1 Istituto di Ricerche Farmacologiche Mario Negri, Milan; 2 Servizio di Epidemiologia, Centro di Riferimento Oncologico, Aviano (PN), Italy; 3 Registre Vaudois des Tumeurs, Institut Universitaire de Médicine Sociale et Préventive, Lausanne, Switzerland; 4 Servizio Integrato di Epidemiologia e Sistemi Informativi (SINTESI), Rome, Italy; 5 International Agency for Research on Cancer, Lyon Cedex, France; 6 Istituto di Statistica Medica e Biometria, Università degli Studi di Milano, Milan, Italy
Received 20 November 2002; revised 3 March 2003; accepted 25 July 2003
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Abstract |
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Diet has been recognised as having a role in the aetiology of oral and pharyngeal cancer, and dietary factors may account for 1015% of cases in Europe. Folate deficiency has been linked to risk of several cancers, but has not been studied adequately with respect to oral cancer.
Patients and methods:
This casecontrol study, conducted in Italy and French-speaking Switzerland, included 749 patients with incident cancer of the oral cavity and pharynx, and 1772 hospital controls with acute, non-neoplastic conditions. The interviews used a validated food frequency questionnaire. Odds ratios (OR) and 95% confidence intervals (CI) were estimated using multiple logistic regression.
Results:
The ORs were 0.68 (95% CI 0.520.88) for the intermediate tertile and 0.53 (95% CI 0.400.69) for the highest tertile of dietary folate intake, compared with the lowest tertile. No heterogeneity was found in strata of gender, age, methionine intake or alcohol consumption. The combined OR for low-folate and high-alcohol intake versus high-folate and low-alcohol intake was 22.3 (95% CI 13.138).
Conclusions:
Our study supports a protective role of folate against oral and pharyngeal carcinogenesis. Compared with low folate intake, a consistent reduction in risk was already observed from intermediate levels of intake, suggesting that cancer risk may be related to relative folate deficiency.
Key words: alcohol, casecontrol study, diet, folate, oral and pharyngeal cancer
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Introduction |
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Folate deficiency has been linked to risk of cancer at several sites [57]. Several casecontrol and cohort studies have examined the relationship between dietary folate intake, or serum folate, and risk of colorectal, breast and other cancers [8, 9]. Many of them have found inverse associations, particularly for colorectal cancer [811]. Only a few studies, however, have considered the possible influence of folate on the risk of oral and pharyngeal cancer. No association was found in three casecontrol studies from the USA [12], Central America [13] and South America [14], while an Italian study observed significantly lower serum folate levels in head and neck squamous-cell carcinoma patients than in smoking and non-smoking controls [15].
A combined effect of low folate, low methionine and high alcohol intake has been related to excess risk of colon cancer [11, 16, 17]. Folate is essential in the conversion of methionine to S-adenosylmethionine, the principal methyl donor in the body [6]. High alcohol consumption interferes with folate absorption and increases folate excretion by the kidney, and can therefore result in a decreased supply of folate [18, 19]. However, a study from Puerto Rico [13] found neither an association between methionine and risk of oral cancer, nor a systematic pattern of risk with respect to folate intake among non-drinkers and heavy drinkers.
To yield further information on the issue, we analysed data from a casecontrol study conducted in Italy and French-speaking Switzerland. Most subjects in these populations are regular drinkers, and consumption of fruit and vegetables is relatively high [20, 21]. Thus, these populations are particularly suitable for examining the possible relationship between folate and alcohol intake, and risk of oral and pharyngeal cancer.
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Patients and methods |
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The study included 749 incident, histologically confirmed cases with cancer of the oral cavity and pharynx (634 men and 115 women), admitted to the major teaching and general hospitals in the areas under surveillance. Cancers of the lip, salivary glands and nasopharynx were not included. Cases ranged between 22 and 77 years of age (median 57 years). Controls comprised a total of 1252 men and 520 women, aged 2078 years (median 57 years), admitted to the same network of hospitals for acute, non-neoplastic conditions not associated with smoking, alcohol or long-term dietary change. Patients were admitted for acute surgical conditions (29%), for non-alcohol-related traumas (mostly fractures and sprains) (23%), for other orthopaedic disorders (25%), and for other miscellaneous illnesses such as eye, ear, nose and throat, or skin diseases (23%). Less than 5% of cases and controls approached during their hospital stay refused to participate.
Data were collected by trained interviewers, using a structured questionnaire, including information on sociodemographic characteristics such as education and occupation, lifetime smoking and alcohol-drinking habits, physical activity, a problem-oriented personal medical history and family history of cancers.
An interviewer-administered food frequency questionnaire (FFQ) was developed to assess the usual diet during the 2 years preceding the diagnosis (for cases) or hospital admission (for controls), in order to estimate intake of total energy as well as that of selected nutrients. The questionnaire included 78 foods, food groups or dishes, divided into six sections: (i) bread, cereals, first courses; (ii) second courses (i.e. meat, fish and other main dishes); (iii) side dishes (i.e. vegetables); (iv) fruits; (v) sweets, desserts and soft drinks; and (vi) milk, hot beverages and sweeteners. For a few vegetables and fruits, seasonal consumption and the corresponding duration were elicited. At the end of each section, one or two open questions were used to include foods that were not included in the questionnaire, but that were eaten at least once per week. There were a few differences in the dietary items listed in the Italian and Swiss versions of the questionnaire, to account for different eating and drinking patterns. Dietary supplementation was not considered, given the low frequency of use by these populations. Information from the FFQ was managed using a specifically developed SAS programme to avoid any disproportion. Such data were, whenever possible, corrected, or otherwise treated as missing values. If information on a dietary item was missing, we substituted it with the median value of consumption of the item, according to the relevant study centre. To compute energy and nutrient intake, including folate, ad hoc-developed food composition databases were used and integrated with other sources when necessary [23]. The FFQ was satisfactorily reproducible [24] and valid [25].
Odds ratios (OR) of oral and pharyngeal cancer and their corresponding 95% confidence intervals (CI) were estimated using unconditional multiple logistic regression models [26], including terms for age, gender, study centre, education, body mass index, alcohol drinking and smoking habit. To adjust for non-alcohol energy intake, folate intake residuals were computed [27]. Thus, folate cut-off points do not express absolute frequencies of intake, and consequently do not provide information on levels of consumption. However, when the tertiles were computed with respect to the absolute intake of folate, the cut-off points were 235.9 µg/day and 300.7 µg/day. Tertiles of folate, methionine and alcohol intake were based on the combined distribution of cases and controls. The significance of the linear trends in risk was assessed by comparing the differences between the deviances of the models, without and with a term for folate intake, to the 2 distribution with 1 degree of freedom [26]. To test for interactions, the differences in 2 x log(likelihood) of the models with and without interaction terms were compared with the
2 distribution with the same number of degrees of freedom as the interaction terms. When the variables were entered in the regression models, the measurement unit was set at 1 standard deviation (SD) of the distribution of controls.
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Results |
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Discussion |
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Coherently, in this study high folate appeared to exert a stronger protection in subjects with low intake of methionine. However, methionine intake was not related to risk of oral and pharyngeal cancer, and the test for heterogeneity was non-significant. Alcohol consumption is a well assessed, strong risk factor for oral cancer. High intakes of alcohol are also responsible for decreased folate absorption in the body, and may increase folate requirements [18]. Thus, the combined role of folate and alcohol on oral and pharyngeal carcinogenesis is of specific interest. In this population, the inverse association between folate and risk of oral and pharyngeal cancer was similar across strata of alcohol intake, and consequently the risk in those with low folate and high alcohol intake was increased >22 times.
The association between folate and oral cancer may, at least in part, be due to fruit and vegetables, which are the main sources of folate and are inversely related to cancer risk [13, 28, 29]. However, in this study, adjustment for fruit and vegetable consumption only slightly reduced the inverse association between folate and oral cancer risk, which remained significant (OR = 0.66, 95% CI 0.490.89). The possibility that other micronutrients, particularly those contained in fruit and vegetables, are responsible for the protective effect observed could not be excluded [29]. For several micronutrients, this was difficult to verify, given the strong correlations with folate intake and the risk of generating over-adjusted models. For example, the correlation coefficients were 0.68 for vitamin C, 0.57 for ß-carotene, 0.82 for vitamin B6 and 0.61 for vitamin E, and these micronutrients were also inversely related to oral and pharyngeal cancer [30]. When we added in the regression model a term for vitamin C, the OR for high folate intake became 0.78 (95% CI 0.571.08). A similar modifying effect was observed adjusting for ß-carotene (OR = 0.70; 95% CI 0.520.95), while no differences emerged when we included models terms for vitamins B6 and E.
Aspirin, when taken in therapeutic doses, may exert an antifolate activity [31]. In this population, aspirin was regularly used by only eight cases (1.1%) and 17 controls (1.0%). Consequently, neither the adjustment for aspirin use nor the exclusion of regular users materially changed the results.
The present findings are consistent with those reported for other neoplasms. In a companion study on colorectal cancer [17], a protective effect of folate was found. Another Italian study found a favourable effect of folate against breast cancer risk in women consuming two or more alcoholic beverages per day [32]. A recent US casecontrol study found a significant inverse association between folate intake and oesophageal cancer, which shares several risk factors with oral and pharyngeal cancer [33]. On the other hand, the three casecontrol studies conducted in America that have considered folate and oral cancer risk have not found consistent associations [1214]. The different results observed in our study may originate from the higher consumption of alcohol in our population, as well as from differences in average intake and main food sources of folate in different populations.
A possible limitation of this study lies in the use of hospital controls, since their dietary habits may be different from those of the general population. However, we attempted to exclude from the control group those subjects with conditions associated with long-term modifications of diet. On the other hand, however, the use of hospital controls should reduce recall bias and increase the comparability of information obtained by cases and controls [34]. Strengths of the study are the almost complete participation rate, the use of a validated and reproducible FFQ [24, 25] that allowed to control for intake of energy and of other nutrients, and the similar catchment areas of cases and controls.
In conclusion, our study, based on a population with high alcohol intake, supports a protective role of folate in the aetiology of oral and pharyngeal cancer. Given the findings obtained in similar populations for colorectal and breast cancer [17, 32], these data confirm the importance of folate in the process of carcinogenesis. Compared with low folate intake in this population, a significant reduction in risk was found for intermediate levels, suggesting that oral cancer risk may be mainly linked to relative folate deficiencies.
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Acknowledgements |
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Footnotes |
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References |
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