E & Wirfalt, E (2010) Enterolactone and breast cancer: methodological issues may contribute to conflicting results in observational studies. Nutr Res 30, 667677.CrossRefGoogle ScholarPubMed
47Sonestedt, E, Ericson, U, Gullberg, B, et al. (2008) Variation in fasting and non-fasting serum enterolactone concentrations in women of the Malmo Diet and Cancer cohort. Eur J Clin Nutr 62, 10051009.Google Scholar
48Hulten, K, Winkvist, A, Lenner, P, et al. (2002) An incident case-referent study on plasma enterolactone and breast cancer risk. Eur J Nutr 41, 168176.CrossRefGoogle ScholarPubMed
49Barnes, S, Sfakianos, J, Coward, L, et al. (1996) Soy isoflavonoids and cancer prevention. Underlying biochemical and pharmacological issues. Adv Exp Med Biol 401, 87100.CrossRefGoogle ScholarPubMed
50Leiter, EH, Chapman, HD & Falany, CN (1991) Synergism of obesity genes with hepatic steroid sulfotransferases to mediate diabetes in mice. Diabetes 40, 13601363.Google Scholar
51Takaishi, H, Matsuki, T, Nakazawa, A, et al. (2008) Imbalance in intestinal microflora constitution could be involved in the pathogenesis of inflammatory bowel disease. Int J Med Microbiol 298, 463472.Google Scholar
52Kilkkinen, A, Pietinen, P, Klaukka, T, et al. (2002) Use of oral antimicrobials decreases serum enterolactone concentration. Am J Epidemiol 155, 472477.Google Scholar
53Hausner, H, Johnsen, NF, Hallund, J, et al. (2004) A single measurement is inadequate to estimate enterolactone levels in Danish postmenopausal women due to large intraindividual variation. J Nutr 134, 11971200.CrossRefGoogle ScholarPubMed
54Rowland, IR, Wiseman, H, Sanders, TA, et al. (2000) Interindividual variation in metabolism of soy isoflavones and lignans: influence of habitual diet on equol production by the gut microflora. Nutr Cancer 36, 2732.Google Scholar
55Nurmi, T, Mursu, J, Penalvo, JL, et al. (2010) Dietary intake and urinary excretion of lignans in Finnish men. Br J Nutr 103, 677685.Google Scholar
56Hutchins, AM, Lampe, JW, Martini, MC, et al. (1995) Vegetables, fruits, and legumes: effect on urinary isoflavonoid phytoestrogen and lignan excretion. J Am Diet Assoc 95, 769774.Google Scholar
57Johnsen, NF, Hausner, H, Olsen, A, et al. (2004) Intake of whole grains and vegetables determines the plasma enterolactone concentration of Danish women. J Nutr 134, 26912697.Google Scholar
Figure 0

Table 1 Dietary lignan intake among 135 Swedish women (Mean values and standard deviations; medians and ranges)

Figure 1

Table 2 Serum concentration of enterolactone by characteristics of study subjects (Mean values and standard deviations; medians and ranges)

Figure 2

Table 3 Food sources for major contribution of dietary intake of lignans among 135 Swedish women

Figure 3

Table 4 Pearson's correlation between energy-adjust dietary intake of lignans based on the FFQ and serum concentration of enterolactone*

Figure 4

Table 5 Pearson correlations between energy-adjusted dietary intake of lignans based on the FFQ and serum concentration of enterolactone stratified by BMI*

Figure 5

Table 6 Summary of papers investigating correlation between dietary intake of lignans and serum concentration of enterolactone