Heme Iron Intake, Dietary Antioxidant Capacity, and Risk of Colorectal Adenomas in a Large Cohort Study of French Women

The E3N cohort study

The E3N prospective cohort was initiated in France in 1990 to study the main risk factors of cancer and severe chronic conditions in women (24). It includes 98,995 French women born between 1925 and 1950 and covered by the MGEN, a national teacher's health insurance plan. All women signed an informed consent in compliance with the rules of the French National Commission for Data Protection and Individual Freedom (Commission National Informatique et Libertés), from which approval was obtained.

Medical and lifestyle data

In each questionnaire, women declared all medical events, including cancer occurrence, screening examinations, and findings of colonoscopies, as well as information on lifestyle, including lifetime use of hormonal treatments, height and weight, and smoking status.

Dietary data

The food frequency questionnaire was sent to 95,644 women (with two reminders for non-answering women) between June 1993 and July 1995. It was composed of questions about (i) quantity and frequency of food groups and (ii) qualitative data to detail food groups into single foods. The questionnaire was sent with a booklet of pictures to facilitate the estimation of portion sizes (25). The questionnaire provided data on the intake of 208 food and drink items. It was validated with twelve monthly 24-hour recalls, and reproducibility was evaluated after one year (26). In all, 77,613 questionnaires were collected, and the response rate was 81.1%. Among them, we excluded 985 women because they failed to sign a consent file for external health follow-up by the health insurer in the case of dropout of the study and 2,106 women because of miscoded or double answers. Therefore, 74,522 questionnaires were available for the analysis of dietary factors. Mean daily intake of nutrients was evaluated using a food composition table derived from the French food composition table of the French Information Center on Food Quality (27). The table was completed with the NEAC of foods, evaluated with two different assays: ferric ion–reducing antioxidant power (FRAP), based on the single-electron transfer method, and total radical-trapping antioxidant parameter (TRAP), based on the hydrogen atom transfer method, calculated using an Italian database (28, 29). Because the correlation between FRAP and TRAP was high (r_Pearson = 0.999) and because FRAP is directly related to the reduction of iron oxidation, we chose to present only results with FRAP in the main text (results with TRAP are listed in Supplementary Tables). For four food items (apple, melon, beer, and vinegar), two values were available, and we used an average value. If there was no exactly matching food item in the database, we used the value of a similar item, based on the similarity of botanical group and in vitamin E and polyphenol contents. The NEAC intake from coffee was not considered in this study due to (i) uncertainty about the in vivo absorption of its main antioxidant compounds and (ii) the fact that coffee could act as an important confounder, considering its associations with multiple negative lifestyle factors (30). For each food item, the heme iron content was calculated by multiplying the iron content (in mg/g) of the food by the type-specific percentage of heme iron (e.g., 65%, 39%, and 26% for cooked beef, pork, and chicken or fish, respectively), as described by Balder and colleagues (31). For processed meat items, the nitrosylated heme iron content was calculated by multiplying the heme iron content of each type of processed meat by 0.67 (32), a coefficient provided by the French Pork Institute (Paris, France) since in France, most processed meat is pork meat, especially at the time of the questionnaire (1993–1995). These data were included in the food composition table and enabled us to obtain daily intakes of total heme iron and nitrosylated and non-nitrosylated heme iron intakes. Information on antioxidant dietary supplement intake was provided in the 1994 and 2000 questionnaires.

Identification of cases

The polyp database has been described previously (33). Briefly, we requested pathology and colonoscopy reports from the women who reported intestinal polyps in the questionnaires and from their physicians to code the polyp histologic features, size, number, and site. Advanced lesions were defined as adenomas over 1 cm in diameter, or with high-grade dysplasia (severe or in situ adenocarcinoma), or with over 20% villous component. Women simultaneously diagnosed with advanced and nonadvanced adenomas were classified in the “advanced adenoma” category. Right colon included the caecum, ascending colon, hepatic flexure, and transverse colon; left colon included the splenic flexure, descending colon, and sigmoid colon; and rectum included the rectosigmoid junction and the rectal ampulla.

Population and follow-up

Because adenomas are only diagnosed with colonoscopy, we restricted our population to women who underwent at least one colonoscopy during follow-up; women with polyp-free colonoscopies were defined as non-cases. Women with only hyperplastic polyps or with polyps of unknown histology were excluded from the study population.

Baseline was defined as the date of response to the food frequency questionnaire (1993). Participants contributed person-years of follow-up until the date of adenoma diagnosis, the date of the questionnaire with normal colonoscopy prior to any cancer diagnosis, the date the last questionnaire with normal colonoscopy was returned, or July 2002 (date of the 2002 questionnaire mailing) if the 2002 questionnaire was the last questionnaire with normal colonoscopy, whichever occurred first.

From the initial 74,522 women who answered the 1993 questionnaire, we excluded 4,654 with prevalent cancer, 810 lost to follow-up after the baseline questionnaire, and 1,364 with extreme values of energy intake [individuals in the top and bottom 1% of the ratio of energy intake to basal metabolic rate computed on the basis of age, height, and weight (34)]. In the remaining cohort, 20,922 women underwent a colonoscopy during follow-up; we further excluded 193 women with inflammatory bowel disease, 9 with colectomy, one with familial adenomatous polyposis, 1,953 with a colorectal adenoma or unspecified polyp diagnosed before baseline, 840 with only hyperplastic polyps at first polyp diagnosis (i.e., first colonoscopy with a polyp), 114 whose removed polyp was not analyzed, and 415 with no available histologic report despite repeated mailings to women and/or their physicians (33). Therefore, 17,397 women were available for the adenoma study.

Statistical analysis

HR estimates and 95% confidence intervals (CI) were obtained using Cox proportional hazards model with the ages of individuals used as the time scale (35). HRs were determined by comparison with the lowest quartile of intake. To test for linear trends across categories, we modeled semiquantitative variables, considering the median value of each category. In multivariable analyses, models were simultaneously adjusted for colorectal cancer in first-degree relatives (yes or no), education level (less or more than 14 years of schooling), smoking status (never smoker vs. ever smoker), menopausal status (yes or no), physical activity (semiquantitative considering the median value of each quartile in METs), body mass index (BMI; semiquantitative considering the median value of each quartile in kg/m²), total energy intake (semiquantitative considering the median value of each quartile in kcal/day), alcohol intake (semiquantitative considering the median value of each quartile in mL/day), dietary fiber intake (semiquantitative considering the median value of each quartile in g/day), dietary and supplemental calcium intakes (quartiles, time dependent), and dietary zinc intake (semiquantitative considering the median value of each quartile in mg/day). Nitrosylated and non-nitrosylated heme iron were simultaneously included in the model. Additional adjustment for FRAP, TRAP, menopausal hormone therapy, or number of colonoscopies did not modify the observed associations and was therefore not included in the main models. Data were missing for less than 5% of adjustment variables; we therefore replaced missing values with the modal value.

HRs according to adenoma site or risk category (advanced or nonadvanced) were estimated by using a competing risk method in which adenoma cases, other than those under study, were censored at the date of diagnosis (36). We then tested homogeneity in associations between colon and rectum, right and left colon, and advanced and nonadvanced adenomas.

We tested for potential interactions between heme iron intake (in ordered quartiles) and NEAC (two categories according to the median value) by including an interaction term between the two variables into the fully adjusted regression model. We additionally investigated associations between colorectal adenoma risk and the total heme iron/FRAP ratio. The ratio was modeled as restricted cubic splines based on three knots in the Cox regression model. The knots were located at the 25th (reference value), 50th, and 75th percentiles (0.055, 0.084, and 0.12 g/mol). Estimates of colorectal adenoma risk associated with the ratio were extracted from the model.

In the sensitivity analyses, we restricted analyses to women who did not report any antioxidant (vitamin E, vitamin C, or β-carotene) supplement intake during follow-up. Women using supplements were censored at the date they declared antioxidant supplement intake. We also conducted a sensitivity analysis excluding the first two years of follow-up to investigate potential reverse causation bias.

All P values were two-tailed, and statistical significance (P value) was set at the 0.05 level. All analyses were performed using the SAS software, version 9.3 (SAS Institute, Inc).