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Fish consumption and the incidence of cerebrovascular disease

Published online by Cambridge University Press:  14 September 2009

Jukka Montonen*
Affiliation:
Department of Health and Functional Capacity, National Public Health Institute, Mannerheimintie 166, FIN-00300, Helsinki, Finland
Ritva Järvinen
Affiliation:
Department of Clinical Nutrition, University of Kuopio, Kuopio, FIN-70211, Finland
Antti Reunanen
Affiliation:
Department of Health and Functional Capacity, National Public Health Institute, Mannerheimintie 166, FIN-00300, Helsinki, Finland
Paul Knekt
Affiliation:
Department of Health and Functional Capacity, National Public Health Institute, Mannerheimintie 166, FIN-00300, Helsinki, Finland Social Insurance Institution, Helsinki, FIN-00100 and Turku, FIN-20720, Finland
*
*Corresponding author: Dr Jukka Montonen, fax +44 358 9 4744 8924, email [email protected]
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Abstract

Studies of the beneficial role of fish consumption in the prevention of CVD are not consistent in their findings, particularly those studies that focus on the risk of stroke. The aim of the present study is to investigate the relationship between the consumption of different types of fish and the subsequent incidence of cerebrovascular disease (CVA). We prospectively evaluated the association between consumption of different types of fish and CVA in 3958 men and women aged 40–79 years who were free of heart disease and had participated in a health examination survey from 1967 to 1972. A total of 659 incident cases of CVA occurred during a follow-up until the end of 1994. A dietary history interview method provided data on habitual consumption of fish and other foods over the preceding year at baseline. Total fish intake did not predict CVA, but consumption of salted fish suggested an increased risk of intracerebral haemorrhage. The relative risk of intracerebral haemorrhage between the highest tertile of salted fish consumption and non-consumers was 1·98 (95 % CI 1·02, 3·84; P for trend = 0·06) after adjustment for age, sex, energy intake, smoking, BMI, physical activity, geographic area, occupation, diabetes, use of post-menopausal hormones, serum cholesterol, hypertension, and consumptions of butter, vegetables, fruits and berries. The relationship between fish consumption and stroke risk is not straightforward. How the fish is prepared for consumption may play an important role, affecting the association.

Type
Full Papers
Copyright
Copyright © The Authors 2009

Despite the fact that fish is recommended as a part of healthy diet, evidence of fish consumption providing protection against CVD is not entirely consistent, especially when it comes to stroke. The study of this association is also complicated by the different types of stroke, characterized by different risk factors. The meta-analyses of He et al. (Reference He, Song and Daviglus1) and Bouzan et al. (Reference Bouzan, Cohen and Connor2) on fish consumption and stroke risk concluded that there is an inverse relationship between fish consumption and the risk of stroke, the association being concentrated on the ischaemic type of stroke. Another recent careful review suggested that intake of n-3 fatty acids specific to fish may reduce the risk of cardiac death and possibly stroke(Reference Wang, Harris and Chung3). However, in another recent systematic review, the authors did not reach a similar conclusion(Reference Hooper, Thompson and Harrison4).

It has been suggested that fish consumption may be a potential protective factor when it comes to illnesses because fish contain long-chain n-3 fatty acids, which may inhibit atherosclerotic processes(Reference Robinson and Stone5). On the other hand, the type of fish or method of fish preparation may influence the potential preventive effect. Only a few studies have reported on the association between consumption of different types of fish and stroke, however. In a cohort study among elderly individuals based on the data from the Cardiovascular Health Study, a lower risk of ischaemic stroke was reported with higher consumption of tuna or other broiled or baked fish, while the intake of fried fish or fish sandwiches was associated with a higher risk(Reference Mozaffarian, Longstreth and Lemaitre6). Salted fish products contain considerable amounts of salt. In ecological studies, salt consumption has been associated with stroke risk(Reference Sasaki, Zhang and Kesteloot7, Reference Xie, Sasaki and Joossens8), yet evidence from such prospective studies remains sparse and controversial(Reference Cohen, Hailpern and Fang9, Reference Nagata, Takatsuka and Shimizu10). The present study addressed the question of whether an association can be found between total fish consumption, salted or smoked fish in particular, and the subsequent incidence of cerebrovascular disease (CVA), intracerebral haemorrhage or thrombotic stroke in a nationwide cohort of Finns.

Subjects and methods

The Finnish Mobile Clinic Health Examination Survey carried out health examinations in various parts of Finland between 1966 and 1972(Reference Aromaa11Reference Reunanen, Aromaa and Pyörälä13). The baseline examinations were carried out in thirty-four rural, industrial or semi-urban populations in six regions of the country. A dietary history interview of 10 054 citizens 15 years of age or more was included in the study from 1967(Reference Järvinen14). After exclusion of individuals suffering from heart disease prior to the baseline study, and inclusion of persons aged 40–79 years with an energy intake between 3347 and 25 104 kJ (800 and 6000 kcal), the study population was 3958 men and women.

All participants completed a questionnaire that yielded information on their residence, previous and current illnesses, use of medications, smoking habits and leisure-time physical activity. Subjects were classified according to smoking status as non-smokers, ex-smokers, smokers of pipes or cigars only, smokers of fewer than 15 cigarettes/d, and smokers of 15 or more cigarettes/d(Reference Knekt12). The participants were asked whether or not they engaged in regular leisure-time physical activity. Body height and weight were measured, and the BMI was calculated. Casual blood pressure was registered in the sitting position after a 5 min rest, using the auscultatory method(Reference Aromaa11). The subjects were divided into four classes on the basis of systolic and diastolic blood pressure levels and their use of antihypertensive drugs(Reference Knekt12). Persons with systolic blood pressure ≥ 170 mmHg and diastolic blood pressure ≥ 100 mmHg, and persons using antihypertensive medication, were considered definitely hypertensive. Persons with systolic blood pressure ≥ 160 mmHg and diastolic blood pressure ≥ 95 mmHg but not defined as hypertensive were considered to have mild hypertension, and those with systolic blood pressure < 140 mmHg and diastolic blood pressure < 90 mmHg were considered normotensive. All persons with intermediate values were considered to have borderline hypertension. Serum cholesterol concentration was determined with an autoanalyser modification of the Liebermann–Burchard reaction(Reference Huang, Chen and Wefler15). Known cases of diabetes were identified by the history given by the participants, and undiagnosed cases were identified on the basis of a modified oral glucose test and fasting blood glucose values, using the current diagnostic criteria of the WHO(Reference Reunanen, Aromaa and Pyörälä13, 16).

Total habitual food consumption during the previous year was estimated using a dietary history interview(Reference Järvinen14). Trained interviewers conducted these structured interviews using a questionnaire form listing over 100 food items and mixed dishes common in the Finnish diet. Several questions were open-ended, giving the respondent an opportunity to provide more detailed answers and any further explanations during the interview. Food models were used as an aid in determining portion sizes. The consumption of foods was estimated per day, week, month or year according to the choice of the respondent. Individual consumption of food items was converted to g/d. Energy intake was calculated based on the intake of protein, fat and available carbohydrate. Nutrient contents in food items were derived from Finnish food composition tables(Reference Rastas, Seppänen and Knuts17). Food composition data on fatty acids were completed, utilizing analysed values of Finnish foods(Reference Hyvönen and Koivistoinen18, Reference Hyvönen, Lampi and Varo19).

Reproducibility of the dietary history method was estimated after 4–8 months (ninety-three individuals) and 4–7 years (1844 individuals) by repeating the interview. The reproducibility of the dietary interviews completed 4–8 months apart was good, but long-term consistency 4–7 years apart was rather poor(Reference Järvinen, Seppänen and Knekt20). The reliability coefficient for short-term repeatability of the daily consumption of fish was 0·72, and the corresponding long-term coefficient was 0·39.

Information regarding CVA incidence during the follow-up was obtained by linking data from the Finnish Hospital Discharge Register, kept by the National Board of Health, to the dietary data(Reference Heliövaara, Reunanen and Aromaa21). Information on mortality was based on death certificates obtained for all the deceased from the Central Statistical Office of Finland(Reference Reunanen, Aromaa and Pyörälä13). The diagnosis leading to hospitalization or death due to CVA was identified using the three-digit codes 430–438 of the International Classification of Diseases, Eighth Revision (ICD-8(22)). The diagnoses were further classified as intracerebral haemorrhage (code 431), thrombotic or embolic occlusion (codes 432–434) or all acute strokes (codes 430–438 and 344) including also subarachnoidal haemorrhage (code 430). The follow-up refers to the period of observation from the time of the baseline examination until onset of the disease, until death or until the end of the observation period (1994), whichever came first.

The Cox proportional hazards model(Reference Cox23) was used to estimate the association between fish consumption and the incidence of CVA. Dietary variables were categorized as quartiles separately among men and women. Intake of salted fish and smoked fish were categorized as non-consumption as a reference and thereafter as tertiles among consumers, due to the high number of non-consumers. Relative risks were estimated for intake categories using the lowest category as the reference. Potential confounding factors including age, sex, energy intake, smoking, BMI, physical activity, geographic area, occupation, diabetes, use of post-menopausal hormones, hypertension and serum cholesterol were adjusted for by modelling. The potential modifying effect of sex, BMI, serum cholesterol and hypertension was studied by including interaction terms in the model. Tests for trends through the quartiles of intake were carried out on the basis of a likelihood ratio test, treating all variables in the model as continuous by entering the quartile medians.

Results

A total of 659 incident cases of CVA occurred during the follow-up of 28 years (approximately 30 % were identified through death certificates). Of those cases eighty were intracerebral haemorrhages, 364 were thrombotic occlusions or embolia and forty were subarachnoidal haemorrhages. The rest of the cases were unspecified cerebral strokes. Persons who developed CVA tended to be slightly older. They were more likely hypertensive, and they more often had a history of diabetes (Table 1). Distribution of the dietary variables did not show strong differences between incident cases and non-cases.

Table 1 Personal characteristics at baseline in cases of cerebrovascular disease and non-cases

(Mean values and standard deviations)

* Proportion of persons with systolic blood pressure ≥ 160 mmHg and diastolic ≥ 95 mmHg, or having antihypertensive medication.

Proportion of current smokers.

EPA+DHA.

Most of the baseline non-dietary risk factors were distributed in roughly similar patterns across the quartiles of fish consumption (Table 2). However, persons in the highest quartile of fish consumption were more likely smokers or physically active, and their serum cholesterol level tended to be higher. Persons with higher fish consumption also seemed to consume more vegetables, fruits and berries and less butter than those with lower fish consumption. Fish consumption was closely associated with intake of marine long-chain n-3 fatty acids, EPA and DHA and higher intake of energy, mercury and sodium.

Table 2 Mean levels of characteristics in quartiles of fish intake*

(Mean values and standard deviations)

* For details of subjects and procedures, see the Subjects and methods section and Table 1.

Persons with systolic blood pressure ≥ 160 mmHg and diastolic ≥ 95 mmHg, or having antihypertensive medication.

Proportion of current smokers.

§ EPA+DHA.

Total fish consumption did not predict CVA, intracerebral haemorrhage or thrombotic stroke (Table 3). Categorization of subjects by fish consumption as consumers and non-consumers did not notably alter the results (data not shown). A similar absence of association was observed for intakes of marine long-chain fatty acids, mercury and sodium.

Table 3 Adjusted relative risks (RR) of cerebrovascular diseases in quartiles of fish consumption and intakes of marine long-chain n-3 fatty acids, mercury and sodium*

* For details of subjects and procedures, see Subjects and Methods section and Table 1. RR adjusted for age (continuous), sex, energy intake (continuous), smoking (non-smokers, ex-smokers, smokers of pipes or cigars only, smokers of fewer than fifteen cigarettes/d, and smokers of fifteen or more cigarettes/d), BMI (kg/m2: < 23, 23–24·9, 25–27·4, 27·5–29·9, 30+), physical activity (inactive, occasionally or regularly active), geographic area (six areas), occupation, diabetes, use of post-menopausal hormones (yes/no), hypertension (four categories according to measured systolic and diastolic pressure and use of antihypertensive medication), serum cholesterol (continuous), and consumptions of butter, vegetables, fruits and berries (continuous).

Categorized as non-consumers as reference and as tertiles among consumers due to high number of non-consumers.

EPA+DHA (mg/d).

§ μg/d.

A significantly increased risk of intracerebral haemorrhage was observed when persons in the highest category of consumption of salted fish were compared to non-consumers. The relative risk of intracerebral haemorrhage between non-consumers and the extreme consumption tertile was 1·98 (95 % CI 1·02, 3·84; P for trend: P = 0·06) when adjusted for age, sex, energy intake, smoking, BMI, physical activity, geographic area, occupation, diabetes, use of post-menopausal hormones, serum cholesterol, hypertension, consumptions of butter, vegetables, fruits and berries. Adjustment for sodium intake attenuated the association observed. The relative risk of intracerebral haemorrhage in the extreme category of salted fish was 1·70 (CI 0·84, 3·43; P = 0·19) after further adjustment for sodium intake.

The interaction between total fish consumption and the potentially modifying factors of sex, BMI, serum cholesterol and hypertension in the prediction of CVA was studied.

The association between salted fish intake and the risk of intracerebral haemorrhage was more pronounced among normotensive persons and persons with higher serum cholesterol levels (Table 4). Among the normotensive persons, the relative risks across the consumption categories compared to non-consumers were 2·36 (95 % CI 1·03, 5·55), 1·53 (95 % CI 0·62, 3·77) and 3·16 (95 % CI 1·39, 7·20), and among persons with hypertension 0·31 (95 % CI 0·06, 1·54), 1·17 (95 % CI 0·37, 3·78) and 0·42 (95 % CI 0·09, 2·05), respectively. The P value for interaction was 0·02. The corresponding risks among persons with median or higher serum cholesterol level were 0·96 (95 % CI 0·31, 2·98), 0·86 (95 % CI 0·26, 2·83) and 2·87 (95 % CI 1·12, 7·35), and among persons with below median serum cholesterol values 2·12 (95 % CI 0·89, 5·07), 1·90 (95 % CI 0·77, 4·73) and 1·30 (95 % CI 0·46, 3·64). The P value for interaction was 0·04. No significant interactions between any of these modifying factors and fish consumption were noted in prediction of either total CVA or thrombotic strokes (data not shown).

Table 4 Relative risk (RR) of intracerebral haemorrhages between the highest and lowest categories of consumption of fish and salted fish in strata of potential effect-modifying factors*

* For details of subjects and procedures, see the Subjects and methods section and Table 1. Relative risk adjusted for age, sex, energy intake, smoking, BMI, physical activity, geographic area, occupation, diabetes, use of post-menopausal hormones, blood pressure, serum cholesterol, and consumptions of butter, vegetables, fruits and berries except when included in the interaction term.

Categorized as non-consumers as reference and as tertiles among consumers due to high number of non-consumers.

Median value was 26·1 kg/m2.

§ Median value was 6·9 mmol/l.

Persons with systolic blood pressure ≥ 160 mmHg and diastolic ≥ 95 mmHg, or having antihypertensive medication.

Discussion

We did not find a significant association between total fish consumption and the risk of thrombotic or haemorrhagic stroke or total stroke risk. However, the present findings indicated that consumption of salted fish was associated with a higher risk of haemorrhagic stroke. The present findings support the hypothesis that the effects of fish intake on health may depend on the preparation of the fish, especially salting.

Few previous studies have reported on the association between fish consumption and haemorrhagic stroke. No significant associations have been reported among men(Reference He, Rimm and Merchant24), women(Reference Iso, Rexrode and Stampfer25) or elderly people(Reference Mozaffarian, Longstreth and Lemaitre6) in the USA whereas a large-scale population-based cohort study in Japan suggested that fish consumption, among some other animal products, may reduce the risk of intracerebral haemorrhage(Reference Sauvaget, Nagano and Allen26). He et al. (Reference He, Song and Daviglus1) did not observe any significant association between fish consumption and haemorrhagic stroke risk in their meta-analysis on three large cohort studies with data on stroke subtypes.

The method of fish preparation has been considered only in a few studies. Mozaffarian et al. (Reference Mozaffarian, Longstreth and Lemaitre6) reported a lower risk of ischaemic stroke with higher consumption of tuna or other broiled or baked fish, while intake of fried fish or fish sandwiches was associated with a higher risk of stroke; neither type of fish was associated with haemorrhagic stroke, however. In the present study, salted fish, which was associated with a higher risk of haemorrhagic stroke, represents a high-salt food(Reference Pietinen27). In the present study, consumption of salted fish was correlated with sodium intake (energy-adjusted Pearson correlation coefficient 0·77; P < 0·001), and the association observed attenuated after further adjustment for sodium intake. Therefore we suggest that sodium in these fish products may be a factor increasing stroke risk, but it cannot be ruled out that other factors related to higher salted fish consumption may explain the higher stroke risk. High sodium intake is a known predictor for increased blood pressure(Reference Chobanian and Hill28, Reference Karppanen and Mervaala29) and hypertension is one of the major risk factors for stroke(30), even more so for haemorrhagic stroke(Reference Song, Sung and Lawlor31). Ecological comparisons between countries and populations indicate a direct relationship between salt consumption and stroke risk(Reference Sasaki, Zhang and Kesteloot7, Reference Xie, Sasaki and Joossens8), however, evidence from prospective studies is sparse and controversial(Reference Cohen, Hailpern and Fang9, Reference Nagata, Takatsuka and Shimizu10).

In the present study, we were able to estimate the sodium levels in natural foods and processed foods such as cheese, sausages and cured meat, salted and smoked fish, and the salt added in bread. Salt used in home cooking or added at the table was not recorded. It has been estimated from the Finnish Mobile Clinic cohort that in the 1970s, total salt consumption was approximately 14 g/d among men and approximately 10 g/d among women(Reference Pietinen27). The most important foods contributing to total salt intake were baked products, mostly bread, sausages, and salted and smoked fish, which accounted for 12 and 11 %, respectively, of the total salt intake of men and women(Reference Pietinen27). Although the contribution of salted fish to the total salt intake was not very high on average, consumption of salted fish may indicate a preference for salty foods.

In the present study, the association between salted fish and haemorrhagic stroke was more pronounced among persons with normal blood pressure, suggesting that as a transcendent risk factor of stroke, hypertension masks the effect of salted fish. On the other hand, the association observed was also more pronounced among persons with serum cholesterol values over the median. However, the serum cholesterol level itself was modestly associated with reduced risk of stroke mortality in a large meta-analysis of sixty-one prospective studies(32).

No significant associations were found between total fish consumption and the risk of total stroke or thrombotic or haemorrhagic stroke. Similarly, in several previous studies total fish consumption was not found to be significantly associated with stroke risk(Reference Bravata, Wells and Brass33Reference Yang, Shu and Jin37). However, in their meta-analysis He et al. (Reference He, Song and Daviglus1) and Bouzan et al. (Reference Bouzan, Cohen and Connor2) concluded that consumption of fish may offer protection against stroke, particularly ischaemic stroke. Even very small amounts of fish, one fish meal per month, were suggested to offer protection against ischaemic stroke(Reference He, Song and Daviglus1). In the present study, the majority of the subjects in the lowest quartile reached that level. However, we found no significant association between fish consumption and stroke even when the non-consumers of fish were compared with those with any consumption of fish at all.

A few previous studies have associated a lower risk of stroke, particularly thrombotic stroke, with a higher intake of fish-specific fatty acids(Reference He, Rimm and Merchant24, Reference Iso, Rexrode and Stampfer25). In two recent systematic reviews, the evidence of the benefits of n-3 long-chain fatty acids against stroke events was, however, considered to be inconclusive(Reference Wang, Harris and Chung3, Reference Hooper, Thompson and Harrison4). A recent study based on an analysis of fatty acids in the blood by Wennberg et al. (Reference Wennberg, Bergdahl and Stegmayr38) did not conclude that fish-specific fatty acids would decrease stroke risk. Similarly, no significant association between marine long-chain n-3 fatty acids and stroke risk was observed in the present study. In Finland, the type of fish consumed has been mainly low-fat fish. Furthermore, the majority of high-fat fish consumed among the study population was salted herring, also contributing to salt and sodium intake. No significant association was found between stroke risk and dietary mercury in the present study, which is in line the results of Wennberg et al. (Reference Wennberg, Bergdahl and Stegmayr38), who reported no association between mercury analysed in erythrocytes and stroke risk.

In addition to chance, several methodological issues may have influenced the present results. The dietary history method has its limitations, and the consequent misclassification of subjects tends to alter observable associations between dietary exposure and outcome(Reference Willett39). In the present study, all the interviewers were trained nutrition professionals, and a preformed questionnaire was used to diminish differences between interviewers. The questions were open-ended and offered opportunities to specify the answers. Likewise, food models were used to reduce errors of recall. Our prospective study design minimized the possibility that changes in diet due to prevalent disease influenced the findings. Furthermore, it is unlikely that the current discussion about the potential health effects of fish consumption has interfered with the reported fish consumption, since reports on the potential health effects did not become available until the 1980s. It is possible that a lack of information on the cases because of incomplete information on the incident cerebral infarction during the follow-up(Reference Heliövaara, Reunanen and Aromaa21) and the emigration of some persons during the follow-up period may have caused modestly conservative risk estimates.

In general, the short-term repeatability of the dietary history method was favourable, but long-term reliability was relatively poor(Reference Järvinen, Seppänen and Knekt20). The poorer long-term reliability can be explained by changes in Finnish food consumption. During the long follow-up, dietary habits may have changed and attenuated the associations observed.

In conclusion, the present findings clearly demonstrate that the relationship between fish consumption and stroke risk is not straightforward. How the fish is prepared for consumption may be an important factor affecting the association, but it may also depend on which type of stroke is being investigated.

Acknowledgements

The authors state that there are no conflicts of interest. This research received no specific grant from any funding agency in the public, commercial or not-for-profit sectors. J. M. participated in the analysis and interpretation of data and in the drafting of the manuscript. R. J. collaborated on the interpretation of the results, and participated in drafting the manuscript. P. K. contributed to the development of the analysis plan and was closely involved with the interpretation of the results and editing of the manuscript. He also supervised the conducting of the study. A. R. provided significant consultation on the interpretation of the results and editing of the manuscript.

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Figure 0

Table 1 Personal characteristics at baseline in cases of cerebrovascular disease and non-cases(Mean values and standard deviations)

Figure 1

Table 2 Mean levels of characteristics in quartiles of fish intake*(Mean values and standard deviations)

Figure 2

Table 3 Adjusted relative risks (RR) of cerebrovascular diseases in quartiles of fish consumption and intakes of marine long-chain n-3 fatty acids, mercury and sodium*

Figure 3

Table 4 Relative risk (RR) of intracerebral haemorrhages between the highest and lowest categories of consumption of fish and salted fish in strata of potential effect-modifying factors*