Body mass index as predictor for asthma: a cohort study of 118,723 males and females

Study population

Data from health surveys conducted by the Norwegian government during 1994–1999 were linked to information from the NorPD, which includes all drug prescriptions dispensed at pharmacies in Norway since 2004 20. The health surveys were performed partly by means of questionnaires (e.g. on smoking, exercise habits, level of education and history of asthma, heart infarction, angina pectoris, stroke and diabetes) and partly by physical measurements (e.g. height and weight). The questionnaires were filled in at home and delivered at the screening.

Altogether 107,001 males and 102,911 females born during 1952–1959 were invited to participate in the health surveys. A total of 159,331 (70 and 82% of the invited males and females, respectively) attended, and 132,924 answered the question about asthma history (“do you have, or have you had, asthma?” (yes/no)). The 8,638 who answered “yes” were excluded, together with 4,325 who were excluded for other reasons (fig. 1⇓), leaving 118,723 (55,940 males and 62,783 females) for analysis. BMI was calculated as weight in kilogrammes divided by height in metres squared.

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Fig. 1—

Flow chart showing the study population. Norwegian health survey results during 1994–1999 were linked to the nationwide Norwegian Prescription Database for 2004–2007. CVD: cardiovascular disease.

A total of 114,577 subjects also reported their minimum (w_min) and maximum weight (w_max) during the 5 yrs before screening. Females were asked not to report weight during pregnancy. ΔBMI was calculated from the measured height and the reported w_min and w_max as ΔBMI = (w_max – w_min)·height⁻². Relative ΔBMI was calculated as ΔBMI/BMI×100%, where BMI is the measured BMI.

In addition, the following variables from the health surveys were included: smoking (never-, ex- and current), physical activity (low, medium and high), education (five levels), year of birth, urban/rural residence and receipt of disability pension (yes/no).

Physical activity was addressed by asking about the time spent on light (no sweating or heavy breathing) and hard activity. The alternatives in both categories were 0, <1, 1–2 and ≥3 h·week⁻¹, averaged over the year. The two questions were joined in a new variable with three levels: 1) <1 h with light activity and 0 h with hard activity, 2) <3 h with hard activity, and 3) ≥3 h with hard activity.

Educational level was given as one of five categories: 1) elementary school (to an age of 16 yrs), 2) technical college or similar (for 1–2 yrs), 3) further education/high school or similar (for 3 yrs), 4) university/college for <4 yrs, and 5) university/college for ≥4 yrs.

Subjects living in municipalities with >50,000 inhabitants were classified as urban, and others as rural. However, the two largest cities in Norway were not screened during 1994–1999.

Measuring asthma incidence

Asthma incidence (new cases of asthma occurring between screening and 2007) was estimated from data on redeemed prescriptions of inhaled anti-asthmatic drugs during 2004–2007 retrieved from NorPD. Since January 1, 2004, all pharmacies in Norway have been obliged by law to send electronic data on all prescriptions to the Norwegian Institute of Public Health 20. The NorPD contains information on all individuals who have received prescription drugs dispensed at pharmacies. All prescriptions, whether reimbursed or not, are stored in the database. The drugs are classified according to the Anatomical Therapeutic Chemical (ATC) classification system 21. Among the data collected are the patient's unique identification number (encrypted), sex and age, the date of dispensing, detailed information on the drug (brand name, package size, number of packages, ATC code, defined daily dose and price) and the reimbursement code if relevant.

An end-point was used of at least two prescriptions, with the last one being dispensed ≥6 months after the first one, of reimbursed inhaled anti-asthmatic drugs, i.e. drugs with ATC code R03AC (selective β₂-agonists), R03BA (glucocorticoids) and/or R03AK (long-acting β₂-agonists/glucocorticoids combined in one inhaler). The system for general reimbursement in Norway is basically a positive-list system, based on a list of diseases or conditions for which pharmaceutical treatment can be reimbursed. Reimbursement is granted only under the condition that the patient has a chronic disease (e.g. asthma) for which long-term medication (>3 months) is necessary 22.

Use of glucocorticoids indicates more persistent asthma than use of β₂-agonists alone. An analysis was also performed in which the end-point was defined as at least two prescriptions, with the last one being dispensed ≥6 months after the first one, of reimbursed glucocorticoids (ATC code R03BA or R03AK).

The drug prescription data were linked to the health survey data using the unique personal identification number assigned to every Norwegian citizen at birth or immigration (encrypted). Permission for the linkage was given by the Norwegian Data Inspectorate (Oslo, Norway) and the Regional Committees for Medical Research Ethics.

Statistical methods

Poisson regression was used to estimate associations (expressed as relative risks (RRs)) between effect variables (BMI and ΔBMI) and the outcome variable (incident asthma) for never-smokers, ex-smokers and current smokers separately 23. The estimation was carried out using the glm (generalised linear model) function in the statistical package R 24. The effect variables were entered as categorical as well as continuous. RR estimates are presented adjusted for age (year of birth; continuous variable) and sex, physical activity, education, urban/rural residence and disability pension (categorical variables). In the analyses with ΔBMI as effect variable, BMI (continuous variable) was also adjusted for.

Interactions between sex and the effect variables (BMI and ΔBMI), and between smoking and the effect variables, were tested for by including the relevant interaction terms in the model in addition to sex, smoking category and the potential confounders listed above. The effect variables were entered as continuous.

Trends in the potential confounders as a function of BMI were tested for at baseline using linear regression for continuous variables and logistic regression for yes/no variables, with BMI entered as a continuous variable. Individuals with a BMI of <20 kg·m⁻² were not included in the trend tests.

BMI and asthma incidence

The total asthma incidence was 3.4%. Incidence was highest in current smokers and lowest in never-smokers, higher in females than in males (table 3⇓; fig. 2⇓) and positively related to BMI (table 3⇓; fig. 2⇓). There was no significant interaction between BMI and sex (p = 0.25), but the BMI–asthma relationship was significantly weaker in current smokers than in never-smokers (p<0.001 for interaction). As measured by the risk difference, the three smoking groups were more similar (fig. 2⇓; parallel curves would indicate an equal risk difference). The prescription rate was more than three times higher for very obese (BMI of ≥35) never-smokers than for normal-weight (20≤BMI<25) never-smokers. Treating BMI as a continuous variable, the RR associated with an increase of 3 kg·m⁻² in BMI ranged from 1.14 in current smokers to 1.27 in never-smokers when adjusting for confounders. The RRs obtained by adjusting for sex and age alone were very similar to those shown in table 3⇓.

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Fig. 2—

Asthma incidence (number of new asthma cases divided by number of subjects at risk) as a function of body mass index (BMI) in: a) males; and b) females (▵; · · · · ·: current smokers; •; -------: ex-smokers; □; ––––: never-smokers). The mean BMI for each category (<20, 20–24.9, 25–29.9, 30–34.9 and ≥35 kg·m⁻²) was used as × coordinate for the points. The curves are fitted Poisson regression curves from univariate models with BMI as a continuous variable. The histograms represent the relative distribution of BMI.

The overall incidence of persistent asthma, as defined by use of corticoids, was 2.7%, and the association with BMI was typically marginally stronger for incident persistent asthma than for incident asthma (see Section S1 of online supplementary material).

ΔBMI and asthma incidence

The direction of the ΔBMI was not known, but, assuming a weight gain in subjects whose measured weight at screening was closer to the reported w_max than to the reported w_min, and a weight loss in the other subjects, the direction of the change had a minor impact (table S2.1 of online supplementary material). Thus it seems reasonable to use absolute (direction-free) ΔBMI as an effect variable. There was no significant interaction between self-reported ΔBMI during the last 5 yrs before screening and sex (p = 0.97) or smoking (p>0.47). ΔBMI was positively associated with incident asthma. A 3-kg·m⁻² increase in the ΔBMI during the 5 yrs before screening was associated with a 35% increase in the risk of asthma incidence after adjusting for sex, age and smoking category (table 4⇓). After adjustment for all confounders, including BMI, the RR (95% confidence interval (CI)) remained as high as 1.21 (1.16–1.26).

Within each category of BMI, in the range 20≤BMI<35, the RR of being prescribed anti-asthmatic drugs was higher in individuals who reported a relative ΔBMI of ≥10% of their screening BMI than in those with a smaller ΔBMI (table S2.2 of online supplementary material). This was true for all smoking categories.

Strengths and limitations

The main strength of the present study is that it was based on information on measured BMI and several important confounders in >100,000 healthy individuals within a narrow age range, as well as on all dispensed prescriptions of inhaled anti-asthmatic drugs between January 1, 2004 and January 1, 2008 for the same individuals. This approach eliminates the problem of recall bias as regards incident asthma, and attenuates any effect of the seasonal variation in asthma, which may affect prevalence estimates based on cross-sectional surveys with self-reported asthma symptoms and/or doctor-diagnosed asthma.

The main limitations of the present study are (see discussion below) the possibility of false negatives (undetected cases of mild asthma) and false positives (asthma medication may have been prescribed for COPD, especially in smokers, or for other diseases) and the use of self-reported data to calculate ΔBMI. In addition, ∼25% of those who were invited to the health surveys did not attend. If the association between BMI and asthma were to differ between non-attenders and attenders, the effect estimates would be biased, but we believe that the participation rate is more likely to influence prevalence estimates than effect estimates. Further, individuals with a self-reported asthma history were excluded, and the self-reports might have been hampered by recall bias, but, again, the effect estimates are only biased to the extent that the association between asthma and BMI differed between those who recalled their asthma history correctly and those who did not.

BMI versus waist-to-hip ratio and waist circumference

Waist circumference and waist-to-hip ratio have been suggested as being better screening tools than BMI for cardiovascular risk factors 30. In a subsample of 71,424 subjects, for whom measurements of waist and hip were available, the waist-to-hip ratio and the waist circumference were associated with asthma in roughly the same way as was BMI. They were both significantly associated with incident asthma, after adjustment for confounders, including BMI (see section S3 of online supplementary material).

Obesity and asthma: possible mechanisms

Many authors have found an association between obesity and asthma incidence, but it is not clear whether the association is causal or whether the two conditions share the same environmental, behavioural or genetic influences. Although the exact mechanisms responsible for the relationship between obesity and asthma incidence remain unknown, some possible explanations have been put forward 31. These include the effect of obesity on lung mechanics, systemic inflammation and comorbid conditions 32. The comorbid conditions include dyslipidaemia, type 2 diabetes, gastro-oesophageal reflux disease and hypertension. Excluding the 23,141 individuals who, during 2004–2007, were dispensed antihypertensives (ATC group C02), lipid-modifying agents (C10), drugs for gastro-oesophageal reflux disease (A02B) or drugs used in diabetes (A10), the RR associated with a 3-kg·m⁻² increase in BMI in table 3⇑ changed by <0.02 in all smoking categories. This shows that these comorbid conditions do not explain the association between BMI and asthma found in the present study.

Enhancement of pro-inflammatory cytokines and the effect of oestrogens have also been mentioned 33. However, the literature is ambiguous. Barr et al. 34 found that post-menopausal hormone use was associated with an increased rate of newly diagnosed asthma. Conversely, Carlson et al. 35 found that post-menopausal females who used hormone replacement therapy had higher forced expiratory volumes in 1 s, which, again, is expected to give a lower risk of asthma. In a mouse asthma model, Matsubara et al. 36 characterised how oestrogens can suppress airway hyperresponsiveness. In the present population, the proportion that used oestrogens decreased with increasing BMI, but excluding the 7,000 females who were dispensed oestrogens (ATC group G03C) during 2004–2007 did not change the BMI–asthma association in table 3⇑. However, the possibility cannot be excluded that some females used oestrogens during the interval from screening to the start of the NorPD. Both the timing and duration of use, as well as the dose, seem to be very important when assessing the potential effects of hormones. This was clearly demonstrated in the Women's Health Initiative study regarding the effect on coronary heart disease 37.