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Isoflavones in breastfed infants after mothers consume soy^1,2,3

¹ From the Cancer Research Center of Hawaii, Natural Products and Cancer Biology Program, Honolulu (AAF, LJC, YT, and SH), and the Kapi'olani Medical Center for Women and Children, Honolulu, HI (BHH)

² Supported by the Solae Company, including donation of soy protein beverages, and by the National Cancer Institute (CCSG CA71789).

³ Address reprint requests to AA Franke, Cancer Research Center of Hawaii, 1236 Lauhala Street, Honolulu, HI 96813. E-mail: adrian{at}crch.hawaii.edu.

	ABSTRACT

TOP ABSTRACT INTRODUCTION SUBJECTS AND METHODS RESULTS DISCUSSION REFERENCES

 
Background: The bioavailability of isoflavones in children after soy exposure is uncertain.

Objective: We aimed to compare isoflavone patterns in infants exposed to isoflavone-containing breast milk (BF), in tofu-fed (TF) infants, and in mothers consuming a soy beverage.

Design: Eighteen nursing mothers who were not feeding soy foods to their infants consumed one daily serving of a soy protein beverage for 2–4 d and collected their own milk and urine and infant urine. Plasma was collected from infants if venous blood draws were ordered by pediatricians. Blood and urine were collected from additional children after they consumed tofu. Isoflavones were measured by liquid chromatography–mass spectrometry.

Results: In 7 subjects, isoflavone values increased significantly from baseline after mothers ate soy: in maternal urine ( ± SEM) from 18.4 ± 13.0 to 135.1 ± 26.0 nmol/mg creatinine, in breast milk from 5.1 ± 2.2 to 70.7 ± 19.2 nmol/L, and in infant urine from 29.8 ± 11.6 to 111.6 ± 18.9 nmol/mg creatinine. The mean isoflavone concentration in plasma obtained from 11 BF infants was 19.7 ± 13.2 nmol/L. TF infants had much higher mean isoflavone values (urine, 229 ± 129 nmol/mg creatinine; plasma, 1049 ± 403 nmol/L). Statistically significant correlations were observed between the types of fluids investigated within mothers, between mothers and infants, and within infants. Urinary isoflavone excretion per hour adjusted for dose per body weight was 81% lower for BF infants and 24% higher for TF infants than for their mothers after eating soy.

Conclusions: More isoflavones appear in children than in adults after adjustment for isoflavone intake. Systemic isoflavone exposure in infants can be determined by urinary analysis.

Key Words: Isoflavones • soy foods • infants • breast milk • urine • biological markers • creatinine • plasma

	INTRODUCTION

TOP ABSTRACT INTRODUCTION SUBJECTS AND METHODS RESULTS DISCUSSION REFERENCES

 
Soy foods contain high concentrations of the isoflavones genistein, daidzein, and glycitein (0.01–0.3% as consumed) and account for most dietary isoflavone exposure (1), particularly in soy-consuming populations (1–4). Isoflavones are efficiently absorbed by adults after oral administration (5–10), and urinary or plasma isoflavones are used as reliable biomarkers of soy consumption in adults (11–18). According to numerous animal and human studies, isoflavones are suggested to protect against many chronic diseases, including breast, prostate, and colorectal cancer; osteoporosis; menopausal symptoms; and cardiovascular disorders (19–25). Isolated isoflavones as present in nutritional supplements are mostly ineffective (26, 27), except for improving endothelial function (28). Some studies find health benefits from soy foods that are low in or devoid of isoflavones (29, 30), whereas others find that isoflavones from soy alone or in combination with other soy components result in health benefits (27, 28, 31–34).

Although well researched in adults (6–8, 35), the bioavailability of isoflavones after soy exposure has been minimally investigated in infants and children (6–8). In one study, mean plasma isoflavone concentrations in seven 4-mo-old boys fed soy-based formula, cow milk–based formula, or human milk were 3.7, 20, and 16 µmol/L, respectively (36). Urinary isoflavone concentrations were reported to be lower in up to 4-mo-old boys than in adults when both were exposed to comparable isoflavone doses (37). Comparisons in isoflavone bioavailability between children or infants and their mothers in dietary intervention studies have so far not been performed. Details about the absorption, metabolism, and excretion of milk components in infants often remain uncertain, including the fate and quantitative pattern of dietary agents, even vitamins (38, 39). Thus far, no information is available about isoflavone concentrations in infants after they consume isoflavone-containing breast milk. We and others previously showed that lactating women secrete isoflavone into breast milk after soy intake (40, 41) and that this happens in a dose-dependent fashion (42).

We report here on isoflavone values in urine (IU) and plasma (IP) of infants who breastfed from soy-consuming mothers (BF) or who consumed tofu (TF) to find out whether isoflavones consumed by breastfed infants as glucuronate and sulfate conjugates appear in these infants differently than when consumed as ß-glucosides as present in soy foods. In addition, we compared these findings with the isoflavone patterns in urine and milk of the soy-consuming mothers (MU and MM, respectively).

	SUBJECTS AND METHODS

TOP ABSTRACT INTRODUCTION SUBJECTS AND METHODS RESULTS DISCUSSION REFERENCES

 
Subjects and study design
Breastfeeding mothers and their infants were recruited from the local children's hospital and through word of mouth. All were healthy and not allergic to soy foods. The eligibility criteria included breastfeeding 80% of the time, being able to follow the protocol, and not feeding soy-based infant formula at any time. The protocol required that mothers consume one daily serving (36.5 g) of a soy protein beverage (donated by the Solae Company, St Louis, MO) for 2–4 days. Participants were given the choice of an unsweetened soy protein beverage or one with aspartame. According to the manufacturer, both varieties contained 25 g soy protein, 0.5–1 g total fat, 0–5 g cholesterol, 150–240 mg sodium, 10–200 mg potassium, 5–6 g carbohydrates, and various vitamins and minerals and delivered 130 kcal. As shown in Table 1, each contained 55 mg isoflavones with the typical pattern (daidzein:genistein:glycitein = 1:1:0.1; mainly glucosides and malonyl glucosides) (43). After the soy beverage was consumed on the last day in the early morning, sample collection was performed that afternoon and was completed within 1–2 h. Mothers collected their milk and urine as well as the infant's urine. Infants were breastfed as usual. Baseline milk and urine samples were collected before the intervention. Blood was collected at that time only from those infants whose pediatrician ordered a diagnostic blood lead level test as recommended in some circumstances in the State of Hawaii. No separate blood draws from infants were performed solely for this study. The urine of the infants who donated blood was collected immediately after the blood draw by using a pediatric urine bag.

To compare the effects of isoflavone exposure via breast milk with that via solid foods, we collected blood and urine additionally from 3 infants (aged 9, 10, and 24 mo; 2 females, one male) 2 to 4 h after they consumed on average 44 g tofu (equivalent to 7.4 mg isoflavones) (43). No samples were collected from their mothers, and values from TF infants were included in the IP-IU comparisons.

The protocol of this dietary intervention study was approved by the Institutional Review Board of Kapiolani Medical Center for Women and Children/Honolulu and the University of Hawaii Committee on Human Subjects. All participants signed an informed consent form for themselves and their children before entry into the study.

Blood was collected in lithium-heparin–containing evacuated tubes, and urine was collected from infants in special sex-specific collection bags in 2 sizes depending on age (First-Time; Hollister Inc, Libertyville, IL). Sterile screw-cap containers were used to collect MM and MU. Immediately after collection, blood was transported at 5–8 °C in the dark to the laboratory via courier, followed by immediate processing and final storage of plasma at –20 °C. Urine and milk samples were allowed to be stored in refrigerators until transported to the laboratory on wet ice via courier. These samples were always kept at temperatures <8 °C until final storage at –20 °C, no later than 24 h after collection. These conditions were shown not to degrade any of the measured isoflavones (data not shown).

Specimen analysis
The soy protein beverage contained 55 mg isoflavones, composed of daidzein, genistein, glycitein, and their glycoconjugates as determined by HPLC with photodiode array detection (PDA) (5), as shown in Table 1. Daidzein, genistein, glycitein, equol, dihydrodaidzein, dihydrogenistein, and O-desmethylangolensin were analyzed from urine, plasma, and human milk by HPLC with PDA followed online by electrospray ionization (negative mode) ion trap mass spectrometry (ESI-MS) (44, 45). In brief, triply ¹³C-labeled internal standards of daidzein, genistein, equol, and O-desmethylangolensin (University of St Andrews, St Andrews, United Kingdom) were added to each specimen hydrolyzed with glucuronidase and sulfatase (Sigma Chemical Co, St Louis, MO, or Roche Applied Sciences, Indianapolis, IN) followed by repeated phase separation with diethyl ether (5). Milk was additionally defatted with hexane before this procedure (40). The combined ether fractions were dried under nitrogen and redissolved in a 1:1 mixture of acetonitrile–sodium acetate buffer (0.2 mol/L, pH 5). Five to 20 µL of this extract was analyzed by liquid chromatography/PDA/ESI-MS with an LCQ Surveyor-Advantage ion trap system (ThermoElectron Corp, San Jose, CA) equipped with a HydroBond PS C₁₈ (100 x 3.0 mm; 5 µm) reversed-phase column coupled to a HydroBond PS C₁₈ (25 x 3.2 mm; 5 µm) direct-connect guard column (MacMod Analytic Inc, Chadds Ford, PA). The elution, absorbance detection, and mass spectrometric measurements were performed as applied previously (34, 44, 46, 47). Limits of quantitation for all analytes using 0.3 mL plasma, 1.8 mL milk, or 1.2–1.8 mL urine were 2.5 nmol/L except for dihydrodaidzein and dihydrogenistein (1.5 nmol/L) and O-desmethylangolensin (5.0 nmol/L). Between-day CVs for plasma, milk, and urine ranged from 4% to 12% for daidzein, 5–18% for genistein, and 3–14% for glycitein. Isoflavone metabolites (equol, dihydrodaidzein, dihydrogenistein, and O-desmethylangolensin) were not considered here because of amounts at detection limits. Urinary creatinine was measured by using a Roche Cobas MiraPlus clinical autoanalyzer (Roche Diagnostics, Indianapolis, IN) with a kit from Randox Laboratories (Crumlin, United Kingdom) that is based on a kinetic modification of the Jaffe reaction.

Statistical procedures
Student's paired t test was applied to test the significance of differences in isoflavones before and after the soy intervention in MU, IU, and MM with the use of EXCEL software 1998 for Macintosh (Microsoft Inc, Redmond, WA). Fisher's z-transformation was used to test the statistical significance of the correlation coefficients by using EXCEL software 1998. This transformation allowed us to test any null hypothesis, ie, not just to test whether the true correlation was zero. It is more flexible and appropriate than the t test for correlation when the distribution of sample values of the correlation is skewed under the true correlation being nonzero. Means were calculated by using one data point per subject before or after the intervention.

	RESULTS

TOP ABSTRACT INTRODUCTION SUBJECTS AND METHODS RESULTS DISCUSSION REFERENCES

 
Sixteen mothers correctly complied with the protocol and collected at least one specimen (milk, urine, or plasma). Reasons for missing samples were lack of sufficient volume for analysis (MM, IU) or forgetting to collect (MU). One of the noncompliers forgot to consume the soy beverage; samples for that subject pair were used for baseline measurements only. No data from the other noncomplier were included in the analysis. Three mothers gave their infants soy-based infant formula; therefore, only the mothers' specimens could be included. Mean values were used from each individual when repeated collections were available.

Sixteen mothers correctly completed the collection of MU and MM, and 13 and 11 infant samples were collected for IU and IP, respectively. For specimen pair comparisons, 12 participants completed the protocol correctly for the donation of MM-IU pairs, 13 for MU-IU pairs, 14 for IP-IU pairs (11 BF, 3 TF), and 16 for MU-MM pairs (Table 2).

Figure 1

View larger version (13K): [in this window] [in a new window]   FIGURE 1.. Mean (±SEM) urinary isoflavone excretion rates and breast milk and plasma concentrations of isoflavones in mothers' urine (MU), mothers' milk (MM), infants’ urine (IU), and infants' plasma (IP). White bars represent the mean values from 7 participants before the mothers consumed soy, and black bars indicate the mean values from these 7 participants after the mothers consumed soy; the black bar for IP illustrates the mean value in 11 breastfed infants. The gray bars depict mean values in 3 tofu-fed infants. Cr, creatinine. *, **Significantly different from baseline: *P 0.005, **P 0.002 (paired two-tailed t test for 7 intervention-baseline pairs).

As shown in Figure 2, high correlations were observed between the types of fluids investigated and all were statistically significant according to a two-tailed z test whether within mothers (MM versus MU: r = 0.661), between mothers and infants (MM versus IU: r = 0.775; MU versus IU: r = 0.863), or within infants (IP versus IU: r = 0.975). Correlation coefficients and P values did not change considerably when applying median or logged values (data not shown).

View larger version (25K): [in this window] [in a new window]   FIGURE 2.. Correlations between types of specimens collected from mothers and their infants. The linear regression curve (r = Pearson correlation, P = significance by 2-tailed z test) was generated by using values of 7 participants at baseline (), data obtained from these subjects after the mothers consumed soy (), and values of 5–9 more participants who delivered samples exclusively after mothers consumed soy (•) (panels A-C). Infant plasma (IP)-urine (IU) pairs of breastfed () or tofu-fed () infants are shown in panel D. The linear regression is based on all data shown and was not altered significantly after removal of the 3 data pairs for the TF infants. The insert in panel D shows the values on a natural logarithmic scale. MM, mothers' milk; MU, mothers' urine.

Table 3

The daily creatinine excretion in urine can vary greatly between individuals but is mainly determined by sex, age, and body weight (49, 50). Under consideration of these factors, an accurate conversion of creatinine-based urinary excretion rates to hourly urinary excretion rates was performed by using established values for daily creatinine excretion per kg body wt, ie, 21.0, 10.2, and 11.8 mg in mothers (aged 28–36 y), BF infants at a mean age of 2 mo, and TF infants at a mean age of 15 mo, respectively (49–51). Our measured creatinine-based UIE values converted in this process to hourly UIE of 138, 0.08, and 113 nmol · h^–1 · kg^–1, respectively (Table 3). When these body weight–adjusted hourly UIE values were additionally adjusted to dose per kg body wt (UIE/dose; Table 3) they changed to 137, 26, and 169 (nmol

	DISCUSSION

TOP ABSTRACT INTRODUCTION SUBJECTS AND METHODS RESULTS DISCUSSION REFERENCES

 
We found low circulating concentrations and urinary excretion rates of isoflavones in breastfed infants of mothers who consumed usual servings of a soy protein drink despite the presence of these isoflavones as glucuronide and sulfate conjugates, which are easily hydrolyzed to bioavailable aglycons. This finding was probably due to the very low isoflavone dose but also to a lower ability of isoflavone uptake relative to adults when adjusted to dose. In contrast, TF infants showed high isoflavone amounts in plasma and urine, which exceeded those found in adults eating soy. This indicates that the isoflavone conjugation pattern alone does not determine isoflavone uptake capacities in children.

As expected, there was a significant increase in isoflavone amounts between baseline and the soy intervention in mothers (8-fold in MU and 14-fold in MM) but also in their BF children (4-fold in IU). When we included the 5 to 9 participants without baseline samples, the combined mean values after soy intervention were similar, and the differences were most likely due to the known interindividual variability in isoflavone uptake (35, 52). Isoflavone values in TF infants' plasma and urine were on average 53-fold and >1200 times the values in BF infants, respectively. Concentrations of this magnitude in children were previously thought to exist only in soy formula–fed infants, who are exposed to very high isoflavone doses (6–8 mg/kg body wt) (36, 42). Plasma isoflavone concentrations in adults were found to peak at 1.5 µmol/L after 27 mg isoflavone (6) or 10–50 nmol/L per mg isoflavone consumed (reviewed in reference 10), with less efficient uptake at greater doses (53). Our findings in TF infants were much higher, 135 nmol · L^–1 · mg^–1, and may have even been greater because our collections might not have coincided with peak plasma isoflavone concentrations. These findings suggest a higher isoflavone exposure in children than in adults, particularly when considering that children eat more per kg body wt. This might shed a different light on isoflavone effects. High soy consumption in some Asian countries may lead to high systemic isoflavone exposures in Asian children. The low breast and prostate cancer risk in these populations (reviewed in references 54 and 55) may be due to high systemic isoflavone exposure. Phytoestrogens may act as selective estrogen receptor modulators, which, like steroidal estrogens, have been found to have preventive effects on breast cancer during early periods in life through the up-regulation of tumor suppressors, increases in breast cell differentiation, and other mechanisms (56–58). This hypothesis agrees with epidemiologic findings of reduced breast cancer risk later in life when soy is consumed during early ages (59, 60).

We observed high correlations in isoflavone concentrations between the types of fluids investigated. These statistically significant r values indicate that isoflavones 1) are secreted into milk at similar rates as they are excreted into urine in lactating women, 2) are taken up from breastfeeding infants in a linear dose-dependent manner, and 3) appear in BF infants to a similar extent in plasma as they do in urine. The latter finding agrees with recent reports in adults after consideration of accurate timing for sample collections and of different plasma:urine ratios for each individual isoflavonoid (6, 14, 18, 61). Our findings in children are noteworthy, because urinary isoflavone analysis can serve as a surrogate for measuring systemic isoflavone exposure, which avoids invasive blood draws that are particularly difficult to obtain from healthy minors. Similarly, isoflavones in the urine or milk of mothers are good surrogates for their infants' isoflavone exposure. Consequently, mothers' specimens might be sufficient for obtaining reliable estimates of isoflavone exposure in BF infants.

When urinary excretion is expressed by adjusting for urinary creatinine concentrations, it is important to consider that the latter depends mostly on muscle mass and, consequently, largely on body weight, sex, and age (49, 50). This is particularly relevant when comparing children and adults (50), not only because of marked changes in muscle mass in the growing child in absolute terms but also after adjustment for body weight (50, 62–64). We converted measured UIE, which was adjusted for creatinine concentrations, into UIE adjusted for time (hour) by applying established correction factors that take into account body weight, sex, and age (50). Urinary excretion rates adjusted solely for creatinine underestimate true excretion in heavier individuals—for example, in males versus females or in older children versus younger children—and lead to erroneous results (51). The lack of conversion to time-based urinary excretion rates might explain the lower UIE in older than in younger soy-exposed children reported by others (65) or the loss of differences in urinary sex steroid excretion in females of different reproductive ages (66). When we converted UIE to time-based values and additionally adjusted for dose per kg body wt, the UIE/dose ratio changed in infants by a factor of 2, whereas that in adults changed little. The low isoflavone values in BF infants were unexpected because it was hypothesized that the isoflavone glucuronides and sulfates as present in breast milk (40, 41) are more bioavailable to the infant than the beta glucoside conjugates present in soy food (6, 43) because of the intrinsic enzymatic capacity to hydrolyze the former, whereas the latter conjugates require mainly intestinal bacteria for hydrolysis (6). Our hypothesis was based on the fact that ß-glucuronidase is present in humans in many biological fluids and in almost all tissues, with especially high activity in liver, kidney, spleen, endocrine and reproductive organs, and the intestinal epithelium (67–69; for review, see reference 70).

The low isoflavone values in urine and plasma of BF infants, even after consideration of the low dose, could be due to the impaired ability of the nonmatured gut flora to cleave glucuronide and sulfate conjugates for the production of the aglycons required for isoflavone uptake. However, the constant exposure to isoflavone in infants breastfed by mothers regularly consuming soy will result in more uniform systemic concentrations, and bioavailability as measured by area under the curve might be higher than single isoflavone plasma concentrations indicate. Nevertheless, although detectable isoflavone concentrations were measured, the urine and plasma values in infants exposed to isoflavone-containing breast milk were low but might still be in the pharmacologically relevant range. Conversely, the higher isoflavone bioavailability after soy intake in weaning infants relative to adults could be due to the maturing gut flora that has attained the ability to hydrolyze beta glucosides efficiently (6) for the production of aglycons but has not yet developed fully to degrade unconjugated isoflavones (71). This would result in an overall higher survival of ready-for-uptake isoflavone aglycons in the gut (52). Despite similar isoflavone doses per kg body wt through adjustment of soy doses, we found higher creatinine-based UIE in 8–14-y-old girls than in adults (72), and this difference was little changed after conversion to hourly UIE (G Maskarinec, unpublished observations, 2005). This agrees with the present findings and supports our hypothesis of higher isoflavone bioavailability in children than in adults. Collection of the entire urine amount in a timed fashion bypasses the need for conversion of creatinine-based UIE; although 24-h (or longer) urine collections result in very precise data, a protocol of this nature is often difficult or impossible to perform in human studies for various reasons. A good compromise is the collection of overnight urine, which resulted in very high compliance previously (2, 73) and which is particularly recommended for research in children once bladder control is achieved.

Weaknesses of this study are the small sample size and the lack of control over infants' sample collections. In addition, all specimens were collected in a 1–2-h time period in the afternoon after the mothers had consumed their soy dose in the morning. This time frame could lead to major differences in isoflavone appearance in plasma, urine, or breast milk as a result of the fast isoflavone pharmacokinetics (7–9, 40). Correlations between the various types of fluids analyzed could probably be improved with a more uniform and defined schedule for soy consumption, breastfeeding, and sample collections. With this in place, changes in uptake in infants as a function of age could be evaluated. Despite the relatively small number of samples in this study, we obtained robust results considering the insignificant change in all correlation coefficients and P values when applying median or logged values. To our knowledge, this is the first report on isoflavone values in urine and plasma of infants who were breastfed by soy-consuming mothers or who ate tofu. It adds critical information to the previous animal and recent epidemiologic studies showing beneficial effects of soy exposure by elucidating isoflavone appearance in humans at an early age. The current study shows that, independent of relative bioavailability, isoflavone exposure in soy-consuming populations is probably higher in children than in adults, particularly as a result of larger intake when adjusted for body weight.

	ACKNOWLEDGMENTS

 
We are indebted to the diligent participation of the mothers and their infants and thank them genuinely for their time and efforts. We are very grateful to Bibiana Potter for assistance in participant recruitment. Gertraud Maskarinec, Lynne Wilkens, and Leo Chung, Cancer Research Center of Hawaii (CRCH), are acknowledged for their assistance in statistical evaluation and discussions of the data. We thank Leslie Ashburn, CRCH, for manuscript preparations.

LJC performed the chemical analyses. YT and SH were the study coordinators. SH also assisted in manuscript preparations. BMH assisted in study design, recruited the study participants, performed sample collections, and was available for medical advice. She also assisted in matters related to the institutional review board and in data interpretations. AAF, the principal investigator of this project, was responsible for all parts of the study, designed and directed the study, performed data interpretation, and prepared the manuscript. None of the authors had a conflict of interest.

	REFERENCES

TOP ABSTRACT INTRODUCTION SUBJECTS AND METHODS RESULTS DISCUSSION REFERENCES

 

1. Umphress ST, Murphy SP, Franke AA, Custer LJ, Blitz CL. Isoflavone content of foods with soy additives. J Food Comp Anal 2005; 18: 533–50.
2. Franke AA, Custer LJ, Cerna CM, Narala K. Rapid HPLC analysis of dietary phytoestrogens from legumes and from human urine. Proc Soc Exp Biol Med 1995; 208: 18–26.[Abstract]
3. Adlercreutz H, Mazur W. Phyto-estrogens and Western diseases. Ann Med 1997; 29: 95–120.[Medline]
4. Horn-Ross PL, Lee M, John EM, Koo J. Sources of phytoestrogen exposure among non-Asian women in California, USA. Cancer Causes Control 2000; 11: 299–302.[Medline]
5. Franke AA, Custer LJ, Wang W, Shi SJ. HPLC analysis of isoflavonoids and other phenolic agents from foods and from human fluids. Proc Soc Exp Biol Med 1998; 217: 263–73.[Abstract]
6. Franke AA, Custer LJ, Hundahl SA. Determinants for urinary and plasma isoflavones in humans after soy intake. Nutr Cancer 2004; 50: 141–54.[Medline]
7. Setchell KD, Brown NM, Desai PB, et al. Bioavailability, disposition, and dose-response effects of soy isoflavones when consumed by healthy women at physiologically typical dietary intakes. J Nutr 2003; 133: 1027–35.[Abstract/Free Full Text]
8. Zubik L, Meydani M. Bioavailability of soybean isoflavones from aglycone and glucoside forms in American women. Am J Clin Nutr 2003; 77: 1459–65.[Abstract/Free Full Text]
9. Richelle M, Pridmore-Merten S, Bodenstab S, Enslen M, Offord EA. Hydrolysis of isoflavone glycosides to aglycones by beta-glycosidase does not alter plasma and urine isoflavone pharmacokinetics in postmenopausal women. J Nutr 2002; 132: 2587–92.[Abstract/Free Full Text]
10. Hollman PCH. Absorption, bioavailability, and metabolism of flavonoids. Pharm Biol 2004; 42: 74–83.
11. Seow A, Shi C-Y, Franke AA, Hankin J, Lee H-P, Yu MC. Isoflavonoid levels in spot urine are associated with frequency of dietary soy intake in a population-based sample of middle-aged and older Chinese in Singapore. Cancer Epidemiol Biomarkers Prev 1998; 7: 135–40.[Abstract]
12. Chen Z, Zheng W, Custer LJ, et al. Usual dietary consumption of soy foods and its correlation with the excretion rate of isoflavonoid in overnight urine samples among Chinese women in Shanghai. Nutr Cancer 1999; 33: 82–9.[Medline]
13. Atkinson C, Skor HE, Fitzgibbons ED, et al. Overnight urinary isoflavone excretion in a population of women living in the United States, and its relationship to isoflavone intake. Cancer Epidemiol Biomarkers Prev 2002; 11: 253–60.[Abstract/Free Full Text]
14. Grace PB, Taylor JI, Low YL, et al. Phytoestrogen concentrations in serum and spot urine as biomarkers for dietary phytoestrogen intake and their relation to breast cancer risk in European Prospective Investigation of Cancer and Nutrition-Norfolk. Cancer Epidemiol Biomarkers Prev 2004; 13: 698–708.[Abstract/Free Full Text]
15. Wu AH, Yu MC, Tseng CC, Twaddle NC, Doerge DR. Plasma isoflavone levels versus self-reported soy isoflavone levels in Asian-American women in Los Angeles County. Carcinogenesis 2004; 25: 77–81.[Abstract/Free Full Text]
16. Fanti P, Stephenson TJ, Kaariainen IM, et al. Serum isoflavones and soya food intake in Japanese, Thai and American end-stage renal disease patients on chronic haemodialysis. Nephrol Dial Transplant 2003; 18: 1862–8.[Abstract/Free Full Text]
17. Wiseman H, Casey K, Bowey EA, et al. Influence of 10 wk of soy consumption on plasma concentrations and excretion of isoflavonoids and on gut microflora metabolism in healthy adults. Am J Clin Nutr 2004; 80: 692–9.[Abstract/Free Full Text]
18. Ritchie MR, Morton MS, Deighton N, Blake A, Cummings JH. Plasma and urinary phyto-oestrogens as biomarkers of intake: validation by duplicate diet analysis. Br J Nutr 2004; 91: 447–57.[Medline]
19. Messina M, Persky V, Setchell KDR, Barnes S. Soy intake and cancer risk: a review of in vitro and in vivo data. Nutr Cancer 1994; 21: 113–31.[Medline]
20. Barnes S, Grubbs C, Setchell KDR, Carlson J. Soybeans inhibit mammary tumors in models of breast cancer. In: Pariza W, Aeschbacher U, Felton JS, Sato S, eds. Mutagens and carcinogens in the diet. New York, NY: Wiley-Liss, 1990: 239–54.
21. Lamartiniere CA, Moore J, Holland M, Barnes S. Neonatal genistein chemoprevents mammary cancer. Proc Soc Exp Biol Med 1995; 208: 120–3.[Abstract]
22. Murrill WB, Brown NM, Zhang J-X, Manzolillo PA, Barnes S, Lamartiniere CA. Prepubertal genistein exposure suppresses mammary cancer and enhances gland differentiation in rats. Carcinogen 1996; 17: 1451–7.[Abstract/Free Full Text]
23. Pollard M, Luckert PH. Influence of isoflavones in soy protein isolates on development of induced prostate-related cancers in L-W rats. Nutr Cancer 1997; 28: 41–5.[Medline]
24. Zhang J-X, Hallmans G, Landstrom M, et al. Soy and rye diets inhibit the development of Dunning R3327 prostatic adenocarcinoma in rats. Cancer Lett 1997; 114: 313–4.[Medline]
25. Uckun FM, Evans WE, Forsyth CJ, et al. Biotherapy of B-cell precursor leukemia by targeting genistein to CD19- associated tyrosine kinases. Science 1995; 267: 886–91.[Abstract/Free Full Text]
26. Sirtori CR. Risks and benefits of soy phytoestrogens in cardiovascular diseases, cancer, climacteric symptoms and osteoporosis. Drug Saf 2001; 24: 665–82.[Medline]
27. Yeung J, Yu TF. Effects of isoflavones (soy phyto-estrogens) on serum lipids: a meta-analysis of randomized controlled trials. Nutr J 2003; 2: 15.[Medline]
28. Hall WL, Rimbach G, Williams CM. Isoflavones and endothelial function. Nutr Res Rev 2005; 18: 130–44.
29. Lu LJ, Anderson KE, Grady JJ, Nagamani M. Effects of an isoflavone-free soy diet on ovarian hormones in premenopausal women. J Clin Endocrinol Metab 2001; 86: 3045–52.[Abstract/Free Full Text]
30. Sirtori CR, Lovati MR, Manzoni C, et al. Proteins of white lupin seed, a naturally isoflavone-poor legume, reduce cholesterolemia in rats and increase LDL receptor activity in HepG2 cells. J Nutr 2004; 134: 18–23.[Abstract/Free Full Text]
31. Gardner CD, Newell KA, Cherin R, Haskell WL. The effect of soy protein with or without isoflavones relative to milk protein on plasma lipids in hypercholesterolemic postmenopausal women. Am J Clin Nutr 2001; 73: 728–35.[Abstract/Free Full Text]
32. Dillingham BL, McVeigh BL, Lampe JW, Duncan AM. Soy protein isolates of varying isoflavone content exert minor effects on serum reproductive hormones in healthy young men. J Nutr 2005; 135: 584–91.[Abstract/Free Full Text]
33. Potter SM, Baum JA, Teng H, Stillman RJ, Shay NF, Erdman JW, Jr. Soy protein and isoflavones: their effects on blood lipids and bone density in postmenopausal women. Am J Clin Nutr 1998; 68(suppl): 1375S–9S.[Abstract]
34. Cline JM, Franke AA, Register TC, Golden DL, Adams MR. Effects of dietary isoflavone aglycones on the reproductive tract of male and female mice. Toxicol Pathol 2004; 32: 91–9.[Abstract/Free Full Text]
35. Franke AA, Custer LJ. High-performance liquid chromatography assay of isoflavonoids and coumestrol from human urine. J Chromatogr B 1994; 662: 47–60.[Medline]
36. Setchell KDR, Zimmer-Nechemias L, Cai J, Heubi JE. Exposure of infants to phyto-oestrogens from soy-based infant formula. Lancet 1997; 350: 23–7.[Medline]
37. Cruz MLA, Wong WW, Mimouni F, et al. Effects of infant nutrition on cholesterol synthesis rates. Pediatr Res 1994; 35: 135–40.[Medline]
38. Committee on Drugs. Transfer of drugs and other chemicals into human milk. Pediatrics 2001; 108: 776–89.[Abstract/Free Full Text]
39. Saga K, Terao T. [Studies on transfer of vitamin K into human breast milk]. Nippon Sanka Fujinka Gakkai Zasshi 1989; 41: 1713–9 (in Japanese).[Medline]
40. Franke AA, Custer LJ. Daidzein and genistein concentration in human milk after soy consumption. Clin Chem 1996; 42: 955–64.[Abstract/Free Full Text]
41. Setchell KD, Zimmer-Nechemias L, Cai J, Heubi JE. Isoflavone content of infant formulas and the metabolic fate of these phytoestrogens in early life. Am J Clin Nutr 1998; 68(suppl): 1453S–61S.[Abstract]
42. Franke AA, Custer LJ, Tanaka Y. Isoflavones in human breast milk and other biological fluids. Am J Clin Nutr 1998; 68(suppl): 1466S–73S.[Abstract]
43. Franke AA, Hankin JH, Yu MC, Maskarinec G, Low SH, Custer LJ. Isoflavone levels in soy foods consumed by multiethnic populations in Singapore and Hawaii. J Agric Food Chem 1999; 47: 977–86.[Medline]
44. Franke AA, Custer LJ, Wilkens LR, et al. Liquid chromatographic analysis of dietary phytoestrogens from human urine and blood. J Chromatogr B 2002; 777: 43–57.
45. Blair RM, Appt SE, Franke AA, Clarkson TB. Treatment with antibiotics reduces plasma equol concentration in cynomolgus monkeys (Macaca fascicularis). J Nutr 2003; 133: 2262–7.[Abstract/Free Full Text]
46. Dai Q, Franke AA, Jin F, et al. Urinary excretion of phytoestrogens and risk of breast cancer among Chinese women in Shanghai. Cancer Epidemiol Biomarkers Prev 2002; 11: 815–21.[Abstract/Free Full Text]
47. Adams MR, Golden DL, Franke AA, Potter SM, Smith HS, Anthony MS. Dietary soy beta-conglycinin (7S globulin) inhibits atherosclerosis in mice. J Nutr 2004; 134: 511–6.[Abstract/Free Full Text]
48. Vaughan VC III, Litt IF. Growth and development. In: Behrman RE, ed. Nelson textbook of pediatrics. Philadelphia: WB Saunders, 1992: 6.
49. Fomon SJ. Nutrition of normal infants. St Louis, MO: Mosby, 1993.
50. Remer T, Neubert A, Maser-Gluth C. Anthropometry-based reference values for 24-h urinary creatinine excretion during growth and their use in endocrine and nutritional research. Am J Clin Nutr 2002; 75: 561–9.[Abstract/Free Full Text]
51. Knudsen N, Christiansen E, Brandt-Christensen M, Nygaard B, Perrild H. Age- and sex-adjusted iodine/creatinine ratio. A new standard in epidemiological surveys? Evaluation of three different estimates of iodine excretion based on casual urine samples and comparison to 24 h values. Eur J Clin Nutr 2000; 54: 361–3.
52. Zheng Y, Lee SO, Verbruggen MA, Murphy PA, Hendrich S. The apparent absorptions of isoflavone glucosides and aglucons are similar in women and are increased by rapid gut transit time and low fecal isoflavone degradation. J Nutr 2004; 134: 2534–9.[Abstract/Free Full Text]
53. Setchell KDR, Faughnan MS, Avades T, et al. Comparing the pharmacokinetics of daidzein and genistein with the use of ¹³C-labeled tracers in premenopausal women. Am J Clin Nutr 2003; 77: 411–9.[Abstract/Free Full Text]
54. Yan L, Spitznagel E. A meta-analysis of soyfoods and risk of breast cancer in women. Int J Cancer Prev 2004; 1: 281–93.
55. Yan L, Spitznagel EL. Meta-analysis of soy food and risk of prostate cancer in men. Int J Cancer 2005; 117: 667–9.[Medline]
56. Hilakivi-Clarke L. Estrogens, BRCA1, and breast cancer. Cancer Res 2000; 60: 4993–5001.[Abstract/Free Full Text]
57. Lamartiniere CA, Cotroneo MS, Fritz WA, Wang J, Mentor-Marcel R, Elgavish A. Genistein chemoprevention: timing and mechanisms of action in murine mammary and prostate. J Nutr 2002; 132: 552S–8S.[Abstract/Free Full Text]
58. Cabanes A, Wang M, Olivo S, et al. Prepubertal estradiol and genistein exposures up-regulate BRCA1 mRNA and reduce mammary tumorigenesis. Carcinogenesis 2004; 25: 741–8.[Abstract/Free Full Text]
59. Shu XO, Jin F, Dai Q, et al. Soyfood intake during adolescence and subsequent risk of breast cancer among Chinese women. Cancer Epidemiol Biomarkers Prev 2001; 10: 483–8.[Abstract/Free Full Text]
60. Wu AH, Wan P, Hankin J, Tseng CC, Yu MC, Pike MC. Adolescent and adult soy intake and risk of breast cancer in Asian-Americans. Carcinogenesis 2002; 23: 1491–6.[Abstract/Free Full Text]
61. Nettleton JA, Greany KA, Thomas W, Wangen KE, Adlercreutz H, Kurzer MS. Plasma phytoestrogens are not altered by probiotic consumption in postmenopausal women with and without a history of breast cancer. J Nutr 2004; 134: 1998–2003.[Abstract/Free Full Text]
62. Kesteloot H, Joossens JV. On the determinants of the creatinine clearance: a population study. J Hum Hypertens 1996; 10: 245–9.[Medline]
63. Barr DB, Wilder LC, Caudill SP, Gonzalez AJ, Needham LL, Pirkle JL. Urinary creatinine concentrations in the U.S. population: implications for urinary biologic monitoring measurements. Environ Health Perspect 2005; 113: 192–200.[Medline]
64. Kampmann J, Siersbaek-Nielsen K, Kristensen M, Hansen JM. Rapid evaluation of creatinine clearance. Acta Med Scand 1974; 196: 517–20.[Medline]
65. Hoey L, Rowland IR, Lloyd AS, Clarke DB, Wiseman H. Influence of soya-based infant formula consumption on isoflavone and gut microflora metabolite concentrations in urine and on faecal microflora composition and metabolic activity in infants and children. Br J Nutr 2004; 91: 607–16.[Medline]
66. Hall Moran V, Leathard HL, Coley J. Urinary hormone levels during the natural menstrual cycle: the effect of age. J Endocrinol 2001; 170: 157–64.[Abstract]
67. Anlyan AJ, Starr A. Beta-glucuronidase activity of spinal and ventricular fluids in humans. Cancer 1952; 5: 578–80.[Medline]
68. Lampe JW, Li SS, Potter JD, King IB. Serum beta-glucuronidase activity is inversely associated with plant-food intakes in humans. J Nutr 2002; 132: 1341–4.[Abstract/Free Full Text]
69. Pippin DJ, Swafford JR, McCunniff MD. Morphology of azurophil lysosomes in polymorphonuclear leukocytes from humans with rapidly progressive periodontitis. J Periodontal Res 2000; 35: 26–32.[Medline]
70. Kroemer HK, Klotz U. Glucuronidation of drugs. A re-evaluation of the pharmacological significance of the conjugates and modulating factors. Clin Pharmacokinet 1992; 23: 292–310.
71. Hooper LV, Midtvedt T, Gordon JI. How host-microbial interactions shape the nutrient environment of the mammalian intestine. Annu Rev Nutr 2002; 22: 283–307.[Medline]
72. Maskarinec G, Oshiro C, Morimoto Y, Hebshi S, Novotny R, Franke AA. Urinary isoflavone excretion as a compliance measure in a soy intervention among young girls: a pilot study. Eur J Clin Nutr 2005; 59: 369–75.
73. Maskarinec G, Singh S, Meng L, Franke AA. Dietary soy intake and urinary isoflavone excretion among women from a multiethnic population. Cancer Epidemiol Biomarkers Prev 1998; 7: 613–9.[Abstract]

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