Hostname: page-component-586b7cd67f-tf8b9 Total loading time: 0 Render date: 2024-11-26T22:52:28.696Z Has data issue: false hasContentIssue false

Relationship between fish intake, n-3 fatty acids, mercury and risk markers of CHD (National Health and Nutrition Examination Survey 1999–2002)

Published online by Cambridge University Press:  01 August 2009

Kimberly M Smith*
Affiliation:
Department of Nutrition and Food Science, University of Maryland, College Park, MD, USA Exponent, Inc., The Lenz, 1st Floor, Hornbeam Park, Harrogate, North Yorkshire, HG2 8RE, UK
Leila M Barraj
Affiliation:
Exponent, Inc., The Lenz, 1st Floor, Hornbeam Park, Harrogate, North Yorkshire, HG2 8RE, UK
Mark Kantor
Affiliation:
Department of Nutrition and Food Science, University of Maryland, College Park, MD, USA
Nadine R Sahyoun
Affiliation:
Department of Nutrition and Food Science, University of Maryland, College Park, MD, USA
*
Corresponding author: Email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Background

Fish consumption has been shown to be inversely associated with CHD, which may be due to n-3 fatty acids. The n-3 fatty acids, EPA and DHA, are naturally found only in marine sources. Dietary intakes of methylmercury from certain fish have been hypothesized to increase the risk of CHD.

Objective

To investigate the relationship between 30 d fish frequency consumption (assessed by FFQ), total blood Hg concentrations and risk markers of CHD in women aged 16–49 years participating in the National Health and Nutrition Examination Survey 1999–2002.

Design

Multiple linear regression analyses were used to test (i) the relationships between 30 d fish frequency consumption and five CHD risk markers, i.e. HDL cholesterol (HDL-C), LDL cholesterol, total cholesterol, TAG and C-reactive protein (CRP); and (ii) if total blood Hg attenuated any associations between fish consumption and CHD risk markers in non-pregnant, non-diabetic females aged 16–49 years.

Results

Total 30 d fish frequency consumption was negatively associated with CRP (b = −0·10, 95 % CI −0·19, −0·02, P = 0·015) and positively associated with HDL-C (b = 1·40, 95 % CI 0·31, 2·50, P = 0·014). Adjustment for other risk factors did not significantly attenuate the associations. Despite the collinearity between fish and Hg, there is a protective association between fish intake and CHD risk factors.

Conclusions

The levels of DHA + EPA and other nutrients in fish may be adequate to offset the hypothesized risks of heart disease related to ingesting Hg from fish.

Type
Research Paper
Copyright
Copyright © The Authors 2008

Fish and fish oils containing the n-3 fatty acids DHA and EPA have been shown to have cardioprotective attributes in both healthy individuals and those at high risk of CHD(Reference Weber and Raederstorff1Reference Roche and Gibney4). The chief dietary sources of DHA and EPA are fatty fish such as mackerel, lake trout, herring, tuna, sardines and salmon, as well as dietary supplements. Consumption of DHA and EPA and fish containing these fatty acids has been shown to reduce blood lipid concentrations of LDL cholesterol (LDL-C), total cholesterol (TC) and TAG, and to raise concentrations of HDL cholesterol (HDL-C)(Reference Lopez-Garcia, Schulze, Manson, Meigs, Albert, Rifai, Willett and Hu5Reference Agren, Hanninen and Julkunen7). n-3 Fatty acid intake is also associated with a reduction in plasma biomarkers of inflammation such as C-reactive protein (CRP)(Reference Lopez-Garcia, Schulze, Manson, Meigs, Albert, Rifai, Willett and Hu5). The physiological effects of DHA and EPA include lowering plasma TAG concentrations, inhibiting plaque formation, decreasing platelet aggregation and reducing arrhythmias(Reference Konig, Bouzan, Cohen, Connor, Kris-Etherton, Gray, Lawrence, Savitz and Teutsch8Reference Harris and Bulchandani10).

Fish also contains methylmercury (MeHg), an environmental contaminant derived from industrial waste and the burning of fossil fuels. MeHg makes its way into streams, lakes and oceans where it becomes incorporated into the food chain of marine animals(11). The main focus of MeHg has been its effects on neurodevelopment in children(Reference Clarkson, Magos and Myers1214). To monitor exposure to MeHg, the National Health and Nutrition Examination Survey (NHANES) measured blood and hair Hg concentrations in the sensitive populations of children and women of childbearing age. There is more recent evidence that, in addition to its effects on neurodevelopment in children, MeHg may increase the risk of CHD by promoting the formation of free radicals and compromising the function of antioxidants that neutralize these agents(Reference Guallar, Sanz-Gallardo, van’t Veer, Bode, Aro, Gómez-Aracena, Kark, Riemersma, Martín-Moreno and Kok15). Therefore, it is possible that consuming fish contaminated with MeHg may increase the risk of CHD.

The hypothesis that MeHg attenuates associations between fish consumption and CHD risk markers remains unproven. A review of seven epidemiological studies conducted to date (five in men, one in women and one with both men and women) suggests an association between MeHg exposure and greater CHD risk, including acute myocardial infarction, but none of these studies addressed the combined effect of fish or n-3 fatty acid intake and MeHg on risk markers of CHD(Reference Guallar, Sanz-Gallardo, van’t Veer, Bode, Aro, Gómez-Aracena, Kark, Riemersma, Martín-Moreno and Kok15Reference von Schacky, Angerer, Kothny, Theisen and Mudra19). Therefore the objective of the current study was to investigate relationships between 30 d frequency of fish intake, total blood Hg concentrations and risk markers of CHD in women aged 16–49 years who participated in NHANES 1999–2002. Indicators of CHD risk examined include blood concentrations of TC, LDL-C, HDL-C, TAG and the inflammatory marker CRP.

Materials and methods

The NHANES 1999–2002 database was used to investigate relationships between fish consumption, total blood Hg and risk markers of CHD in women aged 16–49 years. The NHANES is a stratified, multistage probability sample of the civilian non-institutionalized US population which interviews approximately 5000 people per survey year. Respondents are interviewed in their homes and also complete a health examination component in mobile examination centres. Low-income persons, adolescents 12–19 years of age, African-Americans and Mexican-Americans are over-sampled(20).

Independent variables

Fish intake of women aged 16–49 years was assessed as the total number of fish meals reported consumed in a 30 d fish FFQ in the NHANES 1999–2002. The NHANES participants did not provide data on the portion sizes of fish reported consumed in the fish FFQ. In the present analysis, total fish frequency of consumption data for women aged 16–49 years was grouped into four categories: 0, 1–4, 5–8 or ≥9 times/30 d. Shellfish were omitted from the analysis because they are low in Hg. For individuals in each of the four fish consumption categories, mean blood lipids, CRP, total blood Hg and nutrient concentrations along with descriptive statistics for selected demographic variables were calculated. The summary statistics were derived using the 4-year statistical weights and adjusting for the statistical design of the survey as recommended by the NHANES analytical guidelines(20).

Dietary exposure to Hg was evaluated in this study using total blood Hg concentrations measured in NHANES 1999–2002 female participants aged 16–49 years.

Dependent variables

The dependent variables of interest in this study were TC, HDL-C and CRP. Because TAG data were available for a limited number of participants in the NHANES 1999–2002, a separate sensitivity analysis was conducted using serum TAG and LDL-C concentrations.

Covariate variables

Covariates were included in the regression models to take into account demographic, lifestyle and nutritional factors. Demographic and lifestyle variables were self-reported unless otherwise noted and included age (grouped for the present analysis into four categories: 16–19, 20–29, 30–39 and 40–49 years), ethnicity (non-Hispanic white, non-Hispanic black, Mexican-American, other Hispanic and other), BMI (calculated as measured weight in kilograms divided by the square of measured height in metres), educational attainment (less than high school, high school or General Educational Development, greater than high school), physical activity (separated into low, moderate and heavy levels of daily activity), prescription drug use (anti-inflammatory or lipid-lowering), serum cotinine concentrations (a measure of exposure to tobacco) and medical history of heart disease (physician-diagnosed diseases). The diagnoses of congestive heart failure, CHD, angina, heart attack or stroke were categorized as heart disease. Intake of individual nutrients was derived from the 24 h dietary recall interview and was based on calculations by the National Center for Health Statistics (NCHS). Nutrient intakes (energy, fibre, MUFA, SFA, TC, vitamin C, alcohol and Se) were treated as continuous variables in all models. Nutrients that were omitted from the models because they were not significantly associated with the dependent variables or caused collinearity included protein, carbohydrate, total fat and total PUFA.

Cohort for analysis

The sample for the present study was limited to women for whom data for the independent and dependent variables of interest were available. The NHANES 1999–2002 dataset contains a total of 10 790 women, including 4084 women aged 16–49 years. Our sample was further restricted to women having measurements for total blood Hg (n 3637), CRP (n 3608), 24 h dietary recall interview (n 3458), 30 d fish FFQ (n 3456), TC (n 3434) and HDL-C (n 3435). LDL-C and TAG data were collected on only a subset of women, reducing the sample size to 1726 prior to testing for confounding variables.

Women were excluded from all analyses if they reported on the demographic questionnaire that they were pregnant (n 704), if a doctor had told them they were diabetic (n 104) or if their 24 h dietary recall interview was coded by NCHS as unreliable (n 207). This occurred if >25 % of foods reported consumed had missing descriptive information, >15 % of foods had missing quantities eaten or if a meal did not include at least one identified food. In addition, 211 women who did not have 4-year statistical weights were excluded. The numbers excluded are not mutually exclusive. After these adjustments were made, the sample size was reduced to 1245 women for the analysis of the major dependent variables, while 577 of the 1245 eligible women were included in the sensitivity analyses for LDL-C and TAG.

Statistical methods

The STATA statistical software package version 7·0 (Stata Corporation, College Station, TX, USA) was used to conduct all statistical analyses including the univariate summaries and multiple regression models. All estimates were derived using the 4-year statistical weights based upon mobile examination centre participation and adjusting for survey design. Regression analyses were conducted using the survey regression commands in STATA. The distributions of continuous variables were tested for normality using the Shapiro–Wilk test and data were transformed to achieve normality when necessary. Prior to analysis, log transformations were done on CRP and total blood Hg values, and a square-root transformation was performed on the total reported 30 d fish food frequency values(Reference Bland and Altman21).

The following hypotheses were tested:

  1. 1. Fish intake is negatively associated with TC and CRP concentrations, and positively associated with HDL-C and total blood Hg concentrations.

  2. 2. Total blood Hg will attenuate any associations demonstrated between fish consumption and CHD risk markers.

We tested the effects of dietary 24 h intakes of n-3 PUFA on TC, CRP and HDL-C and the effects of total blood Hg on these associations; however, all results were not significant and thus are excluded from the current paper.

The sample was stratified into categories defined by total frequency of fish consumption in the past 30 d (0, 1–4, 5–8 and ≥9 times/30 d). Means of all continuous variables for each of the three fish-consuming groups were compared with those of the fish non-consuming group using the adjusted Wald test.

The associations between total frequency of fish consumption in the past 30 d, blood lipids and CRP concentrations were tested using multiple linear regression analyses. The initial models (Model 1) adjusted for energy intake and age (separated by decade, with women aged 16–19 years serving as the reference population). To adjust for potential confounding, subsequent multivariate models included known CHD risk factors.

Specifically, Model 2 adjusted for the variables in Model 1 as well as for lifestyle, dietary habits and medical history of arthritis and CHD. Model 2 also included adjustments for prescription drug use (anti-inflammatory or lipid-lowering), ethnicity, educational attainment (indicator variables) and continuous variables such as BMI, smoking (measured as serum cotinine) and 24 h dietary recall interview intakes of total energy, fibre, SFA, MUFA, vitamin C, Se and alcohol (continuous variables).

Model 3 included total blood Hg concentrations (log) in addition to the variables included in Model 2. The analyses were conducted separately for each of the blood lipids and CRP. The sample for all multiple linear regression analyses was limited to women aged 16–49 years with valid data for all variables included in Model 3 (n 1245).

Results

Characteristics of the population

Demographic and lifestyle characteristics, nutrient intakes and blood biomarkers of CHD risk by fish consumption category are summarized in Tables 13. The 1245 non-pregnant women that constituted the study sample had an average age of 32·5 (se 0·4) years and an average BMI of 26·3 (se 0·22) kg/m2. The reported average daily energy intake of the sample was slightly less than 8500 kJ/d (2000 kcal/d), i.e. 8341 (se 106·7) kJ/d. The study sample reported an average of 2·9 (se 0·13) fish meals over 30 d (less than one fish meal per week) and had an average DHA + EPA intake of 0·1 (se 0·01) g calculated from the 24 h dietary recall interview, confirming a low fish intake.

Table 1 Characteristics of the study sample by fish consumption group: sub-sample of women aged 16–49 years participating in the National Health and Nutrition Examination Survey 1999–2002

Summaries are presented as means with their standard error for continuous variables or as percentage in each category for categorical variables.

*Adjusted Wald test to test the accumulated difference of all fish consumers v. fish non-consumers (NS, P > 0·05).

†Little or no regular recreation, sport or physical activity and avoids walking or exertion.

‡Little or no regular recreation, sport or physical activity but walks for pleasure and occasionally exercise; participating regularly in recreation or work requiring modest physical activity for 10 to 60 min/week.

§Participating regularly in recreation or work requiring modest physical activity for more than 60 min/week; participating regularly in heavy physical activity for less than 30 min/week; participating regularly in heavy physical activity for 30–60 min/week; participating regularly in heavy physical activity for 1–3 h/week; participating regularly in heavy physical activity for more than 3 h/week.

Table 2 Nutrient intake profile of the study sample by fish consumption group: sub-sample of women aged 16–49 years participating in the National Health and Nutrition Examination Survey (NHANES) 1999–2002

*Nutrients calculated by NHANES from the 24 h dietary recall interview.

†Adjusted Wald test to test the accumulated difference of all fish consumers v. fish non-consumers (NS, P > 0·05).

Table 3 Blood lipids, C-reactive protein and total blood mercury concentrations by fish consumption group: sub-sample of women aged 16–49 years participating in the National Health and Nutrition Examination Survey 1999–2002

TC, total cholesterol; HDL-C, HDL cholesterol; LDL-C, LDL cholesterol; CRP, C-reactive protein.

*n 195 for LDL-C and n 213 for TAG.

n 288 for LDL-C and n 304 for TAG.

n 64 for LDL-C and n 67 for TAG.

§n 30 for LDL-C and n 32 for TAG.

||Adjusted Wald test to test the accumulated difference of all fish consumers v. fish non-consumers (NS, P > 0·05).

The majority of the sample of women aged 16–49 years consumed fish 1–4 times/30 d. Study participants who classified themselves as ‘other Hispanic’ and ‘other’ had the greatest percentage of regular fish consumers (fish ≥9 times/30 d; 10 %). The data also suggested that fish consumers were less likely to smoke and to be exposed to second-hand smoke (Table 1).

Of the blood lipids tested, HDL-C concentrations were higher in the fish consumption groups compared with the fish non-consumers (P = 0·0011), while no differences existed across groups for any of the other lipids or CRP (Table 3). The women in this sample had desirable average blood lipid profiles; TC was 188·4 (se 1·4) mg/dl and HDL-C was 55·7 (se 0·7) mg/dl. The average CRP was 0·36 (se 0·02) mg/l, below the value of 1 mg/l which indicates inflammation(22).

Total blood Hg concentrations increased gradually for each fish consumption group, with fish consumers having significantly greater concentrations than fish non-consumers (Table 3). Regular fish consumers (≥9 times/30 d) had a seven-fold greater total blood Hg concentration than fish non-consumers (4·2 (se 0·7) v. 0·6 (se 0·05) μg/l).

The associations between total blood log-transformed Hg concentrations and demographic variables were analysed using multiple linear regression analyses (Table 4). Women in the 30–39 years and 40–49 years age categories had significantly greater total blood Hg concentrations than women aged 16–19 years. Compared with the other race/ethnicity groups, non-Hispanic blacks had significantly greater total blood Hg concentrations (b = 0·36, 95 % CI 0·14, 0·58). After adjusting for age, energy, BMI, education, ethnicity, physical activity, prescription drug use (anti-inflammatory or lipid-lowering), serum cotinine, vitamin C, Se, fibre, alcohol, MUFA and SFA, total blood Hg concentrations were significantly higher in all fish consumption groups compared with the fish non-eaters, indicating a high correlation between fish intake and total blood Hg concentrations.

Table 4 Regression model for y = log(total blood Hg)Footnote *: sub-sample of women aged 16–49 years participating in the National Health and Nutrition Examination Survey 1999–2002

* Adjusted for age, energy, BMI, education, ethnicity, physical activity, prescription drug use (anti-inflammatory or lipid-lowering), serum cotinine, vitamin C, Se, fibre, alcohol, MUFA and SFA.

Fish consumption, C-reactive protein and lipid profile

Initial analyses adjusting for age and energy demonstrated significant negative associations between total 30 d frequency of fish consumption and CRP concentrations (b = −0·10, 95 % CI −0·19, −0·02) and significant positive associations with HDL-C concentrations (b = 1·40, 95 % CI 0·31, 2·50). After adjustments for known risk factors for CHD (BMI, educational attainment, ethnicity, self-reported physical activity, self-reported use of anti-inflammatory or lipid-lowering prescription drugs, serum cotinine, vitamin C, Se, fibre, alcohol, MUFA and SFA), there were no changes in the associations between 30 d frequency of fish consumption and CRP, but some attenuation with HDL-C concentrations (Table 5). There were no associations between 30 d frequency of fish consumption and TC and LDL-C in all models (P > 0·05).

Table 5 Summaries of regression models of CHD risk factors on 30 d fish frequency consumption (g/person per d): sub-sample of women aged 16–49 years participating in the National Health and Nutrition Examination Survey 1999–2002

CRP, C-reactive protein; HDL-C, HDL cholesterol; TC, total cholesterol; LDL-C, LDL cholesterol; NS, P > 0·05.

*Adjusted for age and energy.

†Adjusted for Model 1 variables plus BMI, education, ethnicity, physical activity, prescription drug use (anti-inflammatory or lipid-lowering), serum cotinine, vitamin C, Se, fibre, alcohol, MUFA and SFA.

‡Adjusted for Model 2 variables plus log(total blood Hg) and the interaction term of log(total blood Hg) × square-root of fish frequency.

Sensitivity analyses conducted on the subset of women aged 16–49 years with measured data for TAG (n 577) demonstrated that after adjustment for age and other known CHD risk factors, 30 d frequency of fish consumption was negatively associated with TAG concentrations (b = −4·20, 95 % CI −8·00, −0·33; Table 5).

Fish consumption, C-reactive protein, blood lipids and total blood Hg

The addition of total blood Hg in Model 3 for CRP did not change the significant inverse association between fish consumption and CRP concentrations (b = −0·10, 95 % CI −0·18, −0·03; Table 5). To test this effect and control for total blood Hg, we calculated the average CRP concentration by fish non-consumer or fish consumer group and tertile of total blood Hg concentration (Table 6). Despite the findings that CRP concentrations among infrequent fish consumers were higher than for other groups (Table 3), this analysis, which controlled for total blood Hg, showed that as Hg concentrations increased there was no significant change in CRP concentrations or in the association between CRP and fish consumption. This was most likely due to the categorization of all fish consumers into one group. The unweighted sample sizes were not adequate to conduct the analysis broken down by fish consumption levels.

Table 6 Average C-reactive protein concentration by total blood mercury tertile and fish consumers v. fish non-consumers (mg/dl): sub-sample of women aged 16–49 years participating in the National Health and Nutrition Examination Survey (NHANES) 1999–2002

The addition of total blood Hg in the Model 3 regression analyses showed attenuation of the association between total 30 d frequency of fish consumption and HDL-C concentrations to non-significant levels (b = 0·48, 95 % CI −0·60, 1·60, P = 0·372; Table 5). To test this attenuation effect we calculated the mean HDL-C for fish non-consumers and fish consumers separated by tertile of total blood Hg concentration. Analyses of the association between fish consumption and HDL-C levels, controlling for Hg levels, showed that that the difference in HDL-C concentrations between fish non-consumers and consumers across Hg tertiles did not decrease, implying that total blood Hg did not diminish the positive association between fish intake and HDL-C (Table 7).

Table 7 Average HDL cholesterol concentration by total blood mercury tertile and fish consumers v. fish non-consumers (mg/l): sub-sample of women aged 16–49 years participating in the National Health and Nutrition Examination Survey (NHANES) 1999–2002

Addition of total blood Hg in Model 3 for the relationship between total frequency of fish consumption and TAG resulted in a non-significant association between total frequency of fish and TAG concentrations (b = −2·30, 95 % CI −5·90, 1·20, P = 0·183; Table 5). A follow-up analysis to test this effect controlling for total blood Hg (i.e. calculated average TAG by tertile of total blood Hg and fish consumption category) showed a decrease in TAG for each tertile of total blood Hg, again demonstrating the high collinearity between fish consumption and total blood Hg concentrations (103·8, 102·4 and 94·6mg/dl per tertile of total blood Hg). Despite the high collinearity, the TAG concentrations for fish consumers were consistently lower than those of fish non-consumers (99·7 v. 102·3 mg/dl).

Discussion

The results of the present study suggest an association between frequent fish intake and selected risk markers of CHD (HDL-C, TAG and CRP) in women aged 16–49 years. As the total 30 d frequency of fish consumption increased, concentrations of HDL-C increased while concentrations of TAG and CRP decreased. When total blood Hg was introduced into the regression models, the significant associations between frequent fish intake and CRP remained the same although the association with HDL-C was diminished. Further analyses controlling for total blood Hg demonstrated that this latter effect is most likely due to collinearity between fish intake and total blood Hg. There was no longer an association between fish consumption and TAG once the total blood Hg and fish interaction was added to the model. This may be attributed to the small sample size since the TAG analyses were conducted on a subset of the population, or it may be possible that adding Hg to the model may have led to over-controlling for variables as Hg and fish consumption are highly correlated. No significant associations were seen between fish intake and either LDL-C or TC concentrations.

Consumption of DHA and EPA and fish containing these fatty acids has been shown to reduce blood concentrations of LDL-C, TC and TAG and to raise concentrations of HDL-C(Reference Lopez-Garcia, Schulze, Manson, Meigs, Albert, Rifai, Willett and Hu5Reference Agren, Hanninen and Julkunen7). The average DHA + EPA intake in our study (0·1 g/d) was much lower in comparison to that of other studies. Our results agree with other studies which have shown that fish intake or markers of fish intake (plasma PUFA) do not significantly impact LDL-C or TC levels(Reference Rissanen, Voutilainen, Nyyssönen, Lakka and Salonen17, Reference Hallgren, Hallmans, Jansson, Marklund, Huhtasaari, Schutz, Strömberg, Vessby and Skerfving23). The 24 h calculated DHA + EPA intake in our study was also less than the American Heart Association (AHA) recommendation (at least 0·5–1·0 g of n-3 fatty acids daily to achieve cardioprotective effects), which may explain the lack of association in the models where HDL-C, LDL-C and TC were the independent variables(Reference Kris-Etherton, Harris and Appel24). When 24 h dietary intake of DHA + EPA was used as a marker of fish consumption there were no associations with risk markers of CHD. The lack of association may be due to the fact that fish intake is variable and a single 24 h recall does not capture foods that are eaten on an irregular basis.

Organic (methyl) Hg is present in fish due to its uptake from environmental sources(11). In man, the sole source of exposure to organic Hg is the consumption of fish and sea mammals(Reference Clarkson, Magos and Myers12). Research has linked Hg ingestion from fish to increased risk of CHD in men(Reference Guallar, Sanz-Gallardo, van’t Veer, Bode, Aro, Gómez-Aracena, Kark, Riemersma, Martín-Moreno and Kok15Reference Rissanen, Voutilainen, Nyyssönen, Lakka and Salonen17, Reference Hallgren, Hallmans, Jansson, Marklund, Huhtasaari, Schutz, Strömberg, Vessby and Skerfving23, Reference Virtanen, Voutilainen, Rissanen, Mursu, Tuomainen, Korhonen, Valkonen, Seppanen, Laukkanen and Salonen25). In our study of women aged 16–49 years we found a protective association between fish intake and CHD risk factors. Analyses of the association between fish consumption and HDL-C levels, controlling for Hg levels, showed that the difference in HDL-C concentrations between fish non-consumers and consumers across Hg tertiles did not decrease, implying that Hg did not diminish the positive association between fish intake and HDL-C. Inconsistent relationships between biomarkers of Hg and CHD risk have been reported, perhaps due to differences in the ages of the study subjects, frequency of fish consumption among populations studied, type of fish consumed and health status of the study samples(Reference Yoshizawa, Rimm, Morris, Spate, Hsieh, Spiegelman, Stampfer and Willett18, Reference Hallgren, Hallmans, Jansson, Marklund, Huhtasaari, Schutz, Strömberg, Vessby and Skerfving23, Reference Ahlqwist, Bengtsson, Lapidus, Gergdahl and Schütz26).

CRP is a predictor of CHD risk(Reference Ridker, Hennekens, Buring and Rifai27) and is affected by numerous lifestyle variables. In general, individuals with elevated CRP concentrations tend to smoke, have high blood pressure, are overweight and fail to exercise(Reference Ridker28). A few studies have evaluated the effects of dietary intakes of DHA + EPA on CRP concentrations and other biomarkers of inflammation in different samples of subjects and have produced varying results(Reference Vega-Lopez, Kaul, Devaraj, Cai, German and Jialal29, Reference Stark and Holub30).

The present cross-sectional study extends the results of previous studies using the NHANES data set (1999–2000). The average total blood Hg was higher for the 1245 women (aged 16–49 years) in the current study than Hg levels reported from the same data set using a different sample of 1709 women (1·6 v. 1·02 μg Hg/l)(Reference Schober, Sinks and Jones31). Schober et al. also reported that women who ate 3 or more servings of fish (in the past 30 d) had four-fold greater geometric mean Hg concentrations compared with women not consuming fish(Reference Schober, Sinks and Jones31). A second study that analysed hair Hg data reported three-fold higher hair Hg concentrations in frequent fish consumers (≥3 times in the past 30 d) than in non-consumers(Reference McDowell, Dillon and Osterloh32). In the current study, there was a seven-fold difference in total blood Hg concentration between women who consumed fish ≥9 times/30 d and the fish non-consumers. The differences between studies are most likely due to how the fish consumption groups are stratified and the sample sizes within these groups.

When total blood Hg data were analysed by race/ethnicity, the results of the current study are consistent with two recent reports that analysed relationships between calculated organic blood Hg (rather than total blood Hg concentrations), hair Hg concentrations and fish intake during the first two years of the NHANES (1999–2000)(Reference McDowell, Dillon and Osterloh32, Reference Mahaffey, Clickner and Bodurow33). The lowest blood organic Hg concentrations were in Mexican-Americans and the highest concentrations were in participants who designated themselves in the ‘other’ racial/ethnic category, which included Asians, Native Americans and Pacific Islanders(Reference Mahaffey, Clickner and Bodurow33). Mahaffey et al. reported that women aged 30–49 years have blood organic Hg concentrations 1·5 times greater than women aged 16–29 years(Reference Mahaffey, Clickner and Bodurow33). Similarly, we found a two-fold difference in total blood Hg concentrations between women aged 16–19 and 30–39 years (1·0 (se 0·1) v. 2·0 (se 0·3) μg/l).

Only fifty-seven women in our sample reported consuming fish ≥9 times in the past 30 d, a frequency similar to the AHA recommendation of eating fish at least twice weekly. Most of the women were either fish non-consumers (n 441) or light fish consumers (1–4 times/30 d, n 166), and thus failed to meet the AHA guideline for fish.

Our study was limited to a sub-sample of women aged 16–49 years in the NHANES (1999–2002) data set for whom total blood Hg data were available. Therefore, these results cannot be generalized to other population groups. Inherent to a large cross-sectional study is the temporality of the data; therefore, in the present observational and cross-sectional study we cannot exclude the possibility that the association between fish and CHD risk factors may be due to unmeasured variables. However, we controlled for all variables currently known to affect risk of CHD. Alternatively, the study would have been strengthened if actual disease endpoints could have been used; however, the age group of the study sample was prohibitive of such analysis.

n-6 and n-3 PUFA compete during metabolism and an excessive intake of n-6 fatty acids may attenuate the cardioprotective benefits normally seen with n-3 PUFA. In a large prospective cohort study, Mozaffarian et al. investigated the joint effects of different PUFA on the risk of CHD in men. These researchers saw benefits in the combination of plant- and marine-based n-3 PUFA on CHD risk independent of n-6 PUFA consumption. They concluded that non-marine-based n-3 PUFA are beneficial in reducing risk of CHD, especially when populations do not have easy access or availability to marine sources(Reference Mozaffarian, Ascherio, Hu, Stampfer, Willett, Siscovick and Rimm34). The interplay of plant-derived and marine-derived n-3 fatty acids was not analysed in the current study.

The results of the present study would have been strengthened if data on LDL-C and TAG had been available for more subjects, since both of these lipid biomarkers may be affected by n-3 PUFA(Reference Clarkson, Magos and Myers12). However, the analysis on a subpopulation did not show any association between n-3 fatty acids and these blood lipids. Other inflammatory biomarkers such as IL-6 or other cytokines may be better indicators of CHD risk than CRP, but these data were not available in the current NHANES surveys.

A strength of the current study is that a 30 d frequency of fish intake was used which provides a good estimate of habitual intake. Also, the current study included healthy women of childbearing age, whereas studies that examined the joint association between fish intake, MeHg and CHD only included men and older women. Finally, because the NHANES data set is large, we were able to control for a number of demographic and lifestyle variables.

Summary

The results of the present study provide further support for recommending regular fish consumption along with maintaining a healthy lifestyle (e.g. not smoking and getting daily moderate exercise) as a way of reducing the risk of CHD. The effect of Hg on biomarkers of inflammation is unclear. Based on this study and others, it appears that the levels of Hg in fish consumed by this population may not be high enough to counteract the positive association between fish intake and CHD risk factors.

Acknowledgements

K.M.S., the lead author, was responsible for the article’s conception and design, acquisition of data, analysis and interpretation of data, drafting and critical revision of the manuscript, and the statistical analyses. N.R.S., the lead advisor, was also responsible for the conception and design, interpretation of data, drafting and critical revisions of the manuscript. L.M.B. did extensive reviews of the manuscript, statistical methodology and data interpretation. M.K. helped in critical review of the study design and revising the manuscript. There are no conflicts of interest. No funding was received for this project.

References

1.Weber, P & Raederstorff, D (2000) Triglyceride-lowering effect of omega-3 LC-polyunsaturated fatty acids – a review. Nutr Metab Cardiovasc Dis 10, 2837.Google ScholarPubMed
2.Calder, P (2004) n-3 Fatty acids and cardiovascular disease: evidence explained and mechanisms explored. Clin Sci (Lond) 107, 111.CrossRefGoogle ScholarPubMed
3.Oomen, CM, Feskens, EJ, Räsänen, L, Fidanza, F, Nissinen, AM, Menotti, A, Kok, FJ & Kromhout, D (2000) Fish consumption and coronary heart disease mortality in Finland, Italy and the Netherlands. Am J Epidemiol 151, 9991006.CrossRefGoogle ScholarPubMed
4.Roche, H & Gibney, M (2000) Effects of long-chain n-3 polyunsaturated fatty acids on fasting and postprandial triacylglycerol metabolism. Am J Clin Nutr 71, Suppl., 232S237S.CrossRefGoogle ScholarPubMed
5.Lopez-Garcia, E, Schulze, MB, Manson, JE, Meigs, JB, Albert, CM, Rifai, N, Willett, WC & Hu, FB (2004) Consumption of (n-3) fatty acids is related to plasma biomarkers of inflammation and endothelial activation in women. J Nutr 134, 18061811.CrossRefGoogle Scholar
6.Kelley, DS, Siegel, D, Vemuri, M & Mackey, BE (2007) Docosahexaenoic acid supplementation improves fasting and postprandial lipid profiles in hypertriglyceridemic men. Am J Clin Nutr 86, 324333.CrossRefGoogle ScholarPubMed
7.Agren, JJ, Hanninen, O & Julkunen, A (1996) Fish diet, fish oil and docosahexaenoic acid rich oil lower fasting and postprandial plasma lipid levels. Eur J Clin Nutr 50, 765771.Google ScholarPubMed
8.Konig, A, Bouzan, C, Cohen, J, Connor, W, Kris-Etherton, P, Gray, G, Lawrence, RS, Savitz, DA & Teutsch, SM (2005) A quantitative analysis of fish consumption and coronary heart disease mortality. Am J Prev Med 29, 335346.CrossRefGoogle ScholarPubMed
9.Jong, M, Hofker, M & Havekes, L (1999) Role of ApoCs in lipoprotein metabolism: functional differences between ApoCI, ApoC2, and ApoC3. Aterioscler Thromb Vasc Biol 19, 472484.CrossRefGoogle Scholar
10.Harris, W & Bulchandani, D (2006) Why do omega-3 fatty acids lower serum triglycerides? Curr Opin Lipidol 17, 387393.CrossRefGoogle ScholarPubMed
11. Agency for Toxic Substances and Disease Registry (1999) ToxFAQs™ for mercury. http://www.atsdr.cdc.gov/tfacts46.html (accessed September 2008).Google Scholar
12.Clarkson, TW, Magos, L & Myers, GJ (2003) The toxicology of mercury – current exposures and clinical manifestations. N Engl J Med 349, 17311737.CrossRefGoogle ScholarPubMed
13.National Research Council (2000) Toxicological Effects of Methyl Mercury. Washington, DC: National Academy Press.Google Scholar
14. US Department of Health and Human Services and US Environmental Protection Agency (2004) FDA and EPA Announce the Revised Consumer Advisory on Methylmercury in Fish. http://www.fda.gov/bbs/topics/news/2004/NEW01038.html (accessed September 2008).Google Scholar
15.Guallar, E, Sanz-Gallardo, MI, van’t Veer, P, Bode, P, Aro, A, Gómez-Aracena, J, Kark, JD, Riemersma, RA, Martín-Moreno, JM & Kok, FJ; Heavy Metals and Myocardial Infarction Study Group (2002) Mercury, fish oils, and the risk of myocardial infarction. N Engl J Med 347, 17471754.CrossRefGoogle ScholarPubMed
16.Salonen, JT, Nyyssönen, K & Salonen, R (1995) Fish intake and the risk of coronary disease. N Engl J Med 333, 937.Google ScholarPubMed
17.Rissanen, T, Voutilainen, S, Nyyssönen, K, Lakka, TA & Salonen, JT (2000) Fish oil-derived fatty acids, docosahexaenoic acid and docosapentaenoic acid, and the risk of acute coronary events: the Kuopio ischaemic heart disease risk factor study. Circulation 102, 26772679.CrossRefGoogle ScholarPubMed
18.Yoshizawa, K, Rimm, EB, Morris, JS, Spate, VL, Hsieh, CC, Spiegelman, D, Stampfer, MJ & Willett, WC (2002) Mercury and the risk of coronary heart disease in men. N Engl J Med 347, 17551760.CrossRefGoogle ScholarPubMed
19.von Schacky, C, Angerer, P, Kothny, W, Theisen, K & Mudra, H (1990) The effect of dietary omega-3 fatty acids on coronary atherosclerosis. A randomized double-blind, placebo-controlled trial. Ann Intern Med 130, 554562.CrossRefGoogle Scholar
20. National Center for Health Statistics (2008) National Health and Nutrition Examination Survey. Data Sets and Related Documentation. http://www.cdc.gov/nchs/about/major/nhanes/datalink.htm (accessed September 2008).Google Scholar
21.Bland, J & Altman, D (1996) Transforming data. BMJ 312, 770.CrossRefGoogle ScholarPubMed
22. American Heart Association (2006) Learn and Live. Inflammation, Heart Disease and Stroke: The Role of C-Reactive Protein. http://www.americanheart.org/presenter.jhtml?identifier=4648 (accessed September 2008).Google Scholar
23.Hallgren, C, Hallmans, G, Jansson, J, Marklund, S, Huhtasaari, F, Schutz, A, Strömberg, U, Vessby, B & Skerfving, S (2001) Markers of high fish intake are associated with decreased risk of a first myocardial infarction. Br J Nutr 86, 397404.CrossRefGoogle ScholarPubMed
24.Kris-Etherton, P, Harris, W & Appel, L (2002) AHA Scientific Statement. Fish consumption, fish oil, omega-3 fatty acids and cardiovascular disease. Circulation 106, 27472757.CrossRefGoogle Scholar
25.Virtanen, JK, Voutilainen, S, Rissanen, TH, Mursu, J, Tuomainen, TP, Korhonen, MJ, Valkonen, VP, Seppanen, K, Laukkanen, JA & Salonen, JT (2005) Mercury, fish oils, and risk of acute coronary events and cardiovascular disease, coronary heart disease, and all-cause mortality in men in eastern Finland. Aterioscler Thromb Vasc Biol 25, 228233.CrossRefGoogle ScholarPubMed
26.Ahlqwist, M, Bengtsson, C, Lapidus, L, Gergdahl, IA & Schütz, A (1999) Serum mercury concentration in relation to survival, symptoms, and diseases: results from the prospective population study of women in Gothenburg, Sweden. Acta Odontol Scand 57, 168174.Google ScholarPubMed
27.Ridker, PM, Hennekens, CH, Buring, JE & Rifai, N (2000) C-reactive protein and other markers of inflammation in the prediction of cardiovascular disease in women. N Engl J Med 342, 836843.CrossRefGoogle Scholar
28.Ridker, PM (2003) C-reactive protein. A simple test to help predict risk of heart attack and stroke. Circulation 108, e81e85.CrossRefGoogle ScholarPubMed
29.Vega-Lopez, S, Kaul, N, Devaraj, S, Cai, RY, German, B & Jialal, I (2004) Supplementation with omega3 polyunsaturated fatty acids and all-rac α-tocopherol alone and in combination failed to exert an anti-inflammatory effect in human volunteers. Metabolism 53, 236240.CrossRefGoogle ScholarPubMed
30.Stark, KD & Holub, BJ (2004) Differential eicosapentaenoic acid elevations and altered cardiovascular disease risk factor responses after supplementation with docosahexaenoic acid in postmenopausal women receiving and not receiving hormone replacement therapy. Am J Clin Nutr 79, 765773.CrossRefGoogle Scholar
31.Schober, SE, Sinks, TH, Jones, RL et al. (2003) Blood mercury levels in US children and women of childbearing age, 1999–2000. JAMA 289, 16671674.CrossRefGoogle ScholarPubMed
32.McDowell, MA, Dillon, CF, Osterloh, J et al. (2004) Hair mercury levels in US children and women of childbearing age: reference range data from NHANES 1999–2000. Environ Health Perspect 112, 11651171.CrossRefGoogle ScholarPubMed
33.Mahaffey, KR, Clickner, RP & Bodurow, CC (2003) Blood organic mercury and dietary mercury intake: National Health and Nutrition Examination Survey, 1999 and 2000. Environ Health Perspect 112, 562570.CrossRefGoogle Scholar
34.Mozaffarian, D, Ascherio, A, Hu, FB, Stampfer, MJ, Willett, WC, Siscovick, DS & Rimm, EB (2005) Interplay between different polyunsaturated fatty acids and risk of coronary heart disease in men. Circulation 111, 157164.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Characteristics of the study sample by fish consumption group: sub-sample of women aged 16–49 years participating in the National Health and Nutrition Examination Survey 1999–2002

Figure 1

Table 2 Nutrient intake profile of the study sample by fish consumption group: sub-sample of women aged 16–49 years participating in the National Health and Nutrition Examination Survey (NHANES) 1999–2002

Figure 2

Table 3 Blood lipids, C-reactive protein and total blood mercury concentrations by fish consumption group: sub-sample of women aged 16–49 years participating in the National Health and Nutrition Examination Survey 1999–2002

Figure 3

Table 4 Regression model for y = log(total blood Hg)*: sub-sample of women aged 16–49 years participating in the National Health and Nutrition Examination Survey 1999–2002

Figure 4

Table 5 Summaries of regression models of CHD risk factors on 30 d fish frequency consumption (g/person per d): sub-sample of women aged 16–49 years participating in the National Health and Nutrition Examination Survey 1999–2002

Figure 5

Table 6 Average C-reactive protein concentration by total blood mercury tertile and fish consumers v. fish non-consumers (mg/dl): sub-sample of women aged 16–49 years participating in the National Health and Nutrition Examination Survey (NHANES) 1999–2002

Figure 6

Table 7 Average HDL cholesterol concentration by total blood mercury tertile and fish consumers v. fish non-consumers (mg/l): sub-sample of women aged 16–49 years participating in the National Health and Nutrition Examination Survey (NHANES) 1999–2002