Fish consumption and mortality in the European Prospective Investigation into Cancer and Nutrition cohort

The EPIC cohort included 509,308 women and men, aged mostly 35–70 years at enrolment (1992–1998/1999). The study participants were recruited from the general population and within defined areas in each country with some exceptions; participants were female members of a health insurance scheme for state school employees in France, women attending breast cancer screening in Utrecht (NL) and Florence (Italy), and units of the Italian and Spanish cohorts included members of local blood donor associations. In Oxford (UK), a part of the cohort includes persons not consuming meat (further referred to as health-conscious). In Norway, France, Naples (Italy), and Utrecht only women were recruited [30].

Eligible participants gave written informed consent and completed questionnaires on their diet, lifestyle, and medical history. Approval for this study was obtained from the ethical review boards of the International Agency for Research on Cancer and from all local institutions where subjects had been recruited for the EPIC study.

Individuals in the top and bottom 1 % of the ratio of energy intake to estimated energy requirement (calculated from age, sex and bodyweight) were excluded from the analyses to reduce the effect of implausible extreme values (n = 1,033), in addition 6,627 persons with missing dietary data and 21,113 persons with missing info on non-dietary covariates were excluded. The number of subjects included in the analysis of total fish was 480,535. Due to missing information on lean and fatty fish in the cohorts from Naples, Heidelberg (Germany), Potsdam (Germany) and Umeå (Sweden), we had to exclude all 79,324 individuals from these centres, leaving 401,211 subjects for the separate analysis on lean and fatty fish.

Dietary data were obtained using different validated dietary history or food-frequency questionnaires (FFQ), tailored to each country in order to capture local dietary habits and provide high compliance. To calibrate dietary data collected by different instruments, a single 24-h computerized dietary recall (24-HDR) was performed in a random sample (8 %) of the EPIC cohort (36,900 individuals) [36, 37]. The aim of the calibration study was to adjust for systematic differences in reporting of dietary intakes across countries due to different populations and different instruments [14]. Fish intake has been evaluated in the EPIC cohort, and strong correlations were found between fish intake and plasma phospholipid fatty acids [33].

We examined total fish consumption (lean and fatty fish), lean fish consumption, and fatty fish consumption. Products of lean fish (e.g. fish cakes, fish stew, and similar) were not included in the analyses. Fatty fish consumption included canned fish products. Fish containing <4 % fat was classified as lean (e.g. cod, haddock, plaice), whereas fish containing 4 % fat or more was classified as fatty (e.g. salmon, trout, herring, mackerel).

Questions about fish consumption in the questionnaires varied considerably between centres and countries, from simple questions on whether participants ate fish and the frequency and portion size to more detailed information on type of fish eaten, cooking methods and seasonal variability.

Lifestyle questionnaires included questions about education, socio-economic status, occupation, history of previous illness, physical activity, anthropometry, alcohol consumption and smoking status.

Follow-up was based on cancer registries, boards of health, and death indices in Denmark, Italy (except Naples), the Netherlands, Spain, Sweden, Norway, and the United Kingdom. In France, Germany, Greece, and Naples (Italy) this information was obtained from municipality registries, regional health departments, physicians, and hospitals, and by contacting next-of-kin. The participants were followed from enrolment (1992–1999) until death, emigration or end of the follow-up period (Varese and Naples (Italy) 2006; Florence (Italy) 2007; Granada, Murcia, and San Sebastian (Spain), Malmö (Sweden), and Denmark 2008; Ragusa (Italy), Asturias and Navarra (Spain), Oxford (UK), The Netherlands, Greece, Umeå (Sweden), and Norway 2009; Turin (Italy), Cambridge (UK), Germany, and France 2010).

Causes of death reported in death certificates were recorded according to the 10th edition of the International Statistical Classification of Diseases, Injuries and Causes of Death (ICD10), with ischaemic heart death defined as I20–25, and cancer death of all causes as C00–97 (malignant neoplasms).

Due to the large sample size and statistical power of the study we decided to use a more stringent confidence interval, thus, hazard ratios (HR) and their 99 % confidence interval (CI) were estimated using Cox proportional hazard regression models. Attained age was used as the primary time variable in the Cox regression models. The analyses were stratified by centre and age at enrolment in 1 year intervals to control for effects related to different follow-up procedures and questionnaire design. France was included as a single centre, as dietary assessment and follow-up procedures were the same throughout the country, as was the case for Norway. The UK Oxford centre was divided into two, one for the general population and one for the health conscious participants.

Fish consumption, as reported in the questionnaires, was divided into EPIC-wide quintiles to ensure than comparisons were made over the variability in intake of the entire EPIC cohort. Models with fish consumption as a continuous variable, using an increment of 10 g/day, were also examined. To account for the variability of fish consumption within the different countries fish consumption was also divided into country-wide quintiles. Sex-specific analyses as well as combined analyses of total fish were performed. To investigate which food items higher fish consumption replaced we performed sex and country specific analysis where we looked at consumption of red meat, processed meat, and white meat in quintiles of total fish intake, adjusted for total energy and mutually for each other.

To correct for centre-specific bias and regression dilution within each centre stratum, the 24-HDR values for participants of the calibration study were regressed on their main study dietary questionnaire values, providing regression coefficients for fish consumption.

Age at recruitment, weight, BMI, and season in which the FFQ data were collected were included as covariates in the calibration model. In addition, centre was included in the calibration model as a main effect to ensure correction for between-centre measurement errors. Estimation of regression coefficients was weighted for season and day (weekday/weekend) of the 24-HDR measurements [16].

The regression intercepts and slopes that were obtained from the calibration study were then applied to the main study questionnaire data to obtain individual predicted values of dietary exposure for all participants. Cox regression models were conducted using the predicted values for each individual. An indicator variable (non-consumer/consumer) was included in the disease model. The same covariates were included in disease models using calibrated values as for the non-calibrated model. The middle quintile was used as reference since they are considered to be more “normal consumers” than the non/very low-consumers, who are often different from the rest in many ways (e.g. vegetarians, allergies, etc.). The middle quintile is also closer to the recommended intake of fish [15, 38‐40, 42]. The standard error of the de-attenuated coefficient was calculated with bootstrap sampling (ten samples) in the calibration models to take into account the uncertainty related to measurement error correction.

We explored fish intake using different models for energy adjustment (substitution model, and residual method, model 1 (disease = b₁ Nutrient residual) and model 2 (disease = b₁ Nutrient residual + b₂ Calories). Nutrient residual is the residual from the regression of a specific nutrient (b₁) on calories and b₂ Calories represent calories provided by the specific nutrient) [47], but this did not appreciably change the observed associations and we decided to use the substitution model in our final analysis. In the substitution model, the energy percentage (E %) of fat, and protein and carbohydrate were included as variables. By including these macronutrients, it is possible to estimate relevant contrasts between macronutrient effects. The interpretation of these two estimated parameters is the effect of increasing the intake of one, while keeping the other constant, i.e., at the expense of the nutrient not included as a variable in the model [10]. Fatty fish and lean fish were mutually adjusted for. In addition, the results were adjusted by including the following covariates in the models: estimated energy intake divided into energy from fat (expressed as 100 g/day), and energy from carbohydrates and proteins (expressed as 100 g/day), total dietary fibres, red meat, processed meat, vegetables, fruit (all continuous in g/day), and categories for alcohol intake (abstainers, <15, 15–30, ≧30 g/day), body mass index (BMI) (<18.5, 18.5–24.9, 25–29.9, ≧30), physical activity in leisure time (inactive, moderate, intense, unknown = 1.1 %), smoking status (never smoker, former—quit ≧10 years ago, former—quit <10 years ago, former—quit unknown, current <15 cigarettes/day, current 15–24 cigarettes/day, current ≧25 cigarettes/day, current—number of cigarettes unknown, smoking status unknown = 1.7 %), education (none, primary school, technical/professional school, secondary school, university degree, not specified = 2.4 %).

Test for heterogeneity across countries was performed with Likelihood ratio test, and Wald test was used to test for heterogeneity between men and women.

To account for the distance between the quintiles, a variable with the median within each quintile was included. The same variable was then included as squared, to test for linear and quadratic (U-shaped) trend.

Restricted cubic spline regression was used to examine non-linearity of the relative risk function for predicted intake data. Log likelihood ratio statistics was used to evaluate whether the fish variables contribute significantly to the model fit, either for the linear or the restricted cubic spline model, and whether the restricted cubic spline model parameters add significantly to the model fit compared to the linear model.

To rule out reverse causation the analyses were repeated excluding participants with <2 years of follow up.

All analyses were performed using SAS version 9.2 (SAS Institute, Cary, North Carolina).