Hostname: page-component-78c5997874-g7gxr Total loading time: 0 Render date: 2024-11-11T13:40:54.595Z Has data issue: false hasContentIssue false
  • English
  • Français

Total fluid and specific beverage intake and mortality due to IHD and stroke in the Netherlands Cohort Study

Published online by Cambridge University Press:  11 May 2010

Lina J. Leurs ,
Leo J. Schouten ,
R. Alexandra Goldbohm  and
Piet A. van den Brandt
Lina J. Leurs
Affiliation:
Department of Epidemiology, GROW – School for Oncology and Developmental Biology, Maastricht University, PO Box 616, 6200 MD Maastricht, The Netherlands
Leo J. Schouten*
Affiliation:
Department of Epidemiology, GROW – School for Oncology and Developmental Biology, Maastricht University, PO Box 616, 6200 MD Maastricht, The Netherlands
R. Alexandra Goldbohm
Affiliation:
Department of Prevention and Health, TNO Quality of Life, Leiden, The Netherlands
Piet A. van den Brandt
Affiliation:
Department of Epidemiology, GROW – School for Oncology and Developmental Biology, Maastricht University, PO Box 616, 6200 MD Maastricht, The Netherlands
*
*Corresponding author: Dr L. J. Schouten, fax +31 43 3884128, email lj.schouten@epid.unimaas.nl
Rights & Permissions [Opens in a new window]

Abstract

Chronic mild dehydration has been associated with several diseases, including fatal IHD and stroke. It has been suggested that hydration through total fluid intake (or water) is inversely associated with IHD or stroke mortality. The objective of the present study was to evaluate the relationship between total fluid (and specific beverage) intake and IHD or stroke mortality in the Netherlands Cohort Study (NLCS). In 1986, 120 852 participants aged 55–69 years were enrolled into the NLCS. Mortality data were collected over a 10-year follow-up period. Analysis was done through a case–cohort approach, and it was based on the subjects without a history of heart disease, stroke or diabetes at baseline. A total of 1789 IHD mortality cases and 708 stroke mortality cases occurred during the follow-up. Higher total fluid consumption was not associated with either IHD mortality or stroke mortality in men or women. When analysing specific beverages, a positive association between coffee consumption (increment 270 ml/d) and IHD mortality was observed in men (hazard ratio (HR) 1·09, 95 % CI 1·00, 1·18), while an inverse relationship was observed in women (HR: 0·88, 95 % CI 0·78, 1·00). For tea consumption (increment of 253 ml/d), an inverse relationship with IHD mortality was observed in men (HR: 0·91, 95 % CI 0·83, 1·00). No association with water intake was observed. In the study population, fresh water consumption was very low. In conclusion, total fluid intake was not associated with IHD or stroke mortality in either men or women. Coffee consumption was inversely associated with IHD mortality in women only, while a higher tea intake was associated with lower IHD mortality in men only.

Keywords

Beverage intakeIschaemic heart diseaseStrokeMortalityProspective cohort studies
Type
Full Papers
Information
British Journal of Nutrition , Volume 104 , Issue 8 , 28 October 2010 , pp. 1212 - 1221
Copyright
Copyright © The Authors 2010

Proper hydration is necessary for the body to sustain normal physiological functioning such as the transportation of nutrients, excretion and the regulation of body temperature. Chronic mild to moderate dehydration has been associated with several disease states, such as fatal CHD and CVD(Reference Chan, Knutsen and Blix1). The association between chronic mild dehydration and CHD may be explained by the elevation in haemorheological factors(Reference Dvilansky, Bar-Am and Nathan2, Reference Kristal-Boneh, Glusman and Chaemovitz3). Haemorheological factors that are independently positively associated with CHD are the whole-blood viscosity, plasma viscosity, fibrinogen and haematocrit levels(Reference Lowe, Lee and Rumley4Reference Erikssen, Thaulow and Sandvik8). These factors respond acutely to changes in hydration, which can occur, e.g. during normal daily activities and the use of medications such as diuretics(Reference Kurabayashi, Kubota and Tamura9Reference Yasaka, Yamaguchi and Oita12). Furthermore, it has been suggested that water consumption at night can attenuate nocturnal increase in blood viscosity, and therefore, can prevent morning occurrence of cerebral infarction(Reference Kurabayashi, Kubota and Tamura9). Some investigators reported a decrease in blood viscosity with increased water intake(Reference Kurabayashi, Kubota and Tamura9, Reference Okamura, Washimi and Endo13, Reference Wood14), while others reported no changes in blood haemorheology and chemistry with increased water intake(Reference Tonstad, Klemsdal and Landaas15).

Only one cohort study analysed the effect of water intake and other fluid intake on fatal CHD(Reference Chan, Knutsen and Blix1). The above-mentioned study, which was done by Chan et al., found a protective effect of water intake on mortality related to CHD in men but not in women. In contrast, a high intake of ‘fluids other than water’ was associated with an increased mortality risk in women but not in men. The authors explained these findings by the typically lower blood viscosity (lower haematocrit levels, erythrocyte rigidity and aggregability at all shear rates) in women(Reference de Simone, Devereux and Chien7). Because of the lower blood viscosity, women experience less reduction in plasma volume with dehydration, and body temperature regulation occurs at lower sweat rates(Reference Byrd, Stewart and Torranin16, Reference Rocker, Kirsch and Stoboy17). Thus, in women, reduced water intake does not produce high levels of blood viscosity as in men, which would explain why water intake is not protective in women. Because of the fact that men have larger blood volumes than women, the same quantities of hyperosmolar fluids or caffeinated beverages produce a lower proportionate decrease in intravascular volume and subsequently smaller increase in blood viscosity, explaining why ‘fluids other than water’ have smaller effects on CHD mortality in men(Reference Neuhauser, Beine and Verwied18Reference Bhalla, Sankaralingam and Dundas20).

The effect of other beverages such as coffee and tea on IHD or stroke mortality has also been reported previously in the literature, but inconsistent results were obtained. A meta-analysis of twenty-one prospective cohort studies found a positive association between coffee and IHD in men, while coffee drinking was associated with a lower risk of IHD in women(Reference Wu, Ho and Zhou21).

Also, the effect of tea intake on IHD mortality has been reported to be either inverse, no association, or even positive(Reference Geleijnse, Launer and Hofman22Reference Woodward and Tunstall-Pedoe27).

The lack of sufficient evidence on the relationship between total fluid and other beverage intake and mortality related to IHD or stroke led to the investigation of this association in the Netherlands Cohort Study (NLCS). Due to the detailed collection on dietary and drinking habits in the NLCS, we were able to analyse the association between total fluid (and specific beverage) intake and IHD and stroke mortality, with the possibility of adjustment for potential confounding factors.

Methods

Study population

In September 1986, the population-based prospective NLCS on diet and cancer was started. In this cohort study, 58 279 men and 62 573 women aged between 55 and 69 years living throughout the Netherlands were included(Reference van den Brandt, Goldbohm and van't Veer28). Because of efficiency reasons, a case–cohort approach was used for data processing and statistical analysis(Reference Prentice29, Reference Wacholder, Gail and Pee30). In a case–cohort design, cases are collected from the entire cohort, while detailed follow-up information of a random subcohort provides an estimate of the person-time experience of the cohort. In the NLCS, this subcohort consisted of 5000 cohort members extracted randomly from the entire study population immediately after baseline. The subcohort was followed up biennially for vital status information. Only two male subcohort members were lost to follow-up during the 10-year follow-up period. The study design has been described in detail previously(Reference van den Brandt, Goldbohm and van't Veer28). The NLCS was approved by the institutional review boards of the Maastricht University and the Netherlands Organization for Applied Scientific Research. All cohort members consented to participate in the study by completing a mailed, self-administered questionnaire.

Data collection

All the 120 852 cohort members completed a self-administered questionnaire on dietary habits, beverage consumption, anthropometry and other risk factors related to cancer and CVD at baseline(Reference van den Brandt, Goldbohm and van't Veer28). Habitual consumption of food and beverages during the year preceding the start of the study was assessed using a 150-item semi-quantitative food frequency section of the questionnaire. Validation of this questionnaire was done against a 9 d diet record(Reference Goldbohm, van den Brandt and Brants31). The Spearman correlation coefficient between mean daily intake of non-alcoholic beverages assessed by the questionnaire and that estimated from the 9 d diet record was 0·63. The Spearman correlation coefficient between mean daily intake of alcoholic beverages assessed by the questionnaire and that estimated from the 9 d diet record was 0·89(Reference Goldbohm, van den Brandt and Brants31). Specific nutrient intakes were calculated from this section of the questionnaire using the computerised Dutch food composition table(32). Nutrient intake was adjusted for energy intake using the residual method(Reference Willett and Stampfer33).

Assessment of total fluid and specific beverage intake

Of the 150 FFQ items, twenty-four addressed beverage consumption. The questionnaire covered almost all beverages consumed regularly, namely water (tap or bottled), milk (i.e. milk, buttermilk, cocoa), juice (i.e. tomato, orange, others), soda and lemonade (i.e. cola, others), alcoholic beverages (i.e. beer, red wine, white wine, sherry, port, liqueur, spirits), soup, coffee and tea. The amount of beverages consumed was measured in household units (glasses, cups, soup plates, etc.). The participants could indicate the frequency of beverage consumption and the portion size. During the validation study, the capacity of the household units was measured by a dietitian who visited the subjects(Reference Goldbohm, van den Brandt and Brants31). The standardised size of a glass measured 175 ml, a cup (coffee or tea) 125 ml and a soup plate 250 ml. Based on the questionnaire data, the total fluid consumption was calculated using information on frequency and beverage-specific serving size of all the specific beverages. When subjects reported of drinking a specific beverage but did not report the number of units, a default number was used based on the mean number reported by the other drinkers.

Ascertainment of cases

Follow-up for mortality data was established by linkage of the NLCS to the central bureau of genealogy. Using this record linkage, 18 091 deaths were identified between January 1987 and December 1996. On the basis of the collected subcohort data on vital status, it could be estimated that the Central Bureau of Genealogy linkage was complete for 99 %. The causes of death, coded in international classification of diseases (ICD)-9 until December 1995 and in ICD-10 from January 1996, were obtained by the linkage to Statistics Netherlands. Using this linkage, the cause of death was obtained for 18 045 (99·7 %) of the 18 091 deceased. The primary cause of death was related to CHD (ICD-9 code 390-459/ICD-10 code I00-I99) in 37·2 % (n 6735) of all deaths. In the present analysis, CHD-related mortality was analysed as death due to IHD (ICD-9 code 410-414/ICD-10 code I20-I25, n 3610) or CVD (stroke) (ICD-9 code 430-435/ICD-10 code I60-I69, n 1204).

Statistical analysis

Analysis was confined to participants who did not report physician-diagnosed heart disease, stroke or diabetes as indicated in the baseline questionnaire (exclusion of 3066 subjects). Additionally, subjects with incomplete or inconsistent dietary data (n 1010) were excluded from the analysis, leaving 1789 IHD mortality cases, 708 stroke cases and 3970 subcohort members available for the analysis. For categorical analysis, the lowest consumption stratum was chosen as the reference category. Because different associations between consumption of water and fluids other than water and cardiovascular mortality for males and females have been reported in the literature, we conducted all the analyses separately for men and women(Reference Chan, Knutsen and Blix1). For each sex, the hazard ratios (HR) and the corresponding 95 % CI were calculated by means of a Cox proportional hazards model. The proportional hazards assumption was tested using the scaled Schoenfeld residuals(Reference Schoenfeld34). When this test indicated that the assumption was violated, the − ln( − ln) survival plots were used to assess the proportional hazards assumption. Standard errors were estimated using the robust Huber–White sandwich estimator to account for additional variance introduced by sampling a subcohort from the total cohort(Reference Lin and Wei35).

The multivariable regression models included the following variables: age at baseline (years), sex (if applicable), cigarette smoking (current, frequency and duration) and energy intake (kcal/d). The following variables were considered as potential confounders (other known IHD risk factors or factors influencing total fluid consumption), but were not included in the models because they did not change the HR by >5 %: hypertension (yes/no), BMI (kg/m2), physical inactivity (coded in four categories: very little, average, active or very active), educational level (coded as primary school, lower vocational, high school (junior and senior) and higher vocational/university), fat consumption (g/d), fruit and vegetable consumption (g/d), hormone-replacement therapy (yes/no) (for women only), use of diuretics (yes/no) and multivitamin intake (yes/no)).

When separate beverages were analysed, a second model was used with additional correction for the intake of fluids other than the analysed beverage (e.g. analysis for coffee was corrected for the intake of beverages other than coffee). In none of the beverage-specific analyses did this additional correction with other beverage intake change the HR of the first model. Also, additional adjustment for the ethanol compound of alcoholic beverages (coded in categories 0, 0·1–4, 5–14, 15–29 g/d, ≥ 30 g/d) did not change any of the reported HR substantially. Therefore, only the results of the first model are presented in this report.

When the intake of beverages was analysed as a continuous variable, the HR was calculated per one standard deviation increment (calculated for men and women together). Tests for trends were assessed by fitting the ordinal exposure variables as continuous terms. A two-sided P value of 0·05 or less was considered as statistically significant.

Results

During the 10-year follow-up period, 1789 deaths primarily related to IHD have been reported. Of these deaths, 1252 (70·0 %) occurred in the male population, and 537 (30·0 %) occurred in the female population. Stroke mortality occurred in 708 subjects, of which, 417 (58·9 %) were males and 291 (41·1 %) were females.

The mean daily total fluid consumption from beverages was 1462 ml/d in the male subcohort, and 1341 ml/d in the female subcohort (Table 1). The major beverages consumed in the male and female subcohorts were coffee (mean 581 and 498 ml/d, respectively), tea (mean 319 and 384 ml/d, respectively) and milk (mean 187 and 181 ml/d, respectively). Only a very little amount of the daily total fluid intake was in the form of water consumption (mean 82 ml/d in men and 109 ml/d in women). Potential confounders in the present analyses are also described in Table 1. Compared with the subcohort members, subjects who suffered from fatal IHD or stroke were more often smokers, hypertensive, and less physically active.

Table 1 Descriptive analysis of potential confounders of subcohort members and cases of IHD- and stroke-related mortality, Netherlands Cohort Study, 1987–96

(Mean values with their standard errors, number, percentages and ranges)

NA, not applicable.

Total fluid consumption

When analysing total fluid consumption on a continuous scale with an increment of 431 (1 sd) ml/d, no association between total fluid and water intake and IHD or stroke mortality was found in either men or women (see Tables 2 and 3).

Table 2 Association of the different fluid consumptions and IHD mortality in the Netherlands Cohort Study, 1987–96

(Hazard ratios (HR) and 95 % confidence intervals)

* Adjusted for age.

Adjusted for age, current smoking, number of cigarettes smoked, years of active smoking and total energy intake (kcal).

This P or HR has to be interpreted with care, because the categorical analysis shows a strong U-shaped association.

§ One cup = 125 ml.

Table 3 Association of the different fluid consumptions and stroke mortality in the Netherlands Cohort Study, 1987–96

(Hazard ratios (HR) and 95 % confidence intervals)

* Adjusted for age.

Adjusted for age, current smoking, number of cigarettes smoked, years of active smoking and total energy intake (kcal).

One cup = 125 ml.

§ This P or HR has to be interpreted with care, because the categorical analysis shows a strong U-shaped association.

Categorisation of total fluid consumption revealed that 41 % of the male and 30 % of the female subcohort members consumed the recommended daily dose of total fluids (at least 1·5 litres total fluid per d). It was revealed that 38 % of the male subjects and 31 % of the female subjects who suffered from fatal IHD, and 39 % males and 28 % females who died of stroke had drunk at least 1·5 litres of total fluids. Drinking at least 1·5 litres of total fluids was not related to IHD or stroke mortality compared with drinking less than the recommended daily dose in men or women. Also, analysis over five total fluid categories did not reveal an association between total fluid intake and IHD mortality in men or women. HR for the association between total fluid intake and stroke mortality were all below 1, but were not statistically significant.

Total fluid intake (consumption of at least 1·5 v. < 1·5 litres) was not associated with IHD and stroke mortality across different subgroups of the population defined by risk factors for CVD (sex, smoking, hypertension and BMI) (Table 4).

Table 4 Analyses for the detection of potential effect modification

(Hazard ratios (HR) and 95 % confidence intervals)*

* Hazard rates of mortality related to IHD and stroke in groupings of different CVD risk factors among men and women who reported no physician-diagnosed heart disease, angina pectoris, stroke or diabetes, and where the exposure is consumption of the daily recommended dose (1·5 litres fluids) in the Netherlands Cohort Study, 1987–96

Adjusted for sex, age, current smoking, number of cigarettes smoked, years of active smoking and total energy intake (kcal).

Specific beverage consumption

In men, a positive association between increasing coffee intake and IHD mortality was observed (HR per increment of 1 sd: 1·09, 95 % CI 1·00, 1·18), while an inverse relationship between increasing tea consumption (increment of 1 sd) and IHD mortality was observed (HR: 0·91, 95 % CI 0·83, 1·00) (Table 2). In women, an inverse association between coffee consumption (increment of 1 sd) and IHD mortality was observed (HR: 0·88, 95 % CI 0·78, 1·00), while a positive (not statistically significant) relationship between increasing tea consumption (increment of 1 sd) and IHD mortality was observed (HR: 1·08, 95 % CI 0·97, 1·20). No relationship was observed between milk, soft drink, juice, soup and alcoholic beverage consumption and IHD mortality. When the endpoint was stroke mortality, no associations with separate beverages were observed (Table 3), except for the intake of alcoholic beverages in females. In females, intake of alcoholic beverages (per 1 sd or 166 ml/d) was inversely associated with stroke mortality (HR: 0·66, 95 % CI 0·44, 0·97).

We analysed the observed relationship between coffee and tea intake and IHD mortality more detailedly using categorical variables for these beverages. In the categorical analysis, the positive association between coffee consumption and IHD mortality in men was not statistically significant. For tea, we observed that all categories of tea intakes (moderate (1–2 cups/d) and high tea consumption (>3 cups/d)) were inversely related to IHD mortality in men (HR: 0·75; 95 % CI 0·61, 0·93 and HR: 0·71, 95 % CI 0·57, 0·88, respectively (P-trend = 0·007)) compared with 0–1 cup/d of tea consumption (Table 2).

In women, a more detailed analysis of coffee consumption revealed an inverse dose–response relationship with IHD mortality (P-trend = 0·01). In the categorical analysis, the positive association between tea consumption and IHD mortality in women was no longer significant.

The association between coffee and tea consumption categories and IHD and stroke mortality was relatively consistent across different subgroups of the population defined by risk factors for CVD (sex, smoking, hypertension and BMI) (data not shown).

Water as such was not consumed by 53 % of the male and 43 % of the female subcohort members, 57 % of the males and 45 % of the females who died of IHD and 56 % of males and 46 % of the females who died of stroke. In men, drinking any water compared with drinking no water at all was not statistically significantly associated with a reduced risk of IHD mortality (HR: 0·87, 95 % CI 0·74, 1·03) in the multivariate analysis. In women, drinking any water compared with drinking no water at all was not associated with IHD mortality (HR: 0·92, 95 % CI 0·75, 1·11). When stroke mortality was the endpoint, no significant association with water consumption was observed in men or women. When analysing water in five categories, we observed a decreased HR of IHD mortality for male subjects who consumed between >0 and 100 ml water a day compared with those consuming no water (HR: 0·69, 95 % CI 0·55, 0·87). With the other water categories also, no relationship was observed (P-trend = 0·68). Also, when stroke mortality was the outcome measure, no relationship between any of the five water categories was observed in men. In women, no relationship between any of the five water categories and IHD or stroke mortality was observed.

Discussion

We found no overall association between total fluid intake and IHD or stroke mortality in either men or women. However, a positive association between coffee consumption and IHD mortality was observed in men, while the opposite (inverse association between coffee intake and IHD mortality) was observed in women. For tea consumption, we observed an inverse relationship with IHD mortality in the male subjects, but not in the female subjects. In women, except for the intake of alcoholic beverages, no associations were observed when stroke mortality was the outcome measure.

We observed that a higher coffee consumption was statistically significantly associated with lower IHD mortality in women, while the opposite was observed in men. These opposite results are in line with the results of a meta-analysis of twenty-one prospective cohort studies(Reference LeGrady, Dyer and Shekelle36). The reason for this sex difference, however, is unknown. Apart from a direct effect of coffee consumption on IHD mortality, it is also known that coffee consumption is strongly associated with smoking. Smoking is often associated with unhealthier lifestyle habits (e.g. physical inactivity, alcohol abuse) compared with non-smoking(Reference LeGrady, Dyer and Shekelle36). We adjusted for inter alia smoking in our multivariate analysis – and this changed the HR estimates in women substantially – but adjustment for these factors may not have completely eliminated their influence on the coffee–IHD association, and therefore, may partially explain the observed sex differences. The positive association between IHD and coffee consumption in men has also been reported in previous studies(Reference Rosengren and Wilhelmsen37Reference Urgert and Katan40). In the meta-analysis done by Wu et al., the 1 pooled HR for males with heavy (5–6 cups/d) and very heavy ( ≥ 7 cups/d) coffee consumption (HR: 1·07, 95 % CI 0·91, 1·26 and HR: 1·15, 95 % CI 0·91, 1·46) were slightly elevated, but they did not reach statistical significance(Reference LeGrady, Dyer and Shekelle36). The positive association between coffee consumption and IHD can be explained by diterpenes cafestol and kahweol that are present in unfiltered coffee(Reference Weusten-Van der Wouw, Katan and Viani41Reference Tverdal, Stensvold and Solvoll43). Cafestol and kahweol are potent cholesterol-elevating compounds present in coffee, which are independently associated with the risk of CVD(Reference Hammar, Andersson and Alfredsson44, Reference Coats45). However, in the Netherlands, mainly filtered coffee is consumed, in which the concentration of these diterpenes is very low and not associated with the elevated risk of IHD.

Tea consumption was inversely associated with IHD mortality in the male study population. The potential beneficial effect of tea on IHD has been reported previously(Reference Klag, Mead and LaCroix39Reference Weusten-Van der Wouw, Katan and Viani41). However, other studies found no association or even a positive association between tea intake and IHD mortality(Reference Klatsky, Armstrong and Friedman25Reference Woodward and Tunstall-Pedoe27) Our analysis also suggests a sex difference for the association between tea intake and IHD mortality, but not as clearly as has been suggested for coffee. As mentioned in the previous section, the observed opposite effect could partially be explained by the fact that we have not been able to remove all the confounding effects(Reference Woodward and Tunstall-Pedoe27). We observed that when coffee and tea consumptions were included together in the multivariate analyses, the HR did not change substantially. The intriguing differences between the sexes observed for both coffee and tea indicate that further investigation of the responsible compounds and the biological mechanisms involved has to be done.

The effect of water intake on fatal CHD was analysed in only one other study(Reference Chan, Knutsen and Blix1). In contrast to the study done by Chan et al., we found no association between the intake of water and fluids other than water and mortality related to IHD. The reason for us not finding an association could be the marked differences in drinking habits between the present study population and the population analysed by Chan et al. The average water consumption in the Adventist population was approximately 1000 ml/d, while it was approximately 95 ml/d in the NLCS population. The reported total fluid intake from beverages was around 2 litres/d in the Adventist population, and was 1·4 litres/d in the present study population. Another possible reason for the different results is that in these observational studies, the results have been biased by confounding. Subjects who drink more water could be more health conscious, e.g. drinking more water may be a marker of higher physical activity(Reference Chan, Knutsen and Blix1). We corrected for potential confounders such as physical activity in the multivariate analyses. Diabetics, who may drink more fluids, and are at increased risk of IHD and stroke, were excluded from these analyses. Furthermore, the null association was relatively consistent across subgroups of the population.

The strengths of the present study include the relatively large number of cases in a prospective cohort; the ability to examine the intake of total fluid and specific beverages in relation to the risk of IHD and stoke mortality due to the broad data collection on commonly consumed beverages (including water); the possibility to control for a broad spectrum of confounders such as age, cigarette smoking, hypertension and the intake of other fluids besides the one under investigation.

One disadvantage of the present study is the low consumption of fresh water. Of the male and female subcohort members, 53 and 43 %, respectively, reported that they did not consume any fresh water at all. Another disadvantage is that when subjects reported of drinking a specific beverage but did not report the number of units, a default number was used based on the mean number reported by the other drinkers. This could lead to reduction of the variance of the variable. However, this occurred in only a limited number of participants.

In conclusion, total fluid intake was not associated with IHD- or stroke-related mortality in either men or women in the NLCS. Coffee consumption was inversely associated with IHD mortality in women and it was positively associated with it in men, while tea consumption was inversely associated with IHD mortality in men, but not in women.

Acknowledgements

None of the authors has a financial or personal conflict of interest. This manuscript has been read by all the authors who accept responsibility for its contents. L. J. L. participated in all the processes of the present research topic. L. J. S. assisted with the statistical analysis. L. J. S. and P. A. v. d. B. contributed to writing of the manuscript and R. A. G. contributed to the refining of the manuscript. The present study was funded by KWR, Watercycle Research Institute. This project was conducted within the Joint Research Programme of the Dutch water companies by researchers from the Maastricht University and Kiwa Water Research. External review of the design and results was conducted by a Scientific Advisory Committee consisting of Professor P. Hunter (University of East Anglia, Norwich, United Kingdom), Professor R. Rylander (Emeritus Professor, Sweden) and M.I. Sinclair (Water Quality Research Australia Limited, Monash University, Australia). The authors are much indebted for their valuable comments and, in addition, would like to thank Margreet Mons for initiating this project and for her involvement in the design and advice. They also thank A. Volovics and A. Kester for statistical advice; S. van de Crommert, H. Brants, J. Nelissen, C. de Zwart, M. Moll, W. van Dijk and A. Pisters for assistance; and H. van Montfort, T. van Moergastel, L. van den Bosch, R. Schmeitz and J. Berben for programming assistance. Furthermore, they are indebted to all the participants of the present study and the Dutch Central Bureau of Genealogy and Statistics Netherlands for data provision.

References

1 Chan, J, Knutsen, SF, Blix, GG, et al. (2002) Water, other fluids, and fatal coronary heart disease: the Adventist Health Study. Am J Epidemiol 155, 827833.CrossRefGoogle ScholarPubMed
2 Dvilansky, A, Bar-Am, J, Nathan, I, et al. (1979) Hematologic values in healthy older people in the Negev area. Isr J Med Sci 15, 821825.Google ScholarPubMed
3 Kristal-Boneh, E, Glusman, JG, Chaemovitz, C, et al. (1988) Improved thermoregulation caused by forced water intake in human desert dwellers. Eur J Appl Physiol Occup Physiol 57, 220224.CrossRefGoogle ScholarPubMed
4 Lowe, GD, Lee, AJ, Rumley, A, et al. (1997) Blood viscosity and risk of cardiovascular events: the Edinburgh Artery Study. Br J Haematol 96, 168173.CrossRefGoogle ScholarPubMed
5 Koenig, W, Sund, M, Filipiak, B, et al. (1998) Plasma viscosity and the risk of coronary heart disease: results from the MONICA – Augsburg Cohort Study, 1984 to 1992. Arterioscler Thromb Vasc Biol 18, 768772.CrossRefGoogle ScholarPubMed
6 Ernst, E (1995) Haematocrit and cardiovascular risk. J Intern Med 237, 527528.CrossRefGoogle ScholarPubMed
7 de Simone, G, Devereux, RB, Chien, S, et al. (1990) Relation of blood viscosity to demographic and physiologic variables and to cardiovascular risk factors in apparently normal adults. Circulation 81, 107117.CrossRefGoogle ScholarPubMed
8 Erikssen, G, Thaulow, E, Sandvik, L, et al. (1993) Haematocrit: a predictor of cardiovascular mortality? J Intern Med 234, 493499.CrossRefGoogle ScholarPubMed
9 Kurabayashi, H, Kubota, K, Tamura, J, et al. (1991) A glass of water at midnight for possible prevention of cerebral infarction. Stroke 22, 13261327.CrossRefGoogle Scholar
10 Seaman, GV, Engel, R, Swank, RL, et al. (1965) Circadian periodicity in some physicochemical parameters of circulating blood. Nature 207, 833835.CrossRefGoogle ScholarPubMed
11 Vandewalle, H, Lacombe, C, Lelievre, JC, et al. (1988) Blood viscosity after a 1-h submaximal exercise with and without drinking. Int J Sports Med 9, 104107.CrossRefGoogle ScholarPubMed
12 Yasaka, M, Yamaguchi, T, Oita, J, et al. (1993) Clinical features of recurrent embolization in acute cardioembolic stroke. Stroke 24, 16811685.CrossRefGoogle ScholarPubMed
13 Okamura, K, Washimi, Y, Endo, H, et al. (2005) Can high fluid intake prevent cerebral and myocardial infarction? [Systematic review]. Nippon Ronen Igakkai Zasshi 42, 557563.CrossRefGoogle ScholarPubMed
14 Wood, JH (1987) Response to the editor: is the circadian change in hematocrit and blood viscosity a factor triggering cerebral and myocardial infarction? Stroke 18, 813.Google Scholar
15 Tonstad, S, Klemsdal, TO, Landaas, S, et al. (2006) No effect of increased water intake on blood viscosity and cardiovascular risk factors. Br J Nutr 96, 993996.CrossRefGoogle ScholarPubMed
16 Byrd, R, Stewart, L, Torranin, C, et al. (1977) Sex differences in response to hypohydration. J Sports Med Phys Fitness 17, 6568.Google ScholarPubMed
17 Rocker, L, Kirsch, K, Stoboy, H, et al. (1977) The influence of heat stress on plasma volume and intravascular proteins in sedentary females. Eur J Appl Physiol Occup Physiol 36, 187192.CrossRefGoogle ScholarPubMed
18 Neuhauser, B, Beine, S, Verwied, SC, et al. (1997) Coffee consumption and total body water homeostasis as measured by fluid balance and bioelectrical impedance analysis. Ann Nutr Metab 41, 2936.Google Scholar
19 Bell, S, Anderson, F, Bistrian, B, et al. (1987) Osmolality of beverages commonly provided on clear and full liquid menu. Nutr Clin Pract 2, 241244.CrossRefGoogle Scholar
20 Bhalla, A, Sankaralingam, S, Dundas, R, et al. (2000) Influence of raised plasma osmolality on clinical outcome after acute stroke. Stroke 31, 20432048.CrossRefGoogle ScholarPubMed
21 Wu, JN, Ho, SC, Zhou, C, et al. (2009) Coffee consumption and risk of coronary heart diseases: a meta-analysis of 21 prospective cohort studies. Int J Cardiol 137, 216225.CrossRefGoogle ScholarPubMed
22 Geleijnse, JM, Launer, LJ, Hofman, A, et al. (1999) Tea flavonoids may protect against atherosclerosis: the Rotterdam Study. Arch Intern Med 159, 21702174.CrossRefGoogle ScholarPubMed
23 Sesso, HD, Gaziano, JM, Buring, JE, et al. (1999) Coffee and tea intake and the risk of myocardial infarction. Am J Epidemiol 149, 162167.CrossRefGoogle ScholarPubMed
24 Arts, IC, Hollman, PC, Feskens, EJ, et al. (2001) Catechin intake might explain the inverse relation between tea consumption and ischemic heart disease: the Zutphen Elderly Study. Am J Clin Nutr 74, 227232.CrossRefGoogle ScholarPubMed
25 Klatsky, AL, Armstrong, MA & Friedman, GD (1993) Coffee, tea, and mortality. Ann Epidemiol 3, 375381.CrossRefGoogle ScholarPubMed
26 Hertog, MG, Sweetnam, PM, Fehily, AM, et al. (1997) Antioxidant flavonols and ischemic heart disease in a Welsh population of men: the Caerphilly Study. Am J Clin Nutr 65, 14891494.CrossRefGoogle Scholar
27 Woodward, M & Tunstall-Pedoe, H (1999) Coffee and tea consumption in the Scottish Heart Health Study follow up: conflicting relations with coronary risk factors, coronary disease, and all cause mortality. J Epidemiol Community Health 53, 481487.CrossRefGoogle ScholarPubMed
28 van den Brandt, PA, Goldbohm, RA, van't Veer, P, et al. (1990) A large-scale prospective cohort study on diet and cancer in The Netherlands. J Clin Epidemiol 43, 285295.CrossRefGoogle ScholarPubMed
29 Prentice, RA (1986) A case–cohort design for epidemiologic cohort studies and disease prevention trials. Biometrika 73, 111.CrossRefGoogle Scholar
30 Wacholder, S, Gail, M & Pee, D (1991) Selecting an efficient design for assessing exposure–disease relationships in an assembled cohort. Biometrics 47, 6376.CrossRefGoogle Scholar
31 Goldbohm, RA, van den Brandt, PA, Brants, HA, et al. (1994) Validation of a dietary questionnaire used in a large-scale prospective cohort study on diet and cancer. Eur J Clin Nutr 48, 253265.Google Scholar
32 Nevo-table (1986) Nederlands voedingsstoffenbestand 1986–1987 (Dutch Food Composition Table 1986–1987). The Hague: Voorlichtingsbureau voor de Voeding.Google Scholar
33 Willett, W & Stampfer, MJ (1986) Total energy intake: implications for epidemiologic analyses. Am J Epidemiol 124, 1727.CrossRefGoogle ScholarPubMed
34 Schoenfeld, D (1982) Partial residuals for the proportional hazards regression model. Biometrika 69, 239241.CrossRefGoogle Scholar
35 Lin, D & Wei, LJ (1989) The robust inference for the Cox proportional hazards model. J Am Stat Assoc 84, 10741078.CrossRefGoogle Scholar
36 LeGrady, D, Dyer, AR, Shekelle, RB, et al. (1987) Coffee consumption and mortality in the Chicago Western Electric Company Study. Am J Epidemiol 126, 803812.CrossRefGoogle ScholarPubMed
37 Rosengren, A & Wilhelmsen, L (1991) Coffee, coronary heart disease and mortality in middle-aged Swedish men: findings from the Primary Prevention Study. J Intern Med 230, 6771.CrossRefGoogle ScholarPubMed
38 Lindsted, KD, Kuzma, JW & Anderson, JL (1992) Coffee consumption and cause-specific mortality. Association with age at death and compression of mortality. J Clin Epidemiol 45, 733742.CrossRefGoogle ScholarPubMed
39 Klag, MJ, Mead, LA, LaCroix, AZ, et al. (1994) Coffee intake and coronary heart disease. Ann Epidemiol 4, 425433.CrossRefGoogle ScholarPubMed
40 Urgert, R & Katan, MB (1996) The cholesterol-raising factor from coffee beans. J R Soc Med 89, 618623.CrossRefGoogle ScholarPubMed
41 Weusten-Van der Wouw, MP, Katan, MB, Viani, R, et al. (1994) Identity of the cholesterol-raising factor from boiled coffee and its effects on liver function enzymes. J Lipid Res 35, 721733.CrossRefGoogle ScholarPubMed
42 Heckers, H, Gobel, U & Kleppel, U (1994) End of the coffee mystery: diterpene alcohols raise serum low-density lipoprotein cholesterol and triglyceride levels. J Intern Med 235, 192193.CrossRefGoogle ScholarPubMed
43 Tverdal, A, Stensvold, I, Solvoll, K, et al. (1990) Coffee consumption and death from coronary heart disease in middle aged Norwegian men and women. Br Med J 300, 566569.CrossRefGoogle ScholarPubMed
44 Hammar, N, Andersson, T, Alfredsson, L, et al. (2003) Association of boiled and filtered coffee with incidence of first nonfatal myocardial infarction: the SHEEP and the VHEEP study. J Intern Med 253, 653659.CrossRefGoogle ScholarPubMed
45 Coats, A (2009) Ethical authorship and publishing. Int J Cardiol 131, 149150.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Descriptive analysis of potential confounders of subcohort members and cases of IHD- and stroke-related mortality, Netherlands Cohort Study, 1987–96(Mean values with their standard errors, number, percentages and ranges)

Figure 1

Table 2 Association of the different fluid consumptions and IHD mortality in the Netherlands Cohort Study, 1987–96(Hazard ratios (HR) and 95 % confidence intervals)

Figure 2

Table 3 Association of the different fluid consumptions and stroke mortality in the Netherlands Cohort Study, 1987–96(Hazard ratios (HR) and 95 % confidence intervals)

Figure 3

Table 4 Analyses for the detection of potential effect modification(Hazard ratios (HR) and 95 % confidence intervals)*