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Nutrition and respiratory health in adults: findings from the Health Survey for Scotland

International Centre for Health and Society, Dept of Epidemiology and Public Health, Royal Free and University College Medical School, London, UK

CORRESPONDENCE: Y. Kelly, International Centre for Health and Society, Dept of Epidemiology and Public Health, Royal Free and University College Medical School, 1–19 Torrington Place, London, WCIE 6BT, UK. Fax: 44 2078130280. E-mail: y.kelly@public-health.ucl.ac.uk

Keywords: antioxidants, diet, pulmonary function, respiratory symptoms

Received: June 28, 2002
Accepted December 2, 2002

The 1995 Health Survey for Scotland was funded by the Scottish Office. Y. Kelly is funded by the Higher Education Funding Council for England, A. Sacker and M. Marmot are funded by the Medical Research Council.

	Abstract

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There is a growing body of evidence to support the hypothesised links between consumption of antioxidant rich foods and the occurrence of obstructive airway disease. The main research question was to examine the relationships between two types of dietary exposure and two indicators of respiratory morbidity in Scottish adults.

The relationships between dietary consumption of fruit, vegetables and fish, and plasma levels of vitamins A, C, E and ß-carotene, and pulmonary function (forced expiratory volume in one second (FEV₁)) and symptoms (phlegm production and shortness of breath with wheezing), were examined in a random population sample of adults.

A dose/response relationship was found between fruit consumption and pulmonary function. In comparison with eating fruit rarely or never, eating fruit at least once per day, 1–6 times per week, and 1–3 times per month were associated with differences of 132, 100 and 63 mL in FEV₁, after adjustment for known confounders and dietary intake of vegetables and fish (n=6186). An sd score change in plasma vitamin C was associated with a 49 mL difference in FEV₁ (n=930). Fruit and vitamin E were associated with a reduced prevalence of phlegm production for 3 months or more per year.

The most beneficial combination of dietary components may be found in natural foodstuffs, particularly fresh fruit.

Improved understanding of factors that could potentially be modified in order to reduce morbidity from respiratory disease is clearly desirable.

The hypothesised association between antioxidant and omega-3 fatty acids and/or the foods rich in these, and aspects of airways disease, has biological plausibility. Particular antioxidants, such as vitamins A, C and E, and ß-carotene, protect body tissues from potentially harmful oxidative damage, 1 and omega-3 fatty acids, which are present in fish, have been shown to reduce the potency of inflammatory mediators, such as prostaglandin E₂ 2.

Consumption of fresh fruit has been positively associated with pulmonary function, both cross-sectionally 3–6 and longitudinally 7. Fruit intake has also been linked to reduced prevalence of respiratory symptoms, particularly those of airway obstruction, such as wheeze 8, 9. Reported associations between fish intake and pulmonary function 4, 5, 10 and reduced prevalence of symptoms 11 are equivocal.

Few studies have examined the relationship between plasma nutrient levels and respiratory health. Of those that have, positive associations have been reported between pulmonary function and plasma vitamin C 12, 13, A 14, 15, E 13, and ß-carotene 13, 15. Furthermore, lower rates of bronchitis and wheeze have been linked to higher plasma levels of vitamin C 11. These reports have been limited because they have only considered one or two of these blood analytes on any one occasion.

Variations in the types of explanatory factors studied and their measurement, whether it is dietary intake of fruits, vegetables and fish, specific micronutrients, or plasma vitamin levels, and variations in the measurement of disease outcome, have led to inconsistencies in reported associations between diet and respiratory health. In order to clarify these relationships, the authors examined the effects of two sets of exposures, namely dietary intakes (of fruit, vegetables and fish) and plasma analytes (vitamins C, A and E and ß-carotene) on two indicators of airway disease, namely symptoms (phlegm production and shortness of breath with wheeze) and pulmonary function (forced expiratory volume in one second (FEV₁)) in the same subjects. The major dietary sources of antioxidant vitamins in this population include fruits and vegetables 16.

Data was analysed from a large random population sample of Scottish adults from the 1995 Health Survey for Scotland.

	Subjects and methods

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Sample
The1995 Scottish Health Survey was conducted to obtain data on the health of the working age population (16–64 yrs) living in private households. The sample is described in detail in the Scottish Health Survey 17. Briefly, a random sample of addresses was selected from 312 postcode sectors across Scotland. A letter was sent to each address informing residents that their household had been selected for inclusion in the survey. Each address was then visited by an interviewer who randomly selected one eligible resident. In total, 7,932 people were interviewed. The second stage of the survey was a nurse visit during which height, weight and pulmonary function measurements were taken (n=6,958, 88% of the sample), and with written consent a blood sample was obtained (n=6,183, 78% of the sample). For practical reasons it was only possible to measure plasma vitamin and carotenoid levels in a subsample of participants, as blood samples had to be processed and frozen within 4 h of venepuncture. Therefore, only postcode sectors 1 h drive of one of the seven processing laboratories were eligible for these analyses (n=1,146). Participants included in the plasma vitamin and carotenoid analyses were thus more heavily concentrated in urban areas. The subsample was similar to the whole study sample in age, sex, height, weight, smoking status and social class (table 1). These participants were more likely to report respiratory symptoms (table 2), although mean FEV₁ levels were the same in the subsample as the whole study sample.

Explanatory variables
Participants were asked how often they ate fresh fruit, raw vegetables, cooked green and root vegetables, white and nonwhite fish (see Appendix 1).

Immediately after venepuncture, blood samples were refrigerated and stored in the dark. On arrival at the laboratory, samples were processed and frozen at –40°C. Of the 1,146 blood samples obtained, 40 were not analysed for vitamins A, E and ß-carotene due to technical difficulties, 1,026 samples were analysed for vitamin C levels and 80 samples were not analysed either because of technical reasons or because participants had consumed fruit or fruit juice <1 h before venepuncture. Vitamins A, C, E and ß-carotene were measured using high-pressure liquid chromatography techniques 19, 20. As recommended, vitamin E levels were adjusted for the amount of cholesterol in the blood.

Confounders
Data were collected on known confounding factors. Those included in regression models were as follows: 1) social class of head of household (I+II (professional and managerial), III (skilled nonmanual), III (skilled manual), IV+V (semi- and unskilled manual)) 18; 2) cigarette smoking status (never, ex, current); 3) average number of cigarettes smoked per day (none, 1–10, 11–20, >20); 4) activity levels: work and leisure (inactive, light, moderate, vigorous).

Outcomes
The occurrence of the symptoms of phlegm production and attacks of shortness of breath with wheezing were assessed (see Appendix 2).

Pulmonary function was assessed by spirometry using a Vitalograph Escort Spirometer (Vitalograph, Buckingham, UK). The best of five FEV₁ measurements were used in analysis for participants who had performed the manoeuvre satisfactorily.

Data analysis
Symptoms
The effects of dietary consumption and plasma analytes on respiratory symptoms were estimated using logistic regression analysis.

To estimate the effect of fruit, vegetable and fish intake, frequency of consumption categories were entered into the models as categorical variables. To assess whether there was a dose response relationship, fruit, vegetable and fish consumption categories were entered into models as continuous variables. sd scores (Z scores) for plasma analytes were generated, and were used as continuous variables.

A three-stage modelling process was used to adjust for known confounders. Model A adjusted for age and sex, model B added in social class, cigarette smoking, and activity levels, and in model C additional adjustment was made for either other dietary intakes or other plasma analyte levels.

Pulmonary function
Using multiple linear regression, maximum FEV₁ was regressed against dietary intake of fruit, vegetables and fish, and adjusted in three stages for the confounders age, age², height, height² and sex in model A; social class, smoking status, number of cigarettes smoked per day and overall activity level in model B; and other dietary intakes or other plasma analytes in model C.

Differences in lung function (calculated for an individual of average height 1.67 m) for dietary intakes are presented using the lowest intake as the reference category. A test for dose/response was performed by entering fruit, vegetable and fish intake categories as continuous variables.

Models A, B and C were run with plasma vitamins and carotenoids as the explanatory variables. There was no deviation from linearity in the relationship between lung function and plasma analyte levels and so these predictors were entered as continuous sd scores. Differences in lung function for a one sd increase in plasma vitamin and carotenoid levels are presented.

Fruit intake and plasma vitamins were included in the same model to test whether the effect of fresh fruit on pulmonary function is due to its vitamin content. Models were also run to estimate the simultaneous affects of fruit intake and plasma vitamins on the occurrence of phlegm symptoms. Three models are presented, model A has fruit consumption as the explanatory variable, adjusting for confounders, model B has plasma analytes as the explanatory variables adjusting for the same confounders, and model C simultaneously estimates the effects of fruit intake and plasma analytes after adjustments.

To examine the possible residual confounding in associations between explanatory and outcome variables, all models were run separately for smokers and nonsmokers, nonmanual and manual social classes and levels of activity (inactive, light, moderate and vigorous). Also tested were two-way interactions between both dietary and plasma variables and social class, smoking and activity levels, in turn. There were no differences in the effect estimates when stratifications were used, and neither were there any significant interactions between the explanatory variables and the confounders. Therefore, results for all participants are presented.

	Results

TOP Abstract Subjects and methods Results Discussion References

 
Mean±sd plasma levels of vitamin C, A, and ß-carotene were 34.6±23.6, 2.47±0.79, and 0.36±0.26 µmol·L^–1, respectively, and mean vitamin E:cholesterol was 5.43±1.46. Vitamin C levels correlated with those of vitamin A and ß-carotene (0.26 and 0.25, respectively) but not with vitamin E, and vitamins A and E and ß-carotene were all correlated with one another (0.21–0.75).

Fruit, vegetable and fish intake, pulmonary function and respiratory symptoms
There was a consistent dose/response relationship between more frequent fruit and green vegetable consumption and higher FEV₁, after adjustment for age, height and sex (table 3; model A). These associations remained significant after further adjustment for confounders and intake of other foods (model C). There was a positive association between consumption of raw vegetables, cooked root vegetables, white and nonwhite fish intake and better pulmonary function (models A and B). After simultaneous adjustment for other dietary intakes these associations lost statistical significance.

Plasma antioxidants and carotenoids, and pulmonary function and respiratory symptoms
Vitamin C and ß-carotene levels were positively associated with pulmonary function, an sd score change in plasma levels corresponding to differences of 94 mL (62–126) in FEV₁ for vitamin C, and a 42 mL (10–74) difference for ß-carotene, adjusted for the effects of age, sex and height. Table 5 shows that these differences remained significant for vitamin C in the fully adjusted model C but lost statistical significance for ß-carotene after adjustment for social class, activity level and smoking. Vitamin A and E levels were not associated with pulmonary function.

	Discussion

TOP Abstract Subjects and methods Results Discussion References

 
The findings of this study add to previous studies, since the authors were able to analyse data for two types of exposure: fruit, vegetable and fish intake and plasma vitamins and carotenoids, and outcome data for two aspects of respiratory health, pulmonary function and symptoms in the same individuals.

Fruit, vegetable and fish consumption, and plasma vitamin C were shown to be positively associated with pulmonary function, and fruit intake and plasma vitamin E were associated with reduced prevalence of phlegm production.

There was a dose/response relationship between consumption of fresh fruit and pulmonary function (p<0.001). A 132 mL difference in FEV₁ between those eating fresh fruit less than once a month and those eating fruit once or more a day is consistent with other large epidemiological studies 3–7. Consumption of raw and cooked vegetables and fish were also associated with better pulmonary function, the estimated size of the effect being 30–50% that of fresh fruit. The findings for fish intake and pulmonary function are consistent with findings by Sharp et al. 10.

Fresh fruit intake was associated with a 30–40% reduction in the prevalence of phlegm in the morning in winter and phlegm for 3 months or more per year. This is consistent with the findings from a study of the onset of chronic nonspecific lung disease 21. No link with fruit intake and SOB was found with wheezing. This contrasts with analysis of the 1958 birth cohort data, when subjects were aged 33 yrs, which showed reduced risk of wheezing symptoms 8. Forastiere et al. 9 showed a protective role for fruit consumption against wheezing illness in children, though this was not demonstrated in the Ten Towns study of children 6.

A difference of 49 mL in FEV₁ was associated with an sd change in plasma vitamin C. Positive associations between plasma vitamin C and pulmonary function have been reported elsewhere 12, 13.

Plasma vitamin E was associated with a reduced prevalence of phlegm production. Previously, dietary vitamin E has been reported to be positively associated with respiratory health and allergic sensitisation in adults 4, 13, 22–26, and two population-based studies of children have suggested a beneficial role for vitamin E on respiratory health 27, 28.

The same broad consistency was not observed in the effect of plasma analytes on respiratory health as was, for example, fruit intake. There are difficulties in comparing data and interpreting analyses when the nature of the explanatory factors differ. When fruit consumption and plasma analytes were included in the same statistical models, fruit intake remained significantly associated with lung function and the prevalence of phlegm. Vitamin C was important in predicting lung function and vitamin E was associated with a reduced prevalence of phlegm in the morning during winter.

Causal inferences
Findings from this and many other studies support the original hypothesis proposed by Seaton et al. 29 that dietary factors, particularly antioxidant rich foods, influence respiratory health. Data from the current study show a dose/response relationship between dietary intakes of fruit and vegetables, and pulmonary function and respiratory symptoms. The current study reports differences in relationships between dietary intakes and plasma analytes on the prevalence of symptoms of phlegm production and SOB with attacks of wheezing. These observations may reflect different effects of diet on different aspects of airway disease.

A recent prospective study presented evidence of the reversible effects of fruit consumption on pulmonary function 7, though this was in contrast to the findings of the Caerphilly Heart study 4. Experimental data from laboratory protocols that administered large doses of vitamin C to healthy and asthmatic subjects who subsequently underwent airway hyperactivity challenges, show evidence of a protective effect of vitamin C 30, 31. In contrast, vitamin C supplementation trials in small numbers of asthmatic subjects have failed to show beneficial effects 32, 33. However, studies of combined vitamin C, E and ß-carotene supplementation in subjects exposed to ozone have shown benefits for pulmonary function 34, 35. A large vitamin E and ß-carotene supplementation trial showed no beneficial effect on symptoms associated with chronic obstructive pulmonary disease 36.

Inconsistencies that have arisen from previous observational studies are probably due to variations in measuring exposures, and to some extent outcomes, particularly with respiratory symptoms or disease definitions. The bulk of these studies are in adults and thus any inconsistencies in findings from children may be due to general physiological differences, and perhaps such study findings should not be extrapolated to adult populations.

Limitations, measurement and bias
As cross-sectional data were analysed, findings in this study should be interpreted with caution as they lack temporality. Findings from this study are consistent with many previous epidemiological reports, which are based, in the main, on cross-sectional observations.

There have been reports to support the hypothesised protective role of other dietary factors, such as flavenoids and magnesium 4, 28, 37. However, the authors were not able to test these associations in the data as hard fruits, which are a major source of flavenoids, could not be distinguished from other fruits, and data on individual micronutrient intakes were not available.

Dietary intakes assessed by food frequency are a crude measure of consumption. However, estimates of the effects on pulmonary function and symptom prevalence were highly statistically significant. A more refined measure of dietary consumption may have resulted in larger effect sizes. It is not clear how plasma antioxidant levels relate to overall antioxidant status in the body. However, plasma vitamins C, A, E and ß-carotene are valid biochemical indicators of nutrient status 38.

Reporting bias is unlikely as participants were asked questions about many aspects of health, not solely respiratory, and about many lifestyle indicators including diet, and so it is unlikely that subjects would have been aware of individual hypotheses.

Conclusions
The potential public health significance of these findings, if there are causal links, are important as clinically significant benefits in terms of both pulmonary function and the reduced prevalence of symptoms are apparent from the authors' and other epidemiological studies. The consistent effect of fresh fruit compared with those of plasma micronutrients that has been shown in this study suggests that the active agent(s), or the most beneficial combinations of dietary components are contained within whole foods. It may be that improving the diet, by increasing the consumption of fresh fruit, vegetables and fish, rather than consumption of vitamin supplements, will be beneficial in helping to protect against airway disease.

Appendix 1: Dietary intake questions

"How often do you eat fresh fruit?"

"How often do you eat cooked green vegetables such as peas, broccoli, cabbage, spinach, cauliflower, green beans, and so on?"

"How often do you eat cooked root vegetables such as carrots, parsnips, turnips, and so on?"

"How often do you eat raw vegetables or salad?"

"How often do you eat white fish, such as cod, haddock, whiting, sole or plaice?"

"How often do you eat other types of fish, such as herring, tuna, mackerel, salmon or kippers?"

Possible answers: 6 times a day 4–5 times a day 2–3 times a day Once a day 5–6 times a week 2–4 times a week Once a week 1–3 times a month Less often or never

Appendix 2: Respiratory symptom questions

"Do you usually bring up any phlegm from your chest, first thing in the morning in winter?"

"Do you bring up phlegm like this on most days for as much as 3 months each year?"

"Have you ever had attacks of shortness of breath with wheezing?"

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