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Review

Soy Consumption and the Risk of Prostate Cancer: An Updated Systematic Review and Meta-Analysis

1
Division of Nutritional Sciences, University of Illinois at Urbana-Champaign, Urbana, IL 61801, USA
2
Department of Food Science and Human Nutrition, University of Illinois at Urbana-Champaign, Urbana, IL 61801, USA
*
Author to whom correspondence should be addressed.
Nutrients 2018, 10(1), 40; https://doi.org/10.3390/nu10010040
Submission received: 29 November 2017 / Revised: 23 December 2017 / Accepted: 28 December 2017 / Published: 4 January 2018
(This article belongs to the Special Issue Natural Products for Cancer Prevention and Therapy)

Abstract

:
Prostate cancer (PCa) is the second most commonly diagnosed cancer in men, accounting for 15% of all cancers in men worldwide. Asian populations consume soy foods as part of a regular diet, which may contribute to the lower PCa incidence observed in these countries. This meta-analysis provides a comprehensive updated analysis that builds on previously published meta-analyses, demonstrating that soy foods and their isoflavones (genistein and daidzein) are associated with a lower risk of prostate carcinogenesis. Thirty articles were included for analysis of the potential impacts of soy food intake, isoflavone intake, and circulating isoflavone levels, on both primary and advanced PCa. Total soy food (p < 0.001), genistein (p = 0.008), daidzein (p = 0.018), and unfermented soy food (p < 0.001) intakes were significantly associated with a reduced risk of PCa. Fermented soy food intake, total isoflavone intake, and circulating isoflavones were not associated with PCa risk. Neither soy food intake nor circulating isoflavones were associated with advanced PCa risk, although very few studies currently exist to examine potential associations. Combined, this evidence from observational studies shows a statistically significant association between soy consumption and decreased PCa risk. Further studies are required to support soy consumption as a prophylactic dietary approach to reduce PCa carcinogenesis.

1. Introduction

Prostate cancer (PCa) is the second most commonly diagnosed cancer in men worldwide. According to the International Agency for Research on Cancer’s GLOBOCAN database, 1.1 million men were diagnosed with PCa in 2012, accounting for 15% of all cancers in men [1]. Incidence rates are lowest in Asian countries, where soy foods are regularly consumed as part of a normal diet. Several studies have reviewed the inverse association seen between soy food intake and PCa incidence in Asian populations, proposing that soy isoflavones act as weak hormones to exert a protective physiological effect against the development of PCa [2,3,4,5]. Indeed, the soy isoflavones, genistein and daidzein, have been shown to accumulate in prostatic tissue [6], where they may be cytotoxic to cancer cells [7]. These effects may occur as a result of both non-hormonal and hormonal action. For example, genistein upregulates tumor suppressor genes in PCa cells [8] and suppresses prostate carcinogenesis in an estrogen receptor (ER) wild-type mouse model, when compared to ER knock-out mouse models [9].
This hypothesis has further been supported by four previous meta-analyses of epidemiological studies, all of which showed a protective association between soy consumption and PCa [10,11,12,13]. However, these meta-analyses did not integrate and evaluate all available existing studies pertaining to both dietary soy food intake and circulating levels of isoflavones. Our current analysis broadens the included categories of soy food and isoflavone measurements, allowing for a more complete review of the literature. We include a larger number of studies and an in-depth analysis on the relationship between total soy food intake, fermented and unfermented soy food intakes, individual and combined dietary isoflavones, and circulating individual and combined isoflavones and the risk of PCa. Furthermore, no previous meta-analysis has explored potential links between soy foods and advanced PCa. Because soy isoflavones have also been linked to inhibiting PCa cell motility and invasion [14] and reducing inflammatory markers in men with PCa [15], we also evaluated the impact of soy on the risk of advanced PCa.

2. Materials and Methods

2.1. Study Selection Criteria

This meta-analysis was conducted following PRISMA and Meta-analysis of Observational Studies in Epidemiology (MOOSE) guidelines [16,17]. Studies fitting the following criteria were included in this meta-analysis: (a) examined the relationship between soy and PCa risk by using randomized control trials and/or cohort, cross-sectional, retrospective, prospective and case-control studies; (b) methodology was reported in replicable detail; (c) examined the association between soy and PCa risk; (d) reported relative risk ratios with 95% confidence intervals for the reported exposure categories; (e) were written in English; and (f) were peer-reviewed publications.

2.2. Literature Search

We conducted a thorough literature search of PubMed, Web of Science, and the Cochrane Library, using a combination of the following key words and their variants: prostate cancer, prostate neoplasm, soy, soymilk, soy milk, isoflavone, bean curd, tofu, soy protein, daidzein and genistein (up to 25 May 2017). The keyword search yielded a comprehensive list of titles and abstracts of articles that were screened for relevance against the listed study selection criteria. These screened articles were evaluated in full text for study inclusion. Finally, we conducted a reference list search (i.e., backward search) and works cited search (i.e., forward search) from the articles identified as meeting the inclusion criteria. The studies identified through this process were further assessed using the same inclusion criteria, with this process being repeated until all relevant articles were identified. Three authors (CA, JR3 and KR) individually considered all articles obtained in full text for inclusion or exclusion, and any discrepancies were discussed and resolved.

2.3. Data Extraction and Quality Assessment

The following information was extricated from each article: name of first author; year of publication; location of study; study period; number of cases, controls and total number of participants in the study; age of participants; total years of follow-up; exposure values of soy (serum/plasma and/or intake); relative risk ratios for PCa; adjustments made for any covariates; and study type. The term RR (relative risk) will be used in this study as a general term to denote the following: relative odds (cumulative incidence data), rate ratio (incidence-rate data) and odds ratios (OR; case-control data). Study quality was examined using the Newcastle–Ottawa Scale, which is a validated scale used to assess the quality for case-control and non-randomized cohorts in a meta-analysis [18]. This scale evaluates each study based on the following three categories: selection of cases and controls, comparability of studies, and exposure of the main variable (soy, genistein, daidzein, or total isoflavones). We regarded scores of 1–3, 4–6 and 7–9 as low, medium and high quality, respectively. The resulting quality score was included as a measurement of the strength of the evidence presented in each study and was not used to determine the inclusion or exclusion of studies. The significance of the study quality was analyzed in the subgroup analysis.

2.4. Statistical Analysis

STATA/IC version 14.2 (StataCorp LP, College Station, TX, USA) was used to analyze the data. Because OR is nearly equivalent to RR when considering low incidence of diseases [19], RR and 95% confidence intervals (CI) were used as a measure of the effect size for all included studies. Heterogeneity amongst studies was determined using the I2 statistic [20]. Fixed and random (DerSimonian–Laird) effects models were used, depending on the I2 result, as markers of study heterogeneity [20]. An I2 value of less than 50% (I2 < 50%) signified low-to-moderate heterogeneity between studies, so a fixed effect model was used to determine RR estimates. An I2 value of greater than or equal to 50% (I2 ≥ 50%) signified moderate-to-substantial heterogeneity between studies, so a random effects model was used to determine RR estimates. When results from fixed and random effects models were conflicting and studies showed moderate heterogeneity (I2 = 30–60%), we presented the latter as it represents a more conservative approach [21,22].
Because studies reported different exposure categories as tertiles, quartiles or quintiles, we used the study specific RR for the highest quantile of dietary soy intake and/or circulating (serum or plasma) isoflavone concentrations. Potential publication bias was assessed by using funnel plots [23,24], Egger’s linear regression test [25], and Begg’s rank correlation test of asymmetry [26]. We also performed sensitivity analyses to evaluate whether the pooled results could have been affected by excluding a single study at a time. Subgroup analyses were performed on study type, study location, study quality, and individual covariate adjustment. A p-value of less than 0.05 was considered statistically significant for all analyses.

3. Results

3.1. Literature Search

In total, 3356 articles were identified from the library search engines. After removing duplicates and adding articles identified from reference lists, 2531 articles remained. Of the 2531 articles that were screened by abstract, 39 articles were found to contain potentially relevant information and were evaluated by full text review. Upon reviewing the full text articles for the aforementioned inclusion criteria, 30 articles were included in the final analysis [27,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53,54,55,56]. Of these 30 articles, 24 [27,28,29,30,31,32,33,34,36,37,38,39,40,41,42,43,45,46,47,48,49,52,53,55] included information regarding dietary soy intake and nine [29,35,40,42,44,50,51,54,56] included information regarding circulating isoflavone levels (Figure 1).

3.2. Study Characteristics

Of the 30 articles included for analysis, fifteen [28,29,30,32,34,37,38,39,41,42,47,48,49,52,56] articles were case-control studies, eight [27,31,33,36,43,45,46,53] articles were cohort studies, and seven [35,40,44,50,51,54,55] articles were nested case-control studies (NCC). The total number of study participants included was 266,699, and the total number of PCa cases reported was 21,612. Twelve [27,32,35,36,37,39,41,42,44,47,49,56] articles reported data from Asia, ten [31,33,34,38,43,45,46,48,52,53] articles reported data from North America, and eight [28,29,30,40,50,51,54,55] articles reported data from Europe. The study characteristics are summarized in Table 1. Articles analyzing soy intake from the diet used lifestyle questionnaires or validated food frequency questionnaires (FFQs) to collect usual dietary intake. All articles reported results using risk estimates as RR or OR.
Quality scores were assigned to each article using the criteria outlined by the Newcastle–Ottawa scales for case-control and cohort studies. The average score for case-control studies was 6.93 (standard deviation = 0.7); 6 was the lowest score and 8 was the highest score given. Cohort and NCC studies received an average score of 7.73 (standard deviation = 0.7); 6 was the lowest score and 9 was the highest score given. Individual quality assessment scores are provided in Appendix A (Table A1).

3.3. Soy Intake and PCa Risk

Twenty-four articles evaluated dietary soy and soy isoflavone intake and PCa risk. These articles were further divided into groups that analyzed risk pertaining to total soy (n = 16) [27,29,31,32,33,34,36,37,39,41,43,45,46,47,49,52], unfermented soy food (n = 11) [27,31,33,34,37,39,43,46,47,49,52], fermented soy food (n = 8) [27,32,36,37,41,45,46,47], genistein (n = 10) [30,36,37,38,40,41,42,45,48,55], daidzein (n = 10) [30,36,37,38,40,41,42,45,48,55], total isoflavones (n = 6) [28,29,30,45,53,55], tofu (n = 5) [27,37,43,46,47], miso (n = 3) [27,36,46], soy milk (n = 2) [31,49], and natto (n = 1) [47] intakes. Funnel plots used to explore publication bias are shown in Appendix A (Figure A1).
Articles that reported soy intake as either a combination of multiple soy food items or as a single soy food item were classified as total soy intake. Sixteen articles reported the association between total soy intake and PCa risk. The pooled RR for this association was 0.71 (95% CI: 0.58–0.85, p < 0.001) (Figure 2A). Neither Begg’s correlation test (p = 0.300) nor Egger’s linear regression test (p = 0.052) for bias were significant. Heterogeneity amongst studies was analyzed using the I2 index to show high variation between studies (68.9%).
When selecting articles for evaluating the association between unfermented or fermented soy food intake and PCa risk, studies had to have explicitly stated which soy food items were being reported. Examples of commonly reported unfermented soy foods included soy milk, tofu and soybeans; fermented soy foods included miso and natto. The pooled RR for unfermented soy foods and risk of PCa was 0.65 (95% CI: 0.56–0.83, p < 0.001), and the pooled RR for fermented soy foods and risk of PCa was 0.86 (95% CI: 0.66–1.13, p = 0.218) (Figure 2B,C, respectively). Neither Begg’s correlation test (p = 0.161 and p = 0.902, respectively) nor Egger’s linear regression test (p = 0.117 and p = 0.670, respectively) for bias were significant. The I2 index showed high heterogeneity amongst studies included in the unfermented (60.3%) and fermented (66.6%) groups.
Ten articles reported soy intake as a measurement based on the calculation of genistein and daidzein present in soy foods. The pooled RR for genistein and risk of PCa was 0.90 (95% CI: 0.84–0.97, p = 0.008), and the pooled RR for daidzein and risk of PCa was 0.84 (95% CI: 0.73–0.97, p = 0.018) (Figure 2D,E, respectively). Begg’s correlation test was significant for genistein but was not significant for daidzein (p = 0.049 and p = 0.210, respectively), and Egger’s linear regression test was significant for both measurements (p = 0.009 and p = 0.039, respectively). The I2 index showed moderate heterogeneity between studies included in the genistein (31.0%) and daidzein (50.5%) groups.
Six articles reported isoflavone intake without disclosing the sources of the isoflavones. These studies were analyzed separately, so as not to interfere with measurements based solely on soy intake because isoflavones are found in other food items, such as seed sprouts and pulses. The pooled RR for isoflavone intake and PCa risk was 1.03 (95% CI: 0.97–1.09, p = 0.313) (Figure 2F). Neither Begg’s correlation test (p = 0.707) nor Egger’s linear regression test (p = 0.802) for bias were significant. The I2 index showed moderate heterogeneity between studies (44.9%). Notably, the inclusion of these studies in the total soy analysis did not significantly change the RR of dietary soy intake and PCa risk.
Finally, articles were further stratified into specific soy food groups, which included tofu, miso and soy milk. Few studies were available to accurately represent meta-analysis data on these points, so RR are reported here, but not included in further subgroup analyses. The pooled RR for tofu and PCa risk was 0.73 (95% CI: 0.57–0.94, p = 0.013), the pooled RR for miso and PCa risk was 1.01 (95% CI: 0.80–1.28, p = 0.919), and the pooled RR for soy milk and PCa risk was 0.58 (95% CI: 0.19–1.78, p = 0.343). None of the groups were significant for bias using Begg’s correlation test (p = 0.221, p = 0.296, and p = 1.000, respectively) or Egger’s linear regression test (p = 0.093, p = 0.497, and p = NA, respectively). The I2 index showed low heterogeneity amongst the studies included in the tofu (4.5%) and miso (0.0%) groups and high heterogeneity amongst studies included in the soy milk (63.1%) group.

3.4. Circulating Isoflavones and PCa Risk

Nine articles measured circulating isoflavone concentrations and their associations with PCa risk. Specifically, these articles reported RR data for circulating genistein (n = 9) [29,35,40,42,44,50,51,54,56], circulating daidzein (n = 7) [29,35,40,42,44,51,54], and total circulating isoflavones (n = 2) [29,54]. The pooled RR for circulating genistein and PCa risk was 0.87 (95% CI: 0.69–1.10, p = 0.236) (Figure 3A), the pooled RR for circulating daidzein and PCa risk was 0.92 (95% CI: 0.78–1.08) (Figure 3B), and the RR for circulating isoflavones and PCa risk was 1.01 (95% CI: 0.93–1.10, p = 0.738). None of the studies were significant for bias using Begg’s correlation test (p = 0.175, p = 0.368, and p = 1.00, respectively) or Egger’s linear regression test (p = 0.228, p = 0.197, and p = NA, respectively). The I2 index showed high heterogeneity amongst the studies included in the circulating genistein (76.8%) and circulating daidzein (58.1%) groups and low heterogeneity amongst the circulating isoflavone group (0.0%). Funnel plots used to explore publication bias are shown in Appendix A (Figure A2).

3.5. Subgroup Analysis

Articles reporting total soy intake and PCa risk had a pooled RR of 0.61 (95% CI: 0.45–0.82, p = 0.001) for case-control studies and a pooled RR of 0.90 (95% CI: 0.82–0.99, p = 0.022) for cohort and NCC studies. Studies conducted in both North America (p = 0.009) and Europe (p = 0.021) were significantly associated with a reduced PCa risk, whereas studies conducted in Asia (p = 0.064) were not. A complete subgroup analysis can be found in Table 2. Cumulative meta-analyses first demonstrated that soy food intake was significantly associated with the reduced risk of PCa in 1998 and has remained significant over time, and with the inclusion of additional studies within the field (Figure A3).
Articles reporting unfermented soy food intake and PCa risk had a pooled RR of 0.55 (95% CI: 0.46–0.66, p < 0.001) for case-control studies and a pooled RR of 0.91 (95% CI: 0.76–1.08, p = 0.267) for cohort studies. Studies were conducted in both North America (p = 0.014) and Asia (p = 0.005), and there was a significantly reduced risk of PCa in both continents. Studies of medium quality were significantly associated with a lower PCa risk (p < 0.001).
The pooled RR for articles reporting dietary genistein intake and PCa risk was 0.81 (95% CI: 0.68–0.96, p = 0.016) for case-control studies and a pooled RR of 0.93 (95% CI: 0.85–1.01, p = 0.077) for cohort and NCC studies. Studies conducted in Asia (p = 0.004) showed a significantly reduced risk of PCa, while studies conducted in North America (p = 0.145) and Europe (p = 0.419) did not. Mid quality studies were significantly associated with a reduced risk of PCa (p = 0.007).
The pooled RR for articles reporting dietary daidzein intake and PCa risk was 0.68 (95% CI: 0.47–1.00, p = 0.052) for case-control studies and a pooled RR of 0.91 (95% CI: 0.84–1.00, p = 0.042) for cohort and NCC studies. Studies conducted in Asia (p = 0.012) showed a significantly reduced risk of PCa, while studies conducted in North America (p = 0.094) and Europe (p = 0.799) did not. High quality studies were significantly associated with a reduced risk of PCa (p = 0.042).
There was no significant association for case-control or NCC studies and risk of PCa for articles evaluating circulating levels of genistein. Only studies conducted in Asia (p = 0.031) were significantly associated with a decreased risk of PCa, while studies conducted in Europe (p = 0.784) showed no significant association with circulating genistein levels and PCa risk.
Articles evaluating dietary isoflavones, fermented soy intake, and circulating levels of daidzein showed no significant associations on risk of PCa when studies were grouped by design or by continent. Finally, no studies significantly affected any of the pooled RRs when conducting sensitivity analyses for each group.

3.6. Soy and Advanced PCa Risk

Seven [34,35,36,43,45,50,53] studies reported the risk of advanced PCa with soy intake and circulating isoflavone levels. Of these seven studies, four [34,43,45,53] studies were conducted in North America, two [35,36] studies were conducted in Asia, and one [50] study was conducted in Europe. Only one [34] was a case-control study, two [35,50] were NCC studies, and four [36,43,45,53] were cohort studies. Five [34,36,43,45,53] studies reported a risk of advanced PCa with dietary soy food intake and two [35,50] studies reported a risk of advanced PCa with circulating isoflavones. For studies that reported dietary soy food intake, the pooled RR was 0.87 (95% CI: 0.74–1.06, p = 0.119) (Figure 4A). Neither Begg’s correlation test (p = 1.00) nor Egger’s linear regression test (p = 0.548) for bias were significant. The I2 index showed moderate heterogeneity between studies (45.7%). Funnel plots, used to explore publication bias, are shown in Appendix A (Figure A4).
When stratifying groups by combining dietary and circulating measurements of isoflavones, the pooled RR for genistein and PCa risk (n = 4) was 0.92 (95% CI: 0.77–1.11, p = 0.381), the pooled RR for daidzein and PCa risk (n = 3) was 0.89 (95% CI: 0.74–1.10, p = 0.227), and the pooled RR for total isoflavones and PCa risk (n = 2) was 0.91 (95% CI: 0.82–1.01, p = 0.337) (Figure 4B). The I2 index showed moderate heterogeneity amongst studies reporting genistein and daidzein dietary and circulating levels (33.7% and 30.7%, respectively), while there was substantially high heterogeneity between the studies reporting total isoflavone measurements (100.0%).

4. Discussion

This updated systematic review and meta-analysis provides a thorough evaluation regarding the association between soy food intake and PCa risk. Using the current pool of scientific literature, our results support the existing evidence, which indicates that total soy food intake is associated with a reduced risk of PCa (p < 0.001). This population-based evidence corroborates observations in both in vitro and in vivo studies, which have shown that soy isoflavones inhibit PCa development and growth [57,58,59]. In agreement with this, we found that both genistein and daidzein intake were inversely associated with the risk of PCa (p = 0.008 and p = 0.018, respectively). These results support our finding that total soy food consumption is associated with decreased PCa risk, as genistein and daidzein are likely found in similar food products.
Soybeans and soy food products contain isoflavones—predominantly genistein and daidzein—mainly as β-glycosides [60]. During digestion, these glycosides are hydrolyzed to their aglycone forms by intestinal or bacterial β-glucosidases [60]. By removing the sugar molecule, the isoflavones are smaller and more hydrophobic, allowing them to more readily diffuse into enterocytes [61]. After absorption and first pass metabolism, aglycones are re-conjugated in the liver to their glycosidic or other conjugated forms and distributed to tissues via systemic circulation [61]. Once within cells, isoflavones act as weak estrogen receptor (ER) agonists or antagonists, depending on the cell type and concentration of estrogen present [61]. Prostatic tissues have higher concentrations of ER-β, to which genistein preferentially binds, with an affinity similar to that of the endogenously-produced estrogen, 17β-estradiol [62]. Increased presence and activation of ER-β is associated with reduced cell proliferation and reduced PCa histological grade [63,64]. This effect has been shown to occur, in part, by reducing the levels of prostate-specific antigen (PSA), cyclin D1, and cyclin-dependent kinase 4 (CDK4) in an ER-dependent manner [57,58]. Interestingly, ER-β expression is often lost during prostate carcinogenesis, so the ability of genistein to bind to ER-β may be a key factor in the inhibition of prostate carcinogenesis. Additional mechanisms of the effects of soy isoflavones on PCa cellular proliferation, apoptosis, and differentiation have been reviewed in depth by Mahmoud et al. (2014) [65].
We also analyzed the potential relationship between unfermented or fermented soy food products and risk of PCa. We found that unfermented soy food products were associated with a decreased risk of PCa (p < 0.001), while fermented soy food products had no associations with PCa risk (p = 0.281). More studies provided food intake data for unfermented soy food products than fermented soy food products (11 studies versus 8 studies, respectively). While this meta-analysis failed to demonstrate a significant association between fermented foods and the risk of PCa, it should be recognized that there was wider variation in results reported by these studies than there was for studies using unfermented and other soy foods. This wider variation could have impacted the risk outcomes. Some concerns have been expressed in the literature regarding the effects of soy fermentation on the risk of developing certain cancers, such as gastric cancer [66]. Due to this association, Yan and Spitznagel chose to not include fermented soy foods in their 2005 meta-analysis [10]. However, during fermentation, β-glucosidases, secreted by fermentative bacteria, cleave glycosidic linkages via a similar process that digestive enzymes in the small intestine and gut microbiota cleave these linkages [60,61,67]. Isoflavones are present in fermented foods, such as tempeh and miso, predominantly as aglycones, with few isoflavones retaining their side-chains. The ratio is reversed for nonfermented foods, but some naturally occurring plant β-glucosidase activity allows for continuous side-chain cleavage to yield aglycones [60]. The more bioavailable aglycone form is readily absorbed from the intestines, rendering this conversion from a glycosylated isoflavone to its aglycone counterpart essential for maximal isoflavone absorption. These similar enzymatic processes yield common aglycone products for intestinal absorption, regardless of whether these processes occur before digestion during the fermentation of soy foods or during the digestion of unfermented soy foods.
Circulating levels of genistein and daidzein were not associated with the risk of PCa (p = 0.236 and p = 0.310, respectively) despite the elevation of circulating genistein and daidzein levels after consumption of these isoflavones. However, peak circulating isoflavone levels can occur as soon as 30 min or as long as 6 h after feeding, depending on the specific isoflavones and foods consumed [61,68]. Mean half-life values vary as well; the average half-life for free genistein is 3.2 h and the average half-life for free daidzein is 4.2 h [69]. Because isoflavones can exist with multiple side-chains (e.g., glucose, sulfate, acetyl, or malonyl-CoA groups) and as different metabolites, accurately measuring in vivo pharmacokinetics is challenging. Thus, the amount of time between isoflavone consumption and blood collection may substantially affect measurement outcomes, which can impact the reliability of blood isoflavone measurements as markers of soy food intake. Due to these factors, an association may have been missed for these circulating isoflavones.
No association was seen when we examined six articles that did not disclose the source of isoflavones measured from participants’ dietary intakes. For example, Bosetti et al. (2006) indicated that isoflavones were measured from the FFQ, primarily based on consumption of soy and soy products, but also from “vegetable or bean soups and pulses” [28]. Because isoflavones are found in other food sources and supplements, such as clover and alfalfa seeds and sprouts, garbanzo beans, and other pulses, we independently analyzed studies that did not explicitly indicate that measurements were taken from soy food sources. As such, total dietary isoflavones were not significantly associated with risk of PCa (p = 0.313). While most dietary isoflavones are consumed from soy food products, examining the sources and types of isoflavones that were included in these analyses could provide insight as to why no association was observed. Notably, this analysis was based on the information found from a limited number of articles, so additional studies could strengthen these observations.
To our knowledge, this is the first meta-analysis to investigate the risk associations between soy and advanced PCa. Advanced PCa is defined as poorly differentiated, aggressive, and metastatic disease. Advanced PCa is often difficult to treat, as patients are typically less responsive to therapy. It is therefore imperative to identify other ways to prevent disease progression, such as through dietary modification. Relatively few studies have examined the relationship between diet and advanced PCa or reported information pertaining to stage or grade of PCa. Our results do not show a significant reduction in the risk of advanced PCa with total soy intake (p = 0.119) or dietary and circulating levels of genistein (p = 0.381), daidzein (p = 0.227), or total isoflavones (p = 0.337), perhaps due to the lack of studies. Two double-blinded, randomized, placebo-controlled clinical trials have supplemented isoflavones in men awaiting radical prostatectomy. One study reported higher apoptotic activity in tumors of men treated with isoflavones when compared to tumors of the men in the placebo group [70], while the other study showed modulation of both cell cycle and apoptotic genes in the prostate tissues of men in the treatment group, when compared to tissues of men in the placebo group [71]. More studies are needed to further explore this promising relationship and to identify whether soy can protect against advanced PCa.
Few studies have analyzed individual soy foods and their relationships with PCa risk. Tofu was the most investigated soy food found in the literature. Tofu showed a significant protective association with PCa (p = 0.013). This result is consistent with the result shown by Hwang et al. (2009) [11]. More studies are needed to understand the role of individual soy foods in PCa risk.
The research design of studies did not seem to bias our results, as case-control and cohort studies both reported significant and null results. It is important to note that case-control studies are generally considered to have a higher risk of bias than cohort studies; however, significant measurement error can occur for both cohort and case-control studies when evaluating a single exposure variable. To accurately account for all reported estimates of soy exposure and PCa risk, both study designs were included in the analysis. To this end, sensitivity analyses conducted for each subgroup showed that no studies significantly altered results or heterogeneity within subgroups. Separating results by continent showed that total soy intake was only associated with a decreased risk of PCa in North America (p = 0.009) and Europe (p = 0.021), although only one study was included in the European group. However, when looking at the individual dietary isoflavones, genistein and daidzein, Asia was the only continent to show a significant risk reduction for PCa (p = 0.004 and p = 0.012, respectively). Similarly, Asia was the only continent to show a significant association between circulating genistein and risk of PCa (p = 0.031). Both North America (p = 0.014) and Asia (p = 0.005) showed a reduced risk of PCa when only considering unfermented soy foods. The variability in these associations makes it difficult to draw conclusions about whether ethnic differences, preparation methods, or eating patterns exist in soy food or isoflavone consumption and PCa risk.
Because differences in overall dietary composition or other unmeasured lifestyle factors could contribute to increased or decreased disease risk, the results from this study and others showing that soy intake is associated with a reduced risk of PCa should be interpreted with caution. Our study was limited in that our results relied on the reporting of the studies included in this analysis and may have been affected by several factors. For example, studies relying on dietary recall or FFQ reporting are subject to recall bias by participants. Soy food intake measurements could be inconsistently reported or nutrient analyses may differ based on the amount and type of soy food or the database used to collect nutrient information. In addition, not all studies accounted for potential confounding variables, such as family history of prostate cancer (FHPC), body mass index (BMI), smoking, or energy intake. The subgroup analyses in this study attempted to account for these limitations by highlighting some of these differences between studies, to account for variability in data adjustments and selection bias created by study design (i.e., whether the study was case-control or NCC/cohort).
In addition to attempting to address these study limitations, our analysis delved deeper into potential confounding factors, through meta-regression, to determine whether study quality, length, or the sample size impacted significant results of the study. None of these factors were found to impact our results, and as such were not included in our results. We also reported both dietary intakes and circulating levels of isoflavones to create a more comprehensive review of the existing literature. Finally, we analyzed any associations between soy and advanced PCa, which has not previously been reported.
As the second most commonly diagnosed cancer in men worldwide, it is important to identify modifiable factors, such as diet, that may impact the risk of developing PCa. The current study provides an updated systematic review and meta-analysis of the available literature describing the associations between soy food consumption and PCa risk. Of the four meta-analyses previously published, all showed that soy intake was associated with a reduced risk for PCa. Our study further enhances this association by including additional studies for analysis, grouping soy foods by type of food and by isoflavone intake, adding groups of circulating isoflavone concentrations, and by evaluating the potential relationship between soy food intake and advanced PCa risk.

Author Contributions

C.C.A., J.L.R., J.W.E. designed the study, C.C.A., J.L.R., K.M.R., S.J. conducted the research, C.C.A., J.L.R., K.M.R., J.W.E. analyzed the data, C.C.A. wrote the manuscript. All authors edited and approved the manuscript.

Conflicts of Interest

The authors declare no conflict of interest.

Appendix A

Table A1. Quality assessment of included studies.
Table A1. Quality assessment of included studies.
SourceSelectionComparability 5ExposureTotal 9
Author, YearDefinition 1Representative 2Selection 3 Definition 4Ascertainment 6Method 7Rate 8
Allen, 2004 [27]006
Bosetti, 2006 [28]0★★07
Heald, 2007 [29]★★08
Hedelin, 2006 [30]006
Jacobsen, 1998 [31]07
Jian, 2004 [32]0★★07
Kirsh, 2007 [33]0★★8
Kolonel, 2000 [34]07
Kurahashi, 2007 [36]07
Kurahashi, 2008 [35]8
Lee, 2003 [37]07
Lewis, 2009 [38]0★★07
Li, 2008 [39]07
Low, 2006 [40]★★9
Nagata, 2007 [41]006
Nagata, 2016 [42]07
Nomura, 2004 [43]07
Ozasa, 2004 [44]8
Park, 2008 [45]0★★8
Severson, 1989 [46]8
Sonoda, 2004 [47]006
Strom, 1999 [48]0★★07
Sung, 1999 [49]006
Travis, 2009 [51]8
Travis, 2012 [50]8
Villenueve, 1999 [52]★★08
Wang, 2014 [53]0★★8
Ward, 2008 [54]8
Ward, 2010 [55]0★★8
Wu, 2015 [56]0★★8
1 Indicates that cases are independently validated for case-control studies (0, 1 star); 2 cases are from a representative population or drawn from the same community as the non-exposed cohort (0, 1); 3 community controls or structured interview for cohort studies (0, 1); 4 controls have no history of prostate cancer (endpoint) (0, 1); 5 study controls for most important factor (age) and family history of prostate cancer (0, 1, 2); 6 structured interview where blind to case/control status for case-control studies, record linkage or independent blind assessment for cohort studies (0, 1); 7 same method of ascertainment for cases and controls or follow-up was long enough for outcomes to occur (4 years) (0, 1); 8 same non-response rate or <20% lost to follow up (0, 1); 9 total: minimum equals 1; maximum equals 9 stars.
Figure A1. Funnel plots for (A) total soy intake and risk of prostate cancer; (B) unfermented soy intake and risk of prostate cancer; (C) fermented soy intake and risk of prostate cancer; (D) genistein intake and risk of prostate cancer; (E) daidzein intake and risk of prostate cancer; and (F) total isoflavone intake and risk of prostate cancer.
Figure A1. Funnel plots for (A) total soy intake and risk of prostate cancer; (B) unfermented soy intake and risk of prostate cancer; (C) fermented soy intake and risk of prostate cancer; (D) genistein intake and risk of prostate cancer; (E) daidzein intake and risk of prostate cancer; and (F) total isoflavone intake and risk of prostate cancer.
Nutrients 10 00040 g0a1
Figure A2. Funnel plots for (A) circulating genistein and risk of prostate cancer and (B) circulating daidzein and risk of prostate cancer.
Figure A2. Funnel plots for (A) circulating genistein and risk of prostate cancer and (B) circulating daidzein and risk of prostate cancer.
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Figure A3. Forest plot for total soy intake and risk of prostate cancer by year of study publication. These associations were indicated as a relative risk (RR) estimate with the corresponding 95% confidence interval (CI).
Figure A3. Forest plot for total soy intake and risk of prostate cancer by year of study publication. These associations were indicated as a relative risk (RR) estimate with the corresponding 95% confidence interval (CI).
Nutrients 10 00040 g0a3
Figure A4. Funnel plot for total soy intake and risk of advanced prostate cancer.
Figure A4. Funnel plot for total soy intake and risk of advanced prostate cancer.
Nutrients 10 00040 g0a4

References

  1. GLOBOCAN. Cancer Fact Sheets: Prostate Cancer. Available online: http://globocan.iarc.fr/old/FactSheets/cancers/prostate-new.asp (accessed on 1 September 2017).
  2. Adlercreutz, H.; Mazur, W. Phyto-oestrogens and Western diseases. Ann. Med. 1997, 29, 95–120. [Google Scholar] [CrossRef] [PubMed]
  3. Andres, S.; Abraham, K.; Appel, K.E.; Lampen, A. Risks and benefits of dietary isoflavones for cancer. Crit. Rev. Toxicol. 2011, 41, 463–506. [Google Scholar] [CrossRef] [PubMed]
  4. Messina, M.J. Legumes and soybeans: Overview of their nutritional profiles and health effects. Am. J. Clin. Nutr. 1999, 70 (Suppl. 3), 439S–450S. [Google Scholar] [PubMed]
  5. Valachovicova, T.; Slivova, V.; Sliva, D. Cellular and physiological effects of soy flavonoids. Mini-Rev. Med. Chem. 2004, 4, 881–887. [Google Scholar] [CrossRef] [PubMed]
  6. Gardner, C.D.; Oelrich, B.; Liu, J.P.; Feldman, D.; Franke, A.A.; Brooks, J.D. Prostatic soy isoflavone concentrations exceed serum levels after dietary supplementation. Prostate 2009, 69, 719–726. [Google Scholar] [CrossRef] [PubMed]
  7. Hsu, A.; Bray, T.M.; Helferich, W.G.; Doerge, D.R.; Ho, E. Differential effects of whole soy extract and soy isoflavones on apoptosis in prostate cancer cells. Exp. Biol. Med. 2010, 235, 90–97. [Google Scholar] [CrossRef] [PubMed]
  8. Chiyomaru, T.; Fukuhara, S.; Hidaka, H.; Majid, S.; Saini, S.; Arora, S.; Guoren, D.; Shahryari, V.; Inik, C.; Tanaka, Y.; et al. Genistein up-regulates tumor suppressor microRNA-574-3p in prostate cancer. PLoS ONE 2013, 8, e58929. [Google Scholar] [CrossRef] [PubMed]
  9. Slusarz, A.; Jackson, G.A.; Day, J.K.; Shenouda, N.S.; Bogener, J.L.; Browning, J.D.; Fritsche, K.L.; MacDonald, R.S.; Besch-Williford, C.L.; Lubahn, D.B.; et al. Aggressive prostate cancer is prevented in ERalphaKO mice and stimulated in ERbetaKO TRAMP mice. Endocrinology 2012, 153, 4160–4170. [Google Scholar] [CrossRef] [PubMed]
  10. Yan, L.; Spitznagel, E.L. Meta-analysis of soy food and risk of prostate cancer in men. Int. J. Cancer 2005, 117, 667–669. [Google Scholar] [CrossRef] [PubMed]
  11. Hwang, Y.; Kim, S.; Jee, S.; Kim, Y.; Nam, C. Soy food consumption and risk of prostate cancer: A meta-analysis of observational studies. Nutr. Cancer 2009, 61, 598–606. [Google Scholar] [CrossRef] [PubMed]
  12. Zhang, M.; Wang, K.; Chen, L.; Yin, B.; Song, Y. Is phytoestrogen intake associated with decreased risk of prostate cancer? A systematic review of epidemiological studies based on 17,546 cases. Andrology 2016, 4, 745–756. [Google Scholar] [CrossRef] [PubMed]
  13. Zhang, Q.; Feng, H.; Qluwakemi, B.; Wang, J.; Yao, S.; Cheng, G.; Xu, H.; Qiu, H.; Zhu, L.; Yuan, M. Phytoestrogens and risk of prostate cancer: An updated meta-analysis of epidemiologic studies. Int. J. Food Sci. Nutr. 2017, 68, 28–42. [Google Scholar] [CrossRef] [PubMed]
  14. Pavese, J.M.; Krishna, S.N.; Bergan, R.C. Genistein inhibits human prostate cancer cell detachment, invasion, and metastasis. Am. J. Clin. Nutr. 2014, 100 (Suppl. 1), 431S–436S. [Google Scholar] [CrossRef] [PubMed]
  15. Lesinski, G.B.; Reville, P.K.; Mace, T.A.; Young, G.S.; Ahn-Jarvis, J.; Thomas-Ahner, J.; Vodovotz, Y.; Ameen, Z.; Grainger, E.; Riedl, K.; et al. Consumption of soy isoflavone enriched bread in men with prostate cancer is associated with reduced proinflammatory cytokines and immunosuppressive cells. Cancer Prev. Res. 2015, 8, 1036–1044. [Google Scholar] [CrossRef] [PubMed]
  16. Moher, D.; Liberati, A.; Tetzlaff, J.; Altman, D.G.; Group, P. Preferred reporting items for systematic reviews and meta-analyses: The PRISMA statement. J. Clin. Epidemiol. 2009, 62, 1006–1012. [Google Scholar] [CrossRef] [PubMed]
  17. Stroup, D.F.; Berlin, J.A.; Morton, S.C.; Olkin, I.; Williamson, G.D.; Rennie, D.; Moher, D.; Becker, B.J.; Sipe, T.A.; Thacker, S.B.; et al. Meta-analysis of observational studies in epidemiology: A proposal for reporting. Meta-analysis Of Observational Studies in Epidemiology (MOOSE) group. JAMA 2000, 283, 2008–2012. [Google Scholar] [CrossRef] [PubMed]
  18. Stang, A. Critical evaluation of the Newcastle-Ottawa scale for the assessment of the quality of nonrandomized studies in meta-analyses. Eur. J. Epidemiol. 2010, 25, 603–605. [Google Scholar] [CrossRef] [PubMed]
  19. Egger, M.; Smith, G.D.; Phillips, A.N. Meta-analysis: Principles and procedures. BMJ 1997, 315, 1533–1537. [Google Scholar] [CrossRef] [PubMed]
  20. Higgins, J.P.; Thompson, S.G. Quantifying heterogeneity in a meta-analysis. Stat. Med. 2002, 21, 1539–1558. [Google Scholar] [CrossRef] [PubMed]
  21. Jackson, D.; White, I.R.; Thompson, S.G. Extending DerSimonian and Laird's methodology to perform multivariate random effects meta-analyses. Stat. Med. 2010, 29, 1282–1297. [Google Scholar] [CrossRef] [PubMed]
  22. Chen, H.; Manning, A.K.; Dupuis, J. A method of moments estimator for random effect multivariate meta-analysis. Biometrics 2012, 68, 1278–1284. [Google Scholar] [CrossRef] [PubMed]
  23. Peters, J.L.; Sutton, A.J.; Jones, D.R.; Abrams, K.R.; Rushton, L. Contour-enhanced meta-analysis funnel plots help distinguish publication bias from other causes of asymmetry. J. Clin. Epidemiol. 2008, 61, 991–996. [Google Scholar] [CrossRef] [PubMed]
  24. Sterne, J.A.C.; Egger, M. Funnel plots for detecting bias in meta-analysis: Guidelines on choice of axis. J. Clin. Epidemiol. 2001, 54, 1046–1055. [Google Scholar] [CrossRef]
  25. Egger, M.; Davey Smith, G.; Schneider, M.; Minder, C. Bias in meta-analysis detected by a simple, graphical test. BMJ 1997, 315, 629–634. [Google Scholar] [CrossRef] [PubMed]
  26. Begg, C.B.; Mazumdar, M. Operating characteristics of a rank correlation test for publication bias. Biometrics 1994, 50, 1088–1101. [Google Scholar] [CrossRef] [PubMed]
  27. Allen, N.E.; Sauvaget, C.; Roddam, A.W.; Appleby, P.; Nagano, J.; Suzuki, G.; Key, T.J.; Koyama, K. A prospective study of diet and prostate cancer in Japanese men. Cancer Causes Control 2004, 15, 911–920. [Google Scholar] [CrossRef] [PubMed]
  28. Bosetti, C.; Bravi, F.; Talamini, R.; Parpinel, M.; Gnagnarella, P.; Negri, E.; Montella, M.; Lagiou, P.; Franceschi, S.; La Vecchia, C.; et al. Flavonoids and prostate cancer risk: A study in Italy. Nutr. Cancer 2006, 56, 123–127. [Google Scholar] [CrossRef] [PubMed]
  29. Heald, C.L.; Ritchie, M.R.; Bolton-Smith, C.; Morton, M.S.; Alexander, F.E. Phyto-oestrogens and risk of prostate cancer in Scottish men. Br. J. Nutr. 2007, 98, 388–396. [Google Scholar] [CrossRef] [PubMed]
  30. Hedelin, M.; Klint, A.; Chang, E.T.; Bellocco, R.; Johansson, J.-E.; Andersson, S.-W.; Heinonen, S.-M.; Adlercreutz, H.; Adami, H.-O.; Gronberg, H.; et al. Dietary phytoestrogen, serum enterolactone and risk of prostate cancer: The cancer prostate Sweden study (Sweden). Cancer Causes Control 2006, 17, 169–180. [Google Scholar] [CrossRef] [PubMed]
  31. Jacobsen, B.K.; Knutsen, S.F.; Fraser, G.E. Does high soy milk intake reduce prostate cancer incidence? The Adventist Health Study (United States). Cancer Causes Control 1998, 9, 553–557. [Google Scholar] [CrossRef] [PubMed]
  32. Jian, L.; Zhang, D.H.; Lee, A.H.; Binns, C.W. Do preserved foods increase prostate cancer risk? Br. J. Cancer 2004, 90, 1792–1795. [Google Scholar] [CrossRef] [PubMed]
  33. Kirsh, V.A.; Peters, U.; Mayne, S.T.; Subar, A.F.; Chatterjee, N.; Johnson, C.C.; Hayes, R.B.; Prostate, L.C. Prospective study of fruit and vegetable intake and risk of prostate cancer. J. Natl. Cancer Inst. 2007, 99. [Google Scholar] [CrossRef] [PubMed]
  34. Kolonel, L.N.; Hankin, J.H.; Whittemore, A.S.; Wu, A.H.; Gallagher, R.P.; Wilkens, L.R.; John, E.M.; Howe, G.R.; Dreon, D.M.; West, D.W.; et al. Vegetables, fruits, legumes and prostate cancer: A multiethnic case-control study. Cancer Epidemiol. Biomark. Prev. 2000, 9, 795–804. [Google Scholar]
  35. Kurahashi, N.; Iwasaki, M.; Inoue, M.; Sasazuki, S.; Tsugane, S. Plasma isoflavones and subsequent risk of prostate cancer in a nested case-control study: The Japan Public Health Center. J. Clin. Oncol. 2008, 26, 5923–5929. [Google Scholar] [CrossRef] [PubMed]
  36. Kurahashi, N.; Iwasaki, M.; Sasazuki, S.; Otani, T.; Inoue, M.; Tsugane, S. Soy product and isoflavone consumption in relation to prostate cancer in Japanese men. Cancer Epidemiol. Biomark. Prev. 2007, 16, 538–545. [Google Scholar] [CrossRef] [PubMed]
  37. Lee, M.M.; Gomez, S.L.; Chang, J.S.; Wey, M.; Wang, R.T.; Hsing, A.W. Soy and isoflavone consumption in relation to prostate cancer risk in China. Cancer Epidemiol. Biomark. Prev. 2003, 12, 665–668. [Google Scholar]
  38. Lewis, J.E.; Soler-Vila, H.; Clark, P.E.; Kresty, L.A.; Allen, G.O.; Hu, J.J. Intake of plant foods and associated nutrients in prostate cancer risk. Nutr. Cancer 2009, 61, 216–224. [Google Scholar] [CrossRef] [PubMed]
  39. Li, X.M.; Li, J.; Tsuji, I.; Nakaya, N.; Nishino, Y.; Zhao, X.J. Mass screening-based case-control study of diet and prostate cancer in Changchun, China. Asian J. Androl. 2008, 10, 551–560. [Google Scholar] [CrossRef] [PubMed]
  40. Low, Y.L.; Taylor, J.I.; Grace, P.B.; Mulligan, A.A.; Welch, A.A.; Scollen, S.; Dunning, A.M.; Luben, R.N.; Khaw, K.T.; Day, N.E.; et al. Phytoestrogen exposure, polymorphisms in COMT, CYP19, ESR1, and SHBG genes, and their associations with prostate cancer risk. Nutr. Cancer 2006, 56, 31–39. [Google Scholar] [CrossRef] [PubMed]
  41. Nagata, Y.; Sonoda, T.; Mori, M.; Miyanaga, N.; Okumura, K.; Goto, K.; Naito, S.; Fujimoto, K.; Hirao, Y.; Takahashi, A.; et al. Dietary isoflavones may protect against prostate cancer in Japanese men. J. Nutr. 2007, 137, 1974–1979. [Google Scholar] [PubMed]
  42. Nagata, Y.; Sugiyama, Y.; Fukuta, F.; Takayanagi, A.; Masumori, N.; Tsukamoto, T.; Akasaka, H.; Ohnishi, H.; Saitoh, S.; Miura, T.; et al. Relationship of serum levels and dietary intake of isoflavone, and the novel bacterium Slackia sp. strain NATTS with the risk of prostate cancer: A case-control study among Japanese men. Int. Urol. Nephrol. 2016, 48, 1453–1460. [Google Scholar] [CrossRef] [PubMed]
  43. Nomura, A.M.Y.; Hankin, J.H.; Lee, J.; Stemmermann, G.N. Cohort study of tofu intake and prostate cancer: No apparent association. Cancer Epidemiol. Biomark. Prev. 2004, 13, 2277–2279. [Google Scholar]
  44. Ozasa, K.; Nakao, M.; Watanabe, Y.; Hayashi, K.; Miki, T.; Mikami, K.; Mori, M.; Sakauchi, F.; Washio, M.; Ito, Y.; et al. Serum phytoestrogens and prostate cancer risk in a nested case-control study among Japanese men. Cancer Sci. 2004, 95, 65–71. [Google Scholar] [CrossRef] [PubMed]
  45. Park, S.-Y.; Murphy, S.P.; Wilkens, L.R.; Henderson, B.E.; Kolonel, L.N. Legume and isoflavone intake and prostate cancer risk: The multiethnic cohort study. Int. J. Cancer 2008, 123, 927–932. [Google Scholar] [CrossRef] [PubMed]
  46. Severson, R.K.; Nomura, A.M.; Grove, J.S.; Stemmermann, G.N. A prospective study of demographics, diet, and prostate cancer among men of Japanese ancestry in Hawaii. Cancer Res. 1989, 49, 1857–1860. [Google Scholar] [PubMed]
  47. Sonoda, T.; Nagata, Y.; Mori, M.; Miyanaga, N.; Takashima, N.; Okumura, K.; Goto, K.; Naito, S.; Fujimoto, K.; Hirao, Y.; et al. A case-control study of diet and prostate cancer in Japan: Possible protective effect of traditional Japanese diet. Cancer Sci. 2004, 95, 238–242. [Google Scholar] [CrossRef] [PubMed]
  48. Strom, S.S.; Yamamura, Y.; Duphorne, C.M.; Spitz, M.R.; Babaian, R.J.; Pillow, P.C.; Hursting, S.D. Phytoestrogen intake and prostate cancer: A case-control study using a new database. Nutr. Cancer 1999, 33, 20–25. [Google Scholar] [CrossRef] [PubMed]
  49. Sung, J.F.C.; Lin, R.S.; Pu, Y.; Chen, Y.; Chang, H.C.; Lai, M. Risk factors for prostate carcinoma in Taiwan: A case-control study in a Chinese population. Cancer 1999, 86, 484–491. [Google Scholar] [CrossRef]
  50. Travis, R.C.; Allen, N.E.; Appleby, P.N.; Price, A.; Kaaks, R.; Chang-Claude, J.; Boeing, H.; Aleksandrova, K.; Tjonneland, A.; Johnsen, N.F.; et al. Prediagnostic concentrations of plasma genistein and prostate cancer risk in 1,605 men with prostate cancer and 1,697 matched control participants in EPIC. Cancer Causes Control 2012, 23, 1163–1171. [Google Scholar] [CrossRef] [PubMed]
  51. Travis, R.C.; Spencer, E.A.; Allen, N.E.; Appleby, P.N.; Roddam, A.W.; Overvad, K.; Johnsen, N.F.; Olsen, A.; Kaaks, R.; Linseisen, J.; et al. Plasma phyto-oestrogens and prostate cancer in the European Prospective Investigation into Cancer and Nutrition. Br. J. Cancer 2009, 100, 1817–1823. [Google Scholar] [CrossRef] [PubMed]
  52. Villenueve, P.J.; Johnson, K.C.; Krieger, N.; Mao, Y. Risk Factors for Prostate Cancer: Results from the Canadian National Enhanced CancerSurveillance System. Cancer Causes Control 1999, 10, 355–367. [Google Scholar] [CrossRef]
  53. Wang, Y.; Stevens, V.L.; Shah, R.; Peterson, J.J.; Dwyer, J.T.; Gapstur, S.M.; McCullough, M.L. Dietary Flavonoid and Proanthocyanidin Intakes and Prostate Cancer Risk in a Prospective Cohort of US Men. Am. J. Epidemiol. 2014, 179, 974–986. [Google Scholar] [CrossRef] [PubMed]
  54. Ward, H.; Chapelais, G.; Kuhnle, G.G.C.; Luben, R.; Khaw, K.-T.; Bingham, S. Lack of prospective associations between plasma and urinary phytoestrogens and risk of prostate or colorectal cancer in the European prospective into Cancer-Norfolk study. Cancer Epidemiol. Biomark. Prev. 2008, 17, 2891–2894. [Google Scholar] [CrossRef] [PubMed]
  55. Ward, H.A.; Kuhnle, G.G.; Mulligan, A.A.; Lentjes, M.A.; Luben, R.N.; Khaw, K.T. Breast, colorectal, and prostate cancer risk in the European Prospective Investigation into Cancer and Nutrition-Norfolk in relation to phytoestrogen intake derived from an improved database. Am. J. Clin. Nutr. 2010, 91, 440–448. [Google Scholar] [CrossRef] [PubMed]
  56. Wu, Y.; Zhang, L.; Na, R.; Xu, J.; Xiong, Z.; Zhang, N.; Dai, W.; Jiang, H.; Ding, Q. Plasma genistein and risk of prostate cancer in Chinese population. Int. Urol. Nephrol. 2015, 47, 965–970. [Google Scholar] [CrossRef] [PubMed]
  57. Rice, L.; Handayani, R.; Cui, Y.; Medrano, T.; Samedi, V.; Baker, H. Soy isoflavones exert differential effects on androgen responsive genes in LNCaP human prostate cancer cells. J. Nutr. 2007, 137, 964–972. [Google Scholar] [PubMed]
  58. Kang, N.H.; Shin, H.C.; Oh, S.; Lee, K.H.; Lee, Y.B.; Choi, K.C. Soy milk digestion extract inhibits progression of prostate cancer cell growth via regulation of prostate cancerspecific antigen and cell cycle-regulatory genes in human LNCaP cancer cells. Mol. Med. Rep. 2016, 14, 1809–1816. [Google Scholar] [CrossRef] [PubMed]
  59. Zuniga, K.; Clinton, S.; Thomas-Ahner, J.M.; Erdman, J.W. The effect of tomato powder, soy germ, or a combination on prostate carcinogenesis in TRAMP mice. FASEB J. 2012, 26, 376. [Google Scholar]
  60. Murphy, P.A.; Song, T.; Buseman, G.; Barua, K.; Beecher, G.; Trainer, D.; Holden, J. Isoflavones in retail and institutional soy foods. J. Agric. Food Chem. 1999, 47, 2697–2704. [Google Scholar] [CrossRef] [PubMed]
  61. Larkin, T.; Price, W.E.; Astheimer, L. The key importance of soy isoflavone bioavailability to understanding health benefits. Crit. Rev. Food Sci. Nutr. 2008, 48, 538–552. [Google Scholar] [CrossRef] [PubMed]
  62. Morito, K.; Hirose, T.; Kinjo, J.; Hirakawa, T.; Okawa, M.; Nohara, T.; Ogawa, S.; Inoue, S.; Muramatsu, M.; Masamune, Y. Interaction of phytoestrogens with estrogen receptors alpha and beta. Biol. Pharm. Bull. 2001, 24, 351–356. [Google Scholar] [CrossRef] [PubMed]
  63. Heldring, N.; Pike, A.; Andersson, S.; Matthews, J.; Cheng, G.; Hartman, J.; Tujague, M.; Ström, A.; Treuter, E.; Warner, M.; et al. Estrogen Receptors: How Do They Signal and What Are Their Targets. Physiol. Rev. 2007, 87, 905–931. [Google Scholar] [CrossRef] [PubMed]
  64. Warner, M.; Huang, B.; Gustafsson, J.-A. Estrogen Receptor β as a Pharmaceutical Target. Trends Pharmacol. Sci. 2017, 38, 92–99. [Google Scholar] [CrossRef] [PubMed]
  65. Mahmoud, A.M.; Yang, W.; Bosland, M.C. Soy isoflavones and prostate cancer: A review of molecular mechanisms. J. Steroid Biochem. Mol. Biol. 2014, 140, 116–132. [Google Scholar] [CrossRef] [PubMed]
  66. Wu, A.H.; Yang, D.; Pike, M.C. A meta-analysis of soyfoods and risk of stomach cancer: The problem of potential confounders. Cancer Epidemiol. Biomark. Prev. 2000, 9, 1051–1058. [Google Scholar]
  67. Islam, M.A.; Punt, A.; Spenkelink, B.; Murk, A.J.; Rolaf van Leeuwen, F.X.; Rietjens, I.M. Conversion of major soy isoflavone glucosides and aglycones in in vitro intestinal models. Mol. Nutr. Food Res. 2014, 58, 503–515. [Google Scholar] [CrossRef] [PubMed]
  68. Messina, M. Soy and Health Update: Evaluation of the Clinical and Epidemiologic Literature. Nutrients 2016, 8, 754. [Google Scholar] [CrossRef] [PubMed]
  69. Busby, M.G.; Jeffcoat, A.R.; Bloedon, L.T.; Koch, M.A.; Black, T.; Dix, K.J.; Heizer, W.D.; Thomas, B.F.; Hill, J.M.; Crowell, J.A.; et al. Clinical characteristics and pharmacokinetics of purified soy isoflavones: Single-dose administration to healthy men. Am. J. Clin. Nutr. 2002, 75, 126–136. [Google Scholar] [PubMed]
  70. Jarred, R.A.; Keikha, M.; Dowling, C.; McPherson, S.J.; Clare, A.M.; Husband, A.J.; Pedersen, J.S.; Frydenberg, M.; Risbridger, G.P. Induction of apoptosis in low to moderate-grade human prostate carcinoma by red clover-derived dietary isoflavones. Cancer Epidemiol. Biomark. Prev. 2002, 11, 1689–1696. [Google Scholar]
  71. Hamilton-Reeves, J.M.; Banerjee, S.; Banerjee, S.K.; Holzbeierlein, J.M.; Thrasher, J.B.; Kambhampati, S.; Keighley, J.; Van Veldhuizen, P. Short-term soy isoflavone intervention in patients with localized prostate cancer: A randomized, double-blind, placebo-controlled trial. PLoS ONE 2013, 8, e68331. [Google Scholar] [CrossRef] [PubMed]
Figure 1. Literature search and study selection flow chart.
Figure 1. Literature search and study selection flow chart.
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Figure 2. Forest plots for (A) total soy intake and risk of prostate cancer; (B) unfermented soy intake and risk of prostate cancer; (C) fermented soy intake and risk of prostate cancer; (D) genistein intake and risk of prostate cancer; (E) daidzein intake and risk of prostate cancer; and (F) total isoflavone intake and risk of prostate cancer. These associations were indicated as a relative risk (RR) estimate with the corresponding 95% confidence interval (CI).
Figure 2. Forest plots for (A) total soy intake and risk of prostate cancer; (B) unfermented soy intake and risk of prostate cancer; (C) fermented soy intake and risk of prostate cancer; (D) genistein intake and risk of prostate cancer; (E) daidzein intake and risk of prostate cancer; and (F) total isoflavone intake and risk of prostate cancer. These associations were indicated as a relative risk (RR) estimate with the corresponding 95% confidence interval (CI).
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Figure 3. Forest plots for (A) circulating genistein and risk of prostate cancer; and (B) circulating daidzein and risk of prostate cancer. These associations were indicated as a relative risk (RR) estimate with the corresponding 95% confidence interval (CI).
Figure 3. Forest plots for (A) circulating genistein and risk of prostate cancer; and (B) circulating daidzein and risk of prostate cancer. These associations were indicated as a relative risk (RR) estimate with the corresponding 95% confidence interval (CI).
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Figure 4. Forest plots for (A) total soy intake and risk of advanced prostate cancer; and (B) isoflavone exposure and risk of advanced prostate cancer. These associations were indicated as a relative risk (RR) estimate with the corresponding 95% confidence interval (CI).
Figure 4. Forest plots for (A) total soy intake and risk of advanced prostate cancer; and (B) isoflavone exposure and risk of advanced prostate cancer. These associations were indicated as a relative risk (RR) estimate with the corresponding 95% confidence interval (CI).
Nutrients 10 00040 g004
Table 1. Characteristics of included studies.
Table 1. Characteristics of included studies.
Author, YearCountryExposureExposure TypeCases/SampleStudy TypeStudy Period (Years)AdjustmentsParticipant Age Range, Mean (SD)Exposure Measurement (Intake or Circulating)
Allen, 2004 [27]JapanTotal soy, miso, tofuDiet196/18,115Cohort1950–1996Age, education, geographic area, city of residence, radiation dose51–89 Cases: 75Tofu, miso: T1 < 2x/week, T3 = almost daily
Total soy: T1 = low, T3 = high
Bosetti, 2006 [28]ItalyTotal isoflavonesDiet1294/2745Case-Control1991–2002Age, BMI, FHPC, education, energy, study center46–74 Cases: 66 Controls: 63Q1 ≤ 14.7 μg/day, Q5 > 32.2 μg/day
Heald, 2007 [29]ScotlandTotal isoflavones, total soyDiet437/920Case-Control1998–2001Age, smoking, FHPC, energy, family history of breast cancer, Carstairs Deprivation Index, smoking and energy intake:BMR ratio50–74 Cases: 67.2 (5.5) Controls: 66.0 (5.4)Isoflavones (μg/day): Q1 < 581.1, Q4 > 1982.2
Soy food: no, yes
Genistein, daidzein, total isoflavonesSerumAge, smoking, FHPC, family history of breast cancer, Carstairs Deprivation IndexGenistein (nmol/L): Q1 < 14.23, Q4 > 64.53
Daidzein (nmol/L): Q1 < 8.26, Q4 > 29.11
Isoflavones (nmol/L): Q1 < 25.57, Q4 > 98.86
Hedelin, 2006 [30]SwedenTotal isoflavones, genistein, daidzeinDiet1499/2629Case-Control2001–2002Age, energy35–79 Cases: 66.8 Controls: 67.8Total isoflavones (μg/day): Q1 ≤ 1.0, Q4 ≥ 2.6
Genistein (μg/day): Q1 ≤ 0.27, Q4 ≥ 1.08
Daidzein (μg/day): Q1 ≤ 0.49, Q4 ≥ 1.11
Jacobsen, 1998 [31]USASoy milkDiet225/12,395Cohort1976–1992Age≥25Never, <daily, 1x/day, >1x/day
Jian, 2004 [32]ChinaTotal soyDiet130/404Case-Control2001–2002Age, BMI, FHPC, education, PA, energy, geographic area, marital status, income, fresh vegetables and fruit consumption, tea drinkingCases: 74.7 (7.1) Controls: 71.4 (7.2)T1 = 0 g/day, T3 > 4.00 g/day
Kirsh, 2007 [33]USATotal soyDiet1338/29,361Cohort1993–2001Age, BMI, smoking, FHPC, PA, energy, ethnicity, geographic area, supplemental vitamin E, total fat intake, red meat intake, diabetes, aspirin use, previous number of PCa screening examinations63.3Q1 = 0 servings/month,
Q4 > 0.5 servings/month
Kolonel, 2000 [34]USA, CanadaTotal soyDiet1619/3237Case-Control1987–1991Age, education, energy, ethnicity, geographic area≥65Q1 < 0.1 g/day, Q5 > 39.4 g/day
Kurahashi, 2007 [36]JapanTotal soy, miso, genistein, daidzeinDiet307/43,509Cohort1995–2004Age, geographic area45–74Total soy (g/day): Q1 < 46.6, Q4 ≥ 107.4
Miso (mL/day): Q1 < 110.0, Q4 ≥ 356.0
Genistein (mg/day): Q1 < 13.2, Q4 ≥ 32.8
Daidzein (mg/day): Q1 < 8.5, Q4 ≥ 20.4
Kurahashi, 2008 [35]JapanGenistein, daidzeinPlasma201/603Nested Case-Control1990–2005Smoking; alcohol; marital status; intake of green tea, protein, fiber, green or yellow vegetables40–69 Cases: 58.6 (6.4) Controls: 58.4 (6.6)Genistein (ng/mL): T1 < 57, T3 ≥ 151.7
Daidzein (ng/mL): T1 < 22, T3 ≥ 61.5
Lee, 2003 [37]ChinaTotal soy, tofu, genistein, daidzeinDiet133/398Case-Control1989–1992Age, energy50–89Total soy (g/day): Q1 < 27.5, Q4 > 111.8
Tofu (g/day): T1 < 14.3, T3 > 34.5
Genistein (mg/day): Q1 < 17.9, Q4 > 62.0
Daidzein (mg/day): Q1 < 10.0, Q4 > 36.3
Lewis, 2009 [38]USAGenistein, daidzeinDiet478/860Case-Control1998–2004Age, BMI, smoking, FHPC, education, energyControls: 62.0 (10.7) Incident cases: 63.3 (8.2) Prevalent cases: 66.9 (8.1)Genistein (mcg/day): L ≤ 196.0, U > 196.1
Daidzein (mcg/day): L ≤ 77.0, U > 77.1
Li, 2008 [39]ChinaTotal soyDiet28/308Case-Control1998–2000BMI, smoking, education, alcohol, food frequencyCases: 71.39 (6.03) Control: 71.14 (5.78)T1 ≤ 2x/week
T3 ≥ 1x/day
Low, 2006 [40]EuropeGenistein, daidzeinDiet85/241Nested Case-Control1993–1997BMI, FHPC, energy45–75Genistein average (95% CI) cases (μg/day): 287.7 (255.5–323.9); controls: 310.2 (283.0–339.9)
Daidzein average (95% CI) cases (μg/day): 224.4 (198.1–254.2); controls: 249.2 (227.8–272.5)
PlasmaGenistein average (95% CI) cases (ng/mL): 4.8 (3.6–6.4); controls: 4.4 (3.7–5.4)
Daidzein average (95% CI) cases (ng/mL): 2.4 (1.8–3.1); controls: 2.4 (2.0–2.9)
Nagata, 2007 [41]JapanTotal soy, genistein, daidzeinDiet200/400Case-Control1996–2003Smoking, energy59–73Total soy (isoflavones) (mg/day): Q1 < 30.5, Q4 ≥ 89.9
Genistein (mg/day): Q1 < 1.1, Q4 ≥ 2.5
Daidzein (mg/day): Q1 < 0.8, Q4 ≥ 1.9
Nagata, 2016 [42]JapanGenistein, daidzeinDiet56/112Case-Control2011–2014Age, BMI, smoking, alcohol, energyCases: 64.7 (6.6) Controls: 63.6 (9.1)Genistein (mg/day): T1 < 17.57, T3 ≥ 36.31
Daidzein (mg/day): T1 < 11.56, T3 ≥ 21.86
Genistein, daidzeinSerumAge, BMI, smoking, alcoholGenistein (ng/mL): T1 < 57.10, T3 ≥ 144.50
Daidzein (ng/mL): T1 < 18, T3 ≥ 51.7
Nomura, 2004 [43]USATofuDiet222/5826Cohort1971–1995Age, BMI, smoking, alcohol, energy, arm muscle areaNot givenQ1 = 0 g/week, Q5 > 240 g/week
Ozasa, 2004 [44]JapanGenistein, daidzeinSerum52/203Nested Case-Control1988–1999Age≥40 Cases: 69.4 Controls: 68.7Genistein (nM): T1 < 239, T3 > 682
Daidzein (nM): T1 < 89, T3 > 239
Park, 2008 [45]USATotal soy, total isoflavones, genistein, daidzeinDiet4404/82,483Cohort1993–1996Time since cohort entry, ethnicity, FHPC, education, BMI, smoking, energy45–75Total soy (g/1000 kcal): T1: 0, T2: 0.1–2.8, T3: ≥2.8
Genistein (mg/1000 kcal): Q1 < 0.7, Q2: 0.7–1.2, Q3: 1.2–1.9, Q4: 1.9–3.1, Q5 ≥ 3.1
Daidzein (mg/1000 kcal): Q1 < 0.7, Q2: 0.7–1.3, Q3: 1.3–2.0, Q4: 2.0–3.2, Q5 ≥ 3.2
Total isoflavones (mg/1000 kcal): Q1 < 1.6, Q2: 1.6–2.9, Q3: 2.9–4.5, Q4: 4.5–7.2, Q5 ≥ 7.2
Severson, 1989 [46]USAMiso, tofuDiet174/7999Cohort1965–1986Age≥46Miso: T1 ≤ 1x/week, T3 ≥ 5x/week
Tofu: T1 ≤ 1x/week, T3 ≥ 5x/week
Sonoda, 2004 [47]JapanTotal soy, natto, tofuDiet140/280Case-Control1996–2002Smoking, energy59–73Total soy (g/day): Q1 ≤ 77.0, Q4 ≥ 187.2
Tofu (g/day): Q1 ≤ 19.7, Q4 ≥ 96.4
Natto (g/day): Q1 ≤ 5.7, Q4 ≥ 40.0
Strom, 1999 [48]USAGenistein, daidzeinDiet83/190Case-Control1996–1998Age, FHPC, alcohol, energyCases: 61 (6.6) Controls: 60.6 (6.9)Genistein mean (μg/day): cases: 19.8; controls: 29.7
Daidzein mean (μg/day): cases: 14.2; controls: 22.8
Sung, 1999 [49]ChinaSoy milkDiet90/270Case-Control1995–1996None≥50Yes, No
Travis, 2009 [51]EuropeGenistein, daidzeinPlasma950/1992Nested Case-Control1992–2003BMI, smoking, education, PA, alcohol, marital status43–76 Cases: 60.4 (5.8) Controls: 60.1 (5.8)Genistein (ng/mL): Q1 ≤ 0.30, Q5 ≥ 7.00
Daidzein (ng/mL): Q1 ≤ 0.30, Q5 ≥ 4.10
Travis, 2012 [50]EuropeGenisteinPlasma655/1310Nested Case-Control1992–2006BMI, smoking, education, PA, alcohol, marital status43–76 Cases: 60.4 (5.8) Controls: 60.1 (5.8)Genistein (ng/mL): Q1 ≤ 0.30, Q5 ≥ 6.10
Villenueve, 1999 [52]CanadaTotal soyDiet1623/3246Case-Control1994–1997Age, geographic area50–74None, some
Wang, 2014 [53]USATotal isoflavonesDiet3974/43,268Cohort1999–2009Age50–74Q1 < 0.029 mg/day, Q5 ≥ 0.144 mg/day
Ward, 2008 [54]EuropeTotal isoflavones, genistein, daidzeinPlasma194/1006Nested Case-Control1993–2006Age, energy40–79Total isoflavones median (ng/mL): 10.3
Genistein median (ng/mL): 6.9
Daidzein median (ng/mL): 2.5
Ward, 2010 [55]EuropeTotal isoflavones, genistein, daidzeinDiet204/1016Nested Case-Control1993–2006Age40–79Total isoflavones mean cases (μg/day): 948.6; controls: 1088
Genistein: mean cases (μg/day): 546.6; controls: 638.2
Daidzein: mean cases (μg/day): 314.9; controls: 355.2
Wu, 2015 [56]ChinaGenisteinPlasma46/100Case-Control2012–2013Age70.1 (8.9) Cases: 72.5 (8.4) Control: 68.0 (8.8)<640.2 nmol/L, >640.0 nmol/L
Abbreviations: body mass index (BMI), family history of prostate cancer (FHPC), basal metabolic rate (BMR), physical activity (PA).
Table 2. Subgroup analysis of included studies. Bold values indicate p < 0.05.
Table 2. Subgroup analysis of included studies. Bold values indicate p < 0.05.
Total Dietary SoyDietary Unfermented SoyDietary Fermented Soy
No. of StudiesRR (95% CI)p-ValueI2 (%)No. of StudiesRR (95% CI)p-ValueI2 (%)No. of StudiesRR (95% CI)p-ValueI2 (%)
Overall Model160.71 (0.58–0.85) <0.00168.9110.66 (0.52–0.83) <0.00160.380.86 (0.66–1.13) 0.28166.6
Study Type
Case-control 90.61 (0.45–0.82) 0.00163.260.55 (0.46–0.66)<0.0010.040.64 (0.27–1.50) 0.30082.3
Cohort70.90 (0.82–0.99)0.0222.750.91 (0.76–1.08)0.26730.640.92 (0.83–1.02)0.1230.0
Continent
North America70.72 (0.56–0.92) 0.00974.760.65 (0.47–0.92) 0.01473.420.91 (0.81–1.02)0.0900.0
Europe10.52 (0.30–0.91)0.0210.0 -------
Asia80.71 (0.50–1.02) 0.06467.350.68 (0.52–0.89)0.00535.460.79 (0.51–1.23) 0.30275.5
Adjustments
High quality120.72 (0.58–0.90) 0.00373.480.61 (0.45–0.82) 0.00169.251.00 (0.73–1.37) 0.99463.1
Mid quality40.66 (0.50–0.87)0.00360.530.81 (0.58–1.13)0.2170.030.56 (0.27–1.17) 0.12474.0
Age
Adjusted110.73 (0.57–0.93) 0.01069.780.68 (0.52–0.88) 0.00365.651.03 (0.72–1.47) 0.89259.8
Unadjusted50.61 (0.39–0.96) 0.03232.130.56 (0.35–0.92)0.02147.530.56 (0.28–1.15) 0.1150.0
BMI
Adjusted50.95 (0.73–1.22) 0.66166.230.78 (0.50–1.23) 0.28264.621.27 (0.58–2.78) 0.55283.8
Unadjusted110.61 (0.53–0.71)<0.00132.080.59 (0.50–0.70)<0.00118.060.73 (0.50–1.07) 0.10363.3
Smoking
Adjusted70.71 (0.56–0.91) 0.00766.340.71 (0.46–1.10) 0.12262.230.56 (0.28–1.15) 0.11578.7
Unadjusted90.72 (0.53–0.96) 0.02766.970.60 (0.51–0.71)<0.00127.151.03 (0.72–1.47) 0.89259.8
FHPC
Adjusted40.95 (0.72–1.24) 0.69071.610.98 (0.79–1.22)0.8550.021.27 (0.58–2.78) 0.55283.8
Unadjusted120.63 (0.55–0.72)<0.00141.5100.61 (0.52–0.72)<0.00132.050.73 (0.50–1.07) 0.10363.3
Energy
Adjusted90.76 (0.61–0.95) 0.01669.750.74 (0.57–0.97) 0.02953.250.72 (0.43–1.22) 0.22179.2
Unadjusted70.62 (0.45–0.86) 0.00457.160.57 (0.39–0.83) 0.00450.631.01 (0.80–1.28)0.9190.0
Education
Adjusted50.82 (0.58–1.16) 0.26374.730.64 (0.41–0.99) 0.04556.131.06 (0.76–1.47) 0.74167.7
Unadjusted110.64 (0.50–0.82) <0.00163.480.66 (0.48–0.89) 0.00765.550.66 (0.39–1.11) 0.11668.2
PA
Adjusted21.32 (0.66–2.66) 0.43378.110.98 (0.79–1.22)0.8550.012.02 (1.08–3.78)0.0280.0
Unadjusted140.64 (0.52–0.78) <0.00163.6100.61 (0.52–0.72)<0.00132.070.79 (0.62–1.02) 0.07158.1
Alcohol
Adjusted20.55 (0.19–1.59) 0.27074.420.55 (0.19–1.59) 0.27074.7
Unadjusted140.71 (0.58–0.87) 0.00170.490.66 (0.51–0.85) 0.00262.380.86 (0.66–1.13) 0.28166.6
Geographic area
Adjusted60.83 (0.61–1.13) 0.23780.140.72 (0.51–1.02) 0.06480.731.16 (0.81–1.67) 0.41655.2
Unadjusted100.59 (0.45–0.79) <0.00160.970.63 (0.48–0.82)0.00128.150.64 (0.41–1.02) 0.06168.9
Marital status
Adjusted12.02 (1.08–3.78)0.0280.0----12.02 (1.08–3.78)0.0280.0
Unadjusted150.67 (0.56–0.81) <0.00158.5110.66 (0.52–0.83) <0.00160.370.79 (0.62–1.02) 0.07158.1
Ethnicity
Adjusted30.86 (0.71–1.04) 0.12458.620.80 (0.51–1.25) 0.31978.7----
Unadjusted130.65 (0.50–0.84) 0.00162.690.61 (0.51–0.73)<0.00139.580.86 (0.66–1.13) 0.28166.6
Dietary IsoflavonesDietary GenisteinDietary Daidzein
No. of studiesRR (95% CI)p-ValueI2 (%)No. of studiesRR (95% CI)p-ValueI2 (%)No. of studiesRR (95% CI)p-ValueI2 (%)
Overall Model61.03 (0.97–1.09)0.31344.9100.90 (0.84–0.97)0.00831.0100.84 (0.73–0.97) 0.01850.5
Study Type
Case-control31.04 (0.89–1.22)0.6040.060.81 (0.68–0.96)0.01649.560.68 (0.47–1.00) 0.05270.1
Cohort/NCC31.01 (0.87–1.17) 0.92876.340.93 (0.85–1.01)0.0770.040.91 (0.84–1.00)0.0420.0
Continent
North America21.03 (0.85–1.26)0.75786.230.76 (0.53–1.10) 0.14562.030.71 (0.47–1.06) 0.09468.2
Europe41.00 (0.89–1.12)0.9610.030.95 (0.84–1.08)0.4190.030.98 (0.80–1.18) 0.79951.7
Asia----40.69 (0.53–0.89)0.0040.040.72 (0.55–0.93)0.0120.0
Adjustments
High quality51.02 (0.91–1.14) 0.78055.880.90 (0.83–0.98)0.01125.180.88 (0.81–0.96)0.00428.1
Mid quality11.05 (0.84–1.31)0.6670.020.81 (0.47–1.38) 0.43072.520.83 (0.40–1.72) 0.62084.4
Age
Adjusted51.08 (1.00–1.16)0.0428.170.89 (0.79–1.00)0.04636.670.83 (0.66–1.03) 0.09256.7
Unadjusted10.93 (0.83–1.04)0.2070.030.91 (0.83–1.01)0.07742.430.81 (0.64–1.03) 0.08851.0
BMI
Adjusted20.94 (0.85–1.04)0.2240.040.91 (0.82–1.00)0.05839.040.89 (0.80–0.98)0.01838.7
Unadjusted41.09 (1.01–1.18)0.02919.660.90 (0.80–1.01)0.06338.260.83 (0.66–1.05) 0.11661.2
Smoking
Adjusted20.95 (0.85–1.06)0.32221.540.73 (0.51–1.04) 0.08059.640.71 (0.50–1.01) 0.05959.4
Unadjusted41.08 (1.00–1.16)0.05527.860.91 (0.81–1.01)0.08610.860.88 (0.73–1.06) 0.17851.1
FHPC
Adjusted30.95 (0.86–1.05)0.3310.040.90 (0.82–1.00)0.04345.740.76 (0.59–0.98) 0.03255.9
Unadjusted31.09 (1.00–1.18)0.04044.060.90 (0.80–1.02)0.08933.560.88 (0.71–1.09) 0.22852.0
Energy
Adjusted40.97 (0.88–1.06)0.4770.080.90 (0.82–0.98)0.01542.780.78 (0.63–0.96) 0.01760.6
Unadjusted21.05 (0.87–1.27) 0.60071.220.92 (0.79–1.07)0.2830.020.93 (0.80–1.09)0.3930.0
Education
Adjusted20.94 (0.85–1.04)0.2240.020.75 (0.44–1.28) 0.29678.220.75 (0.45–1.24) 0.26176.3
Unadjusted41.09 (1.01–1.18)0.02919.680.89 (0.80–0.99)0.03315.580.91 (0.82–1.02)0.10449.8
PA
Adjusted------------
Unadjusted61.03 (0.97–1.10)0.31344.9100.90 (0.84–0.97)0.00831.0100.84 (0.73–0.97) 0.01850.5
Alcohol
Adjusted----20.74 (0.44–1.25)0.2550.020.62 (0.36–1.05)0.0750.0
Unadjusted61.03 (0.97–1.10)0.31344.980.91 (0.84–0.98)0.01243.580.86 (0.74–0.99) 0.04256.0
Geographic area
Adjusted----10.80 (0.56–1.14)0.2190.010.87 (0.61–1.25)0.4470.0
Unadjusted61.03 (0.97–1.10)0.31344.990.91 (0.84–0.98)0.01536.490.83 (0.71–0.97) 0.02255.9
Marital status
Adjusted------------
Unadjusted61.03 (0.97–1.10)0.31344.9100.90 (0.84–0.97)0.00831.0100.84 (0.73–0.97) 0.01850.5
Ethnicity
Adjusted10.93 (0.83–1.04)0.2070.010.94 (0.85–1.05)0.2560.010.92 (0.83–1.03)0.1340.0
Unadjusted51.08 (1.00–1.16)0.0428.190.87 (0.78–0.97)0.00933.290.79 (0.65–0.96) 0.01955.6
Circulating GenisteinCirculating Daidzein
No. of studiesRR (95% CI)p-ValueI2 (%)No. of studiesRR (95% CI)p-ValueI2 (%)
Overall Model90.87 (0.69–1.10) 0.23676.870.92 (0.78–1.08) 0.31058.1
Study Type
Case-control30.31 (0.06–1.65) 0.17090.420.49 (0.06–3.92) 0.50290.9
Cohort--------
Nested Case-control60.97 (0.83–1.13) 0.66852.050.98 (0.93–1.04)0.4900.0
Continent
North America--------
Europe51.02 (0.87–1.21) 0.78458.740.99 (0.93–1.04)0.6576.8
Asia40.37 (0.15–0.92) 0.03179.130.52 (0.22–1.23) 0.13772.5
Adjustments
High quality90.87 (0.69–1.10) 0.23676.870.92 (0.78–1.08) 0.31058.1
Mid quality--------
Age
Adjusted50.41 (0.13–1.29) 0.12885.640.77 (0.44–1.35) 0.36274.3
Unadjusted40.97 (0.72–1.29) 0.81469.930.95 (0.83–1.08)0.39713.1
BMI
Adjusted40.78 (0.45–1.34) 0.36887.630.72 (0.44–1.16) 0.17782.7
Unadjusted50.84 (0.60–1.17) 0.30960.540.99 (0.93–1.05)0.7060.0
Smoking
Adjusted40.73 (0.34–1.57) 0.42488.230.66 (0.30–1.47) 0.30781.9
Unadjusted50.90 (0.74–1.10) 0.27255.640.99 (0.93–1.05)0.6820.0
FHPC
Adjusted21.04 (0.86–1.26)0.6700.0021.03 (0.89–1.2)0.6990.0
Unadjusted70.73 (0.51–1.05) 0.08781.950.77 (0.58–1.06) 0.11569.1
Energy
Adjusted20.99 (0.94–1.05)0.7790.020.99 (0.94–1.05)0.7960.0
Unadjusted70.69 (0.42–1.13) 0.14081.450.76 (0.50–1.15) 0.19564.0
Education
Adjusted21.07 (0.51–2.23) 0.86688.210.80 (0.60–1.07)0.1310.0
Unadjusted70.80 (0.60–1.07) 0.12676.860.94 (0.78–1.14) 0.52859.6
PA
Adjusted21.07 (0.51–2.23) 0.86688.210.80 (0.60–1.07)0.1310.0
Unadjusted70.80 (0.60–1.07) 0.12676.860.94 (0.78–1.14) 0.52859.6
Alcohol
Adjusted30.55 (0.20–1.51) 0.24491.620.39 (0.08–1.88) 0.24386.5
Unadjusted60.93 (0.77–1.12) 0.43751.050.99 (0.94–1.05)0.7570.0
Geographic area
Adjusted--------
Unadjusted90.87 (0.69–1.10) 0.23676.870.92 (0.78–1.08) 0.31058.1
Marital status
Adjusted21.07 (0.51–2.23) 0.86688.210.80 (0.60–1.07)0.1310.0
Unadjusted70.80 (0.60–1.07) 0.12676.860.94 (0.78–1.14) 0.52859.6
Ethnicity
Adjusted--------
Unadjusted90.87 (0.69–1.10) 0.23676.870.92 (0.78–1.08) 0.31058.1
Signifies that results are estimated by DerSimonian–Laird random effects model. Abbreviations: relative risk (RR), confidence interval (CI), number (No.), body mass index (BMI), family history of prostate cancer (FHPC), physical activity (PA).

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Applegate, C.C.; Rowles, J.L., III; Ranard, K.M.; Jeon, S.; Erdman, J.W. Soy Consumption and the Risk of Prostate Cancer: An Updated Systematic Review and Meta-Analysis. Nutrients 2018, 10, 40. https://doi.org/10.3390/nu10010040

AMA Style

Applegate CC, Rowles JL III, Ranard KM, Jeon S, Erdman JW. Soy Consumption and the Risk of Prostate Cancer: An Updated Systematic Review and Meta-Analysis. Nutrients. 2018; 10(1):40. https://doi.org/10.3390/nu10010040

Chicago/Turabian Style

Applegate, Catherine C., Joe L. Rowles, III, Katherine M. Ranard, Sookyoung Jeon, and John W. Erdman. 2018. "Soy Consumption and the Risk of Prostate Cancer: An Updated Systematic Review and Meta-Analysis" Nutrients 10, no. 1: 40. https://doi.org/10.3390/nu10010040

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