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Phyto-oestrogen intake and implications for breast cancer therapy

Published online by Cambridge University Press:  27 October 2009

S. Ramnarine
Affiliation:
University of Edinburgh, Edinburgh, UK
H. Hinkley
Affiliation:
British College of Osteopathic Medicine, London, UK
M. Ritchie
Affiliation:
Napier University, Edinburgh, UK
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Abstract

Type
Abstract
Copyright
Copyright © The Authors 2009

Breast cancer is the most common malignancy among women and is the second leading cause of death(1). Evidence suggests that a diet rich in phyto-oestrogens (PE) and vegetables is associated with a reduced risk of breast cancer(Reference Aldecreutz2). The aim of the present study was to evaluate the role of PE in breast cancer therapy by initially assessing intake in a group of volunteers consuming a vegan diet (associated with a lower risk of cancer) and by conducting a literature review.

A newly-developed FFQ designed by the British College of Osteopathic Medicine was used to assess PE (total genistein and daidzein) intake in a group of vegan men and women (n 80). Mean intake was 33.4 mg/d(Reference Ritchie, Ramnarine and Wong3). Assessment of PE intake has useful implications in breast cancer research. Variations in the incidence of breast cancer in Eastern countries, e.g. in Japan where the incidence is one-third of that of Western countries(Reference Rice and Whitehead4), may result from higher PE intakes. The average PE intake of Eastern populations (30 mg/d) is much higher than that of Western populations (⩽10 mg/d)(Reference Ritchie, Ramnarine and Wong3). PE may exert a ‘protective role against breast cancer’(Reference Keinan-Boker, van Der and Grobbee5). Using the FFQ to measure PE (tofu) intake in Asian-American women, it has been found that a higher tofu intake is associated with a significant decrease in breast cancer risk among premenopausal women (15% reduction in risk if consumed at least once weekly)(Reference Ritchie, Ramnarine and Wong3). There is evidence that increased PE consumption in a vegetarian diet is associated with a reduced incidence of breast cancer, validating the use of this new FFQ(Reference Aldecreutz2,Reference Wu, Ziegler and Horn-Ross6).

Analysis and review of epidemiological, rodent and human studies revealed a potential role for PE in breast cancer therapy where exposure to PE is associated with alteration of oestrogen metabolism in a manner that may help reduce the ability of tumours to grow(Reference Wu and Pike7Reference Richter, Mylonas and Toth10). Overall interpretation of results was complicated by methodological limitations (small sample size, selection and recall biases). Based on inconsistencies in evidence, it is apparent that the use of PE is still in its infancy, justifying a need for further research. To improve the integrity of the results a few guidelines should be implemented. First, there should be standardization in methodology, e.g. in the preparation of PE extracts. Stratification of PE levels is also necessary for meaningful comparison of ‘low’ and ‘high’ intakes between populations. Additionally, larger sample sizes in studies will assist in validating results. The mechanisms of action require further investigation in order to understand the interaction with current breast cancer therapies, as the evidence relating to the use of PE and Tamoxifen is conflicting(Reference Duffy, Perez and Partridge11). Last, safety issues such as the long-term effects of PE warrant inspection. In the future the chemopreventative role of PE in breast cancer therapy should be developed ‘in line with advances in genetic and molecular epidemiology of carcinogenesis’(Reference Surh12).

References

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