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n-3 Fatty acid intake from marine food products among Quebecers: comparison to worldwide recommendations

Published online by Cambridge University Press:  12 May 2009

Michel Lucas*
Affiliation:
Lucie and André Chagnon Chair for the Teaching of an Integrated Approach in Prevention, Laval University, Saint-François d’Assise Hospital (CHUQ), Québec, QC, Canada Axe Santé des populations et environnement, Centre Hospitalier de l’Université Laval (CHUL-CHUQ), 2875 Laurier Blvd, Delta Building #2 – Office 600, Québec, Québec (QC) G1V 2M2, Canada
Geneviève Asselin
Affiliation:
Lucie and André Chagnon Chair for the Teaching of an Integrated Approach in Prevention, Laval University, Saint-François d’Assise Hospital (CHUQ), Québec, QC, Canada
Mélanie Plourde
Affiliation:
Research Centre on Aging, Sherbrooke University, Sherbrooke, QC, Canada
Stephen C Cunnane
Affiliation:
Research Centre on Aging, Sherbrooke University, Sherbrooke, QC, Canada
Éric Dewailly
Affiliation:
Axe Santé des populations et environnement, Centre Hospitalier de l’Université Laval (CHUL-CHUQ), 2875 Laurier Blvd, Delta Building #2 – Office 600, Québec, Québec (QC) G1V 2M2, Canada Department of Social and Preventive Medicine, Laval University, Sainte-Foy, QC, Canada
Sylvie Dodin
Affiliation:
Lucie and André Chagnon Chair for the Teaching of an Integrated Approach in Prevention, Laval University, Saint-François d’Assise Hospital (CHUQ), Québec, QC, Canada Department of Obstetrics and Gynaecology, Laval University, Québec, QC, Canada
*
*Corresponding author: Email [email protected]
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Abstract

Objective

To quantify marine food product consumption and EPA + DHA intake among Quebecers, and to compare the results with the most recent recommendations.

Design

Data were obtained from a representative cross-sectional telephone survey (June 2006). Intakes of marine food product species and EPA + DHA were estimated from a validated FFQ on the consumption of marine food products during the previous month. Prevalence of fish oil consumption in the last 6 months was also assessed.

Setting

Province of Quebec (Canada).

Subjects

A representative sample (n 1001) of adults in the province of Quebec. Of these, eight were excluded from the present analysis (n 993).

Results

Mean and median EPA + DHA intakes for all participants were estimated to be 291 mg/d (sem 11) and 207 mg/d, respectively. 85·0 % (95 % CI 82·7, 87·3) of Quebecers had an EPA + DHA intake lower than 500 mg/d, which is the amount internationally recommended for the prevention of CVD. Mean and median DHA intakes among women of childbearing age (n 128, 18–34 years) were estimated to be 169 mg/d (sem 17) and 126 mg/d, respectively. Of these women, 27·7 % had a daily intake >200 mg DHA and 15·9 % had an intake >300 mg DHA. We noted that 13 % of Quebecers take ≥1 capsule of fish oil/d.

Conclusions

Consumption of marine food products and EPA + DHA among Quebecers clearly appears to be lower than international recommendations. Since EPA + DHA confer health benefits and may reduce health costs, strategies to increase their consumption should be implemented to improve public health in Quebec.

Type
Research Paper
Copyright
Copyright © The Authors 2009

Decreasing intake of n-3 fatty acids and increasing intake of n-6 fatty acids are widely considered to be contributing to the rising incidence of many chronic, degenerative diseases(Reference Simopoulos1). However, it has been suggested that n-3 from fish and seafood might be the more important factor in total n-3/total n-6 ratios, and that the utilisation of ratios is mathematically problematic(Reference Harris2). Fish and seafood contain two n-3 long-chain (LC) PUFA – EPA and DHA – both of which appear to be beneficial for the prevention or treatment of CVD(Reference Kris-Etherton, Harris and Appel3) and inflammatory disorders, such as rheumatoid arthritis(Reference Calder4). Although humans are technically capable of endogenously synthesising EPA and DHA from the n-3 precursor in plants (α-linolenic acid; α-LNA), this conversion is a very inefficient way of increasing DHA in tissues(Reference Plourde and Cunnane5). Therefore, in general, EPA and DHA concentrations in blood reflect habitual dietary EPA and DHA intake(Reference Lucas, Asselin, Mérette, Poulin and Dodin6).

In CVD prevention, it has been proposed(Reference Anderson and Appel7) that interventions should initially concentrate on lifestyle factors linked to CVD risk factors (hypertension, hypercholesterolaemia or diabetes)(Reference Mosca, Appel and Benjamin8) or nutritional factors for which there is evidence of a protective effect, such as the consumption of fish, fish oil or marine food products(Reference Kris-Etherton, Harris and Appel3). Several organisations recommend n-3 LC PUFA to reduce CVD risk, especially sudden death and death from CHD in adults(Reference Kris-Etherton, Harris and Appel3, Reference Wang, Harris, Chung, Lichtenstein, Balk, Kupelnick, Jordan and Lau9). n-3 LC PUFA may also have beneficial outcomes on mental health(Reference Freeman, Hibbeln and Wisner10). A recent evidence-based review of international recommendations for LC n-3 fatty acids indicates that an intake of 500 mg/d of EPA and DHA reduces CVD risk(Reference Gebauer, Psota, Harris and Kris-Etherton11). This daily EPA and DHA intake has been suggested by several health agencies worldwide (Table 1).

Table 1 International recommendations for EPA and DHA

α-LNA, alpha-linolenic acid (18 : 3n-3); ADA, American Dietetic Association; AHA, American Heart Association; ANC, Apports nutritionnels conseillés; DC, Dietitians of Canada; DHA (22 : 6n-3); EPA (20 : 5n-3); FNB-IOM, Food and Nutrition Board of the Institute of Medicine of the National Academies of Science; ISSFAL, International Society for the Study of Fatty Acids and Lipids; NATO, North Atlantic Treaty Organization; NHMRC, National Health and Medical Research Council; PeriLip, Perinatal Lipid Intake Working Group.

*EPA and DHA can contribute up to 10 % of total n-3 intake and, therefore, up to this percentage can contribute toward the adequate intake of α-LNA (18 : 3n-3) (1·3–2·7 g/d).

n-3 long-chain PUFA: EPA, DHA, DPA (docosapentaenoic acid, 22 : 5n-3).

The intake of n-3 LC PUFA during pregnancy and lactation is also associated with beneficial effects for mothers and the mental development of their children(Reference Freeman, Hibbeln and Wisner10, Reference Makrides12). Since the fetus is unable to synthesise sufficient DHA for the development of its nervous system, it depends on the mother for DHA(Reference Crawford13). Preformed DHA is preferred for infants and is obtained prenatally via the placenta, postnatally from breast milk, fat stores, supplemented formula and, later, from foods(Reference Innis14, Reference Cunnane, Francescutti, Brenna and Crawford15). Breast-feeding is the preferred method of infant feeding(Reference Carlson16). The DHA content of breast milk is strongly positively associated with the frequency of fish intake and n-3 LC PUFA intake(Reference Makrides12, Reference Carlson16). However, supplementation of breast-feeding mothers with the DHA precursor α-LNA (10·7 g/d) from flaxseed oil does not increase DHA in breast milk(Reference Francois, Connor, Bolewicz and Connor17). Recently, a European collaborative group indicated that providing EPA and DHA at 1–2·7 g/d to pregnant and lactating women had no significant adverse effects(Reference Koletzko, Cetin and Thomas Brenna18). To assure sufficient DHA for fetal and maternal tissue DHA accretion, the recommended daily intake of DHA during pregnancy and lactation has been set at 200 mg by the Perinatal Lipid Intake Working Group (PeriLip)(Reference Koletzko, Cetin and Thomas Brenna18), and 300 mg by the International Society for the Study of Fatty Acids and Lipids (ISSFAL)(Reference Simopoulos, Leaf and Salem19).

In 1990, the consumption of fish and n-3 LC PUFA did not represent a significant part of the diet of Quebecers(20, Reference Dewailly, Blanchet, Gingras, Lemieux and Holub21). Between 1990 and 1992, Santé-Québec, an organisation of the Québec Ministry of Health and Social Services, conducted a series of health surveys among southern Quebecers, James Bay Cree (Northwestern Quebec) and Inuit of Nunavik (Northern Quebec). Data from 24 h dietary recalls revealed that on the day before each survey, mean daily consumption of fish was 13 g for Southern Quebecers, 60 g for James Bay Cree, and 131 g for the Inuit of Nunavik. The daily fish intake of the Cree and Inuit populations provided ∼700–900 and 2115 mg of EPA + DHA, respectively(Reference Dewailly, Blanchet, Gingras, Lemieux and Holub21). However, fish intake among Southern Quebecers provided <200 mg/d of EPA + DHA, a level also observed in the USA(Reference Kris-Etherton, Taylor and Yu-Poth22). In parallel, a natural health product that is becoming more popular in the Canadian population is fish oil or supplements containing EPA and DHA. Indeed, according to the 2000–2001 Canadian Community Health Survey (CCHS) results, the proportion of Canadians who took fish oil was 9·4 %(Reference Singh and Levine23).

Much scientific and lay publicity concerning the benefits of n-3 LC PUFA intake has circulated worldwide since Santé-Québec’s health surveys in the 1990s(20, Reference Dewailly, Blanchet, Gingras, Lemieux and Holub21). Although EPA and DHA have recently gained in popularity, little is known about their actual intake by Quebecers. From a public health standpoint, it was therefore important to know the actual EPA + DHA intake of the Quebec population. To our knowledge, no other recently published studies have attempted to quantify fish consumption and dietary EPA + DHA intake among Quebecers. The primary objective of the present study was, therefore, to analyse marine food product consumption and EPA + DHA intake among a representative sample of adults from the province of Quebec, and to compare these values with the most recent recommendations (Table 1).

Subjects and methods

Study design and participants

Data were obtained from a representative cross-sectional telephone survey (n 1001) by random digital dialling for the selection of one adult (>18 years) per household. During the telephone survey, participants were asked to complete a validated FFQ about marine food products(Reference Lucas, Asselin, Mérette, Poulin and Dodin6). Telephone interviews were conducted by trained interviewers from the largest independent market research firm in Canada – Léger Marketing (Montréal). Sampler software (ASDE Survey Sampler Inc., Gatineau, QC, Canada) selected the random sampling population. The margin of error for the 95 % CI of this survey was ±3·4 %. The response rate was 56·9 %. Among the 1001 participants interviewed, eight gave aberrant answers to questions on marine food product consumption (e.g. twenty meals of 226 g or 8 oz/week) and were, therefore, excluded from the present analysis (n 993). Gender, age, occupation, level of education, income and region were available for each respondent. Furthermore, a weight was established for each respondent according to the latest data from Statistics Canada regarding region, maternal language, gender and age. Therefore, the data presented in the present paper were obtained from weighted data and represented the adult population of Quebec as a whole.

Assessment of marine food product intake

Data on the consumption of marine food products were generated by completion of a validated FFQ, which evaluated marine food product intake within the last month. Validation and more details of the FFQ have been given elsewhere(Reference Lucas, Asselin, Mérette, Poulin and Dodin6). Briefly, the FFQ was validated by measuring the relationship between baseline EPA + DHA intake assessed by this FFQ and EPA + DHA concentration in red blood cells (RBC) among a sample of middle-aged women (n 65) participating in a randomised clinical trial. Analyses indicated that baseline EPA + DHA intake, measured by our FFQ, correlated reasonably well (Spearman’s r = 0·42, P = 0·0005) with EPA + DHA concentration in RBC at baseline. The FFQ had two principal questions. The first question referred to the portion size of fish consumed: ‘In general, what is the portion size that corresponds best to your habitual consumption when you eat fish?’ The second question of the FFQ was aimed at knowing the frequency of marine food products consumed: ‘Based on your food consumption of the last month, how many times did you consume the following marine food products?’ The questionnaire included seven groups of marine food products: (i) oily fish (fresh or canned salmon, herring, mackerel, sardines); (ii) canned tuna; (iii) trout or halibut; (iv) white fish (sole, rockfish, haddock, cod, etc.); (v) molluscs (mussels, oysters, clams, scallops); (vi) crustaceans (shrimps, crabs, lobsters, etc.); (vii) imitation crab. Based on the 2005 Canadian Nutrient File of Health Canada(39), each of these groups of marine food products was assigned an amount of EPA and DHA. A question concerning fish oil consumption was also added to the FFQ: ‘Over the last 6 months, what was your fish oil supplement consumption (capsules containing marine omega-3 fatty acids)?’

Statistical analysis

The statistical distribution of marine food product and EPA + DHA intakes was found to be skewed. Therefore, log transformation was undertaken to compare marine food product and EPA + DHA intakes relative to socioeconomic characteristics. Arithmetic means were also calculated to facilitate comparisons with other studies. Student’s t test was only used to compare EPA + DHA intake between genders. An ANOVA test with Bonferroni correction for multiple comparisons compared EPA + DHA intake according to other participant characteristics (age, occupation, level of education and income). Geometric mean values (95 % CI) were presented for comparisons according to participants’ characteristics. The χ 2 test was performed to compare the proportion of Quebecers who had an intake lower than the international recommendation for CVD protection (500 mg EPA + DHA/d), according to gender. Since DHA intake is a key nutrient during pregnancy and lactating periods, we extracted data on this parameter among women of childbearing age (n 128, 18–34 years). DHA intake of these women was compared to the daily intake recommended during pregnancy and lactation by PeriLip (>200 mg/d)(Reference Koletzko, Cetin and Thomas Brenna18) or ISSFAL (>300 mg/d)(Reference Simopoulos, Leaf and Salem19). Statistical analyses were conducted with the SAS program for Windows v·9 (SAS Institute Inc., Cary, NC, USA). Differences between groups and associations were considered significant at P ≤ 0·05 (bilateral).

Results

Demographic characteristics of the study respondents are presented in Table 2. Among the 993 adults who responded to the survey, forty-two had missing information on portion size, leaving 951 subjects for the estimation of intakes of marine food products and EPA + DHA. Of these, a total of 109 subjects (11·5 %) were non-consumers of marine food products. Mean intakes (g/d) of oily fish, canned tuna, trout or halibut, white fish, molluscs, crustaceans and imitation crab were 12·0 (sd 16·4), 7·3 (sd 13·3), 3·6 (sd 8·3), 5·6 (sd 10·7), 1·6 (sd 4·0), 4·9 (sd 7·7) and 1·7 (sd 6·4), respectively. Their EPA + DHA contributions (mg/d) were 179 (sd 244), 28 (sd 50), 34 (sd 77), 19 (sd 36), 8 (sd 20), 14 (sd 22) and 11 (sd 39), respectively. Total fish intake was 28·4 g/d (sd 31·7) and contributed to an EPA + DHA intake of 258 mg/d (sd 307). The mean intake of total marine food products was 36·6 g/d (sd 37·7). However, the median intakes of oily fish, total fish and marine food products were 7, 19 and 28 g/d, respectively. Mean and median EPA + DHA intakes were estimated to be 291 mg/d (sd 328) and 207 mg/d, respectively. The geometric mean of EPA + DHA intake was 217 mg/d (95 % CI 203, 232). EPA + DHA intakes were not statistically different between men and women (t 840 = 1·26, P = 0·2097). However, the proportion of Quebecers who had an intake <500 mg EPA + DHA/d was 85·0 % (95 % CI 82·7, 87·3), and was higher among males (88·8 %, 95 % CI 85·9, 91·7) than females (81·5 %, 95 % CI 78·0, 84·9) (χ 2 = 10·0, P = 0·0015). EPA + DHA intakes increased progressively with age (P trend = 0·0389), income (P trend = 0·0020) and education (P trend = 0·0441) (data not presented). No statistical differences (P > 0·05) were noted for geometric means of EPA + DHA intake according to age or education groups. Among people with income <$20 000, the geometric mean of EPA + DHA intake was 151 mg/d (95 % CI 121, 188) and was significantly lower (P < 0·05) – by about 79 mg – compared to other income classes.

Table 2 Characteristics of the study subjects (n 993)

Mean and median DHA intakes among women of childbearing age (n 128) were estimated to be 169 mg/d (sd 198) and 126 mg/d, respectively. The geometric mean of DHA intake among these women (n 111) was 127 mg/d (95 % CI 104, 155). The proportions of women of childbearing age who had adequate DHA intake, as recommended by PeriLip (>200 mg/d DHA) and ISSFAL (>300 mg/d DHA), were 27·7 % (95 % CI 20·4, 35·1 %) and 15·9 % (95 % CI 9·9, 21·9 %), respectively.

The prevalence of fish oil capsule consumption (n 993) was 20·7 %, with 13 % taking ≥1 capsule of fish oil/d. The prevalence of fish oil consumption (χ 2 = 0·81, P = 0·369) and taking ≥1 capsule of fish oil/d (χ 2 = 0·40, P = 0·529) was not significantly different between men and women. Among women, the rate of ≥1 capsule of fish oil/d was three times higher among older compared to younger women (≥45 years = 19·1 % v. <45 years = 6·2 %, P < 0·0001). However, this difference was not observed among males (≥45 years = 3·9 % v. <45 years = 9·8 %, P = 0·18). Among participants aged 45–64 years, the rate of ≥1 capsule of fish oil/d was two times higher among women than men (OR = 2·0, 95 % CI 1·05, 3·79). The weekly portions of each marine food category of the FFQ that are needed to attain international recommendations of 500 mg/d of EPA + DHA are shown in Fig. 1.

Fig. 1 Quantity of weekly portions* needed to attain the international recommendation of 500 mg EPA + DHA/d. This daily EPA and DHA intake has been suggested by several health agencies worldwide (see Table 1) (*1 portion = 113 g (4 oz) cooked; DHA, 22 : 6n-3; EPA, 20 : 5n-3)

Discussion

In a representative sample of adults in the province of Quebec, we estimated mean and median EPA + DHA intakes to be 291 mg/d and 207 mg/d, respectively. Several organisations have recognised the importance of consuming marine food products as well as n-3 LC PUFA to reduce the risks of CVD. In its recent revision of diet and lifestyle recommendations (2006), the American Heart Association urged the consumption of two fish meals per week (preferably fatty fish), which is equivalent to 430–570 mg of EPA and DHA daily(Reference Lichtenstein, Appel and Brands34). A review of the risks and benefits of fish consumption suggested that a modest intake of fish (1–2 fish meals/week), especially those rich in EPA and DHA, decreases the risk of CHD death by 36 %(Reference Mozaffarian and Rimm40). Analysis of fifteen randomised clinical trials indicates that n-3 LC PUFA reduce total mortality by 17 %(Reference Mozaffarian and Rimm40). A daily intake of ≈500 mg of EPA and DHA has been chosen by many organisations as a target for CVD risk reduction(Reference Gebauer, Psota, Harris and Kris-Etherton11). Only 15·0 % of the Quebecers we surveyed had a self-proclaimed EPA + DHA intake ≥500 mg/d. Moreover, the median intake of oily fish among these Quebecers was 49 g/week, which is equivalent to about one oily fish meal every 2 weeks. Compared to Western populations, the Japanese CHD death rate is very low and EPA + DHA intake is very high(Reference Iso, Kobayashi, Ishihara, Sasaki, Okada, Kita, Kokubo and Tsugane41). In our population, two fish meals/week is the target, whereas among the Japanese, the reference group (the lowest) is often comprised of those who eat 1–2 fish meals/week.

Among the women of childbearing age we surveyed, mean intake of DHA was 169 mg/d (sem 17), a result agreeing with that of Innis and Elias who reported on fifty-five pregnant women in British Columbia(Reference Innis and Elias42). They administered an FFQ between weeks 28 and 35 of pregnancy, and noted a mean DHA intake of 160 mg/d (sem 20), with 16 % of women they surveyed consuming >300 mg DHA/d. Similarly, we observed that 15·9 % of women of childbearing age had a DHA intake >300 mg/d, and 27·7 % had a DHA intake >200 mg/d. Based on dietary intakes from a 3 d food record among twenty pregnant women from Ontario, Denomme et al. noted a mean DHA intake of 82 mg/d (sem 33)(Reference Denomme, Stark and Holub43). The third trimester of pregnancy is a critical growth period that is highly susceptible to nutritional insults(Reference Carlson16). Clandinin et al. suggested that 80 % of the DHA present in the human brain at birth accumulates during the third trimester(Reference Clandinin, Chappell, Leong, Heim, Swyer and Chance44). DHA levels in the brain increase in parallel with rapid brain growth(Reference Martinez45), from the third trimester through the first years of life, and are closely linked to the presence of DHA in the infant’s diet(Reference Cunnane, Francescutti, Brenna and Crawford15). Combining our present results with two Canadian studies among pregnant women(Reference Innis and Elias42, Reference Denomme, Stark and Holub43), it seems clear that DHA intake among women of childbearing age or pregnant women in Canada is lower than what is recommended for pregnancy and lactation. These findings indicate a need for studies addressing the effects of low DHA intake on pregnancy outcomes and infant neurodevelopment in Canada.

To our knowledge, no other recently published studies have attempted to quantify fish consumption and dietary EPA + DHA intake among Quebecers. In our present work, mean intakes of total fish and total marine food products were 28·4 g/d and 36·6 g/d, respectively. In the 1990 Santé-Québec survey among Quebecers, fish intake was determined by FFQ administered by a nutritionist during face-to-face interviews at home. The FFQ measured consumption during the month before the survey and included only two fish items: fish and fried fish. Each participant was asked to provide the usual frequency of consumption and the usual portion size. The participants’ reported mean fish intake was 95 g/week during the month before the survey. The median intake of total fish consumed was 55 g/week. In the present study, median intake of oily fish and total fish was 49 g/week and 134 g/week, respectively. This divergence in results between the 1990 survey and our present survey can probably be explained by the proportion of non-consumers of fish in the 1990 Santé-Québec survey, which was 43·3 % in 1990 but was only 11·5 % in our survey. The different results may also be due to the use of two very different questionnaires. The FFQ in the present study evaluated the consumption of seven categories of marine food products, whereas the questionnaire in the 1990 Santé-Québec survey had only two questions, one of them on fried fish. EPA + DHA in RBC, a biomarker of marine n-3 fatty acid consumption, correlates very well with the risk of CHD death(Reference Harris and Von Schacky46) and with human myocardial n-3 concentration(Reference Harris, Sands, Windsor, Ali, Stevens, Magalski, Porter and Borkon47). EPA + DHA intake measured by our FFQ correlated reasonably well with EPA + DHA concentration in RBC (Spearman’s r = 0·42, P = 0·0005)(Reference Lucas, Asselin, Mérette, Poulin and Dodin6).

In North America, an increasing number of persons are turning to natural health products(Reference Kessler, Davis, Foster, Van Rompay, Walters, Wilkey, Kaptchuk and Eisenberg48). Indeed, according to 2000–2001 CCHS results, the proportion of Canadians who took fish oil was 9·4 %(Reference Singh and Levine23). In the present study, we noted that 20·7 % of participants consumed fish oil capsules, with 13 % ingesting ≥1 capsule of fish oil/d. Among women, the rate of ≥1 capsule of fish oil/d was three times higher among older compared to younger women, but this difference was not observed among males. In the CCHS, the prevalence of past 2 d natural health product use was 1·5–2 times higher in women between the ages of 36 and 75, than men of the same age group(Reference Singh and Levine23). However, among participants aged 45–64 years, we noted that the rate of ≥1 capsule of fish oil/d was two times higher among women than men. This confirms the fact that middle-aged women are important consumers of natural health products(Reference Singh and Levine23). However, we did not ask about the format or n-3 concentration of fish oil taken and we were, therefore, unable to estimate EPA and DHA intake from fish oil. Since 13 % of the Quebecers we surveyed take more than 1 fish oil capsule/d, the EPA + DHA intake among some Quebecers is probably higher than the level estimated by only the FFQ. In addition, the dietary EPA and DHA intakes of Quebecers might be higher than we estimated because a low level of those n-3 fatty acids might be provided by chicken and regular egg consumption (an additional contribution of ≈30 mg of EPA + DHA/d)(39). Moreover, EPA + DHA intake may be even higher if Quebecers consume food products, such as eggs, yoghurts, milk, cheese and beverages, fortified with these n-3 fatty acids.

Our study has a number of limitations. Data collection by telephone survey is relatively quick and inexpensive, but it has the problem of growing coverage and falling response rates. Indeed, the major biases with telephone surveys are observational errors (or sampling errors), such as non-coverage bias, non-response bias (non-participation) and sampling bias(49). Because of the trend away from fixed landlines to cellular phones, the non-coverage bias is becoming a major problem in telephone survey research. Even if ownership of cellular phones is high among Quebecers (46 %), most of these adults also have landline telephone service (Léger Marketing, personal communication). Indeed, 98–99 % of Quebecers have a fixed landline phone, and only 1 % has no service at all. It is generally accepted that the response rate to telephone surveys is decreasing(Reference Johnson, Holbrook, Ik Cho and Bossarte50). Reports have indicated that for response rates in the 40–70 % range, non-response bias does not appear to significantly affect survey estimates(Reference Keeter, Miller, Kohut, Groves and Presser51, Reference Curtin, Presser and Singer52). A comparison of non-responses in surveys revealed that face-to-face situations had the highest completion rate, telephone surveys, the next highest, and mail surveys, the lowest(Reference Hox and De Leeuw53). Our response rate was 56·9 %. Moreover, our results were weighted according to the latest Statistics Canada data to make the sample representative of the adult Quebec population. Taken together, these potential sampling errors are unlikely to have seriously influenced our findings.

Other limitations could be attributed to the fact that our FFQ has been validated in face-to-face interviews among middle-aged women(Reference Lucas, Asselin, Mérette, Poulin and Dodin6). However, conversion of α-LNA to EPA or DHA has been suggested to be higher among young women due to oestrogen(Reference Burdge54). Nevertheless, if the α-LNA conversion rate is likely higher among women compared to men, it indicates that the relationship between EPA + DHA intakes and RBC EPA + DHA concentrations might be at least equal, or superior, to that in men. However, data from our validation study were self-reported. Therefore, the results might be different since distinct modes of administration of the FFQ were used. Another limitation that affects every FFQ or any estimated nutrient intake tool is the utilisation of nutrient databases that might not adequately reflect temporal changes in food composition(Reference Cantwell55). Moreover, dietary EPA and DHA may vary considerably in the same fish species. We previously noted, that EPA + DHA in skinless fillets (100 g raw) of farmed Atlantic salmon and rainbow trout ranged, respectively, between 414–1460 mg and 263–1334 mg(Reference Blanchet, Lucas, Julien, Morin, Gingras and Dewailly56). In addition, intakes of EPA and DHA can be very different if consumers eat only skinless fillets or subcutaneous fat.

If the recommendation to consume two fish meals/week is to become the norm in the Quebec population, modifications of the food environment and public health strategies are warranted. To reach the international recommendation of 500 mg of EPA + DHA/d, two meals (113 g or 4 oz) per week of oily fish are required, whereas nine meals of white fish would be needed (Fig. 1). Consumption of fatty fish, such as salmon, herring, mackerel or sardines, is the cheapest and easiest way to increase EPA + DHA intake. However, a large proportion of the population is unable or unwilling to consume EPA + DHA from fish alone. In fact, only one-third of the participants reported an oily fish intake of ≥1 meal/week. Alternative strategies would be the intake of fish oil capsules or increased intake of foods enriched with n-3 LC PUFA. Even if fish oil capsules are associated with health benefits(Reference Calder4, Reference Wang, Harris, Chung, Lichtenstein, Balk, Kupelnick, Jordan and Lau9, Reference Freeman, Hibbeln and Wisner10) and with reduced health costs from secondary CHD prevention(Reference Schmier, Rachman and Halpern57, Reference Lamotte, Annemans, Kawalec and Zoellner58), fish and seafood are still preferred because they contain nutrients other than n-3 fatty acids and, thus, represent an integral part of a healthy lifestyle.

In conclusion, the estimated intake of marine food products and EPA + DHA among adult Quebecers is much lower than international recommendations. Since n-3 LC PUFA confer health benefits and may reduce health costs, strategies to increase their consumption should be implemented to improve public health in Quebec.

Acknowledgements

The present study was supported in part by grants from the Lucie and André Chagnon Chair of Laval University, the Department of Medicine, Sherbrooke University (post-doctoral fellowship to M.P.), Canada Research Chairs and the Natural Sciences and Engineering Research Council (S.C.C.). None of the authors have reported any financial or personal conflict of interest to the present manuscript. As the principal investigator, M.L. had full access to the study data, and takes responsibility for the integrity of the data and accuracy of the data analysis. The contributions of each author in this work are as follows: study concept and design – M.L., G.A. and S.D.; development of the FFQ and analysis of the data – M.L.; data interpretation – M.L., G.A., M.P., S.C.C., E.D. and S.D.; drafting the manuscript – M.L., M.P. and S.C.C.; critical revision of the manuscript – M.L., G.A., M.P., S.C.C., E.D. and S.D. The authors also express their gratitude to all participants in this survey.

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Figure 0

Table 1 International recommendations for EPA and DHA

Figure 1

Table 2 Characteristics of the study subjects (n 993)

Figure 2

Fig. 1 Quantity of weekly portions* needed to attain the international recommendation of 500 mg EPA + DHA/d. This daily EPA and DHA intake has been suggested by several health agencies worldwide (see Table 1) (*1 portion = 113 g (4 oz) cooked; DHA, 22 : 6n-3; EPA, 20 : 5n-3)