Objectives: To estimate the prevalence of work related asthma and work related wheezing in United States workers. To identify high risk industries that could be targeted for future intervention. To determine the population attributable risk of work related asthma and work related wheezing.
Methods: The third national health and nutrition examination survey, 1988–1994 (NHANES III) was analyzed to determine the prevalence of work related asthma and wheezing and to identify initially defined industries at risk among United States workers aged 20 and older. Separate logistic models were developed with work related asthma and work related wheezing as outcomes. Work related asthma was defined as affirmative response to questions on self reported physician diagnosed asthma and work related symptoms of rhinitis, conjunctivitis, and asthma. Work related wheezing was defined as affirmative response to questions on self reported wheezing or whistling in the chest in the previous 12 months and work related symptoms of rhinitis, conjunctivitis, and asthma. All analyses were adjusted for age, sex, smoking, and atopy.
Results: The prevalence of work related asthma was 3.70% (95% confidence interval (95% CI) 2.88 to 4.52) and the prevalence of work related wheezing was 11.46% (95% CI 9.87 to 13.05). The main industries identified at risk of work related asthma and wheeze included the entertainment industry; agriculture, forestry, and fishing; construction; electrical machinery; repair services; and lodging places. The population attributable risk for work related asthma was 36.5% and work related wheezing was 28.5%.
Conclusions: The findings provide impetus for further research and actions by public health professionals which prioritise occupational asthma on the public health agenda. Future intervention strategies need to be developed for effective control and prevention of asthma in the workplace.
- work related asthma
- NHANES III
- OA, occupational asthma
- SWORD, United Kingdom surveillance of work related and occupational respiratory diseases
- NHANES III, national health and nutrition examination survey III
- PAR, population attributable risk
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- OA, occupational asthma
- SWORD, United Kingdom surveillance of work related and occupational respiratory diseases
- NHANES III, national health and nutrition examination survey III
- PAR, population attributable risk
Occupational asthma (OA) presently is the most often reported diagnosis of work related occupational respiratory disease in developed nations, and over 250 workplace agents have been identified as specific causes of OA.1 The national occupational exposure survey (1980–2) estimated that about 24% of the total workforce, employed in the United States industries, was exposed to occupational asthmagens.2 In the United Kingdom surveillance of work related and occupational respiratory diseases (SWORD) project, OA accounted for 26% of reported occupational lung disease,3 whereas in British Columbia, OA made up 52% of reported occupational lung disease.4 Gannon et al reported an annual incidence of OA of 43/million among workers in the West Midlands region in the United Kingdom.5 It is estimated that, in the United States, there are over 20 million workers potentially exposed to occupational asthmagens; 9 million of these are exposed to established sensitisers and irritants.6 Estimates of the proportion of asthma that is attributed to workplace exposures vary widely, probably due to several factors, including lack of recognition of occupational factors,7 a general absence of statewide surveillance systems for asthma,8 variations in the case definitions for OA, and differences among denominator populations. Thus, anywhere from 2% to 36% of all adult asthma has been attributed to OA, both in the United States and other developed nations.7,9–12 In a recent review of 43 attributable risk estimates, Blanc and Toren13 found the median (range) value for attributable risk of occupationally related asthma to be 9% (2%–33%).
Certain occupational groups are known to be at particularly high risk of developing OA, including western red cedar workers,1 chemical workers exposed to isocyanate,14 construction workers,15 bakers, and cleaners,16 textile workers,17 animal handlers,18 and healthcare workers.19
However, to our knowledge, no national estimates of the association between asthma and asthmatic symptoms with industry are available in the United States. The national health and nutrition examination survey (NHANES) provides a rich population based dataset to identify high risk industries. This study analysed data gathered from the third NHANES (NHANES III) to estimate the prevalence of work related asthma and wheezing, describe workers at high risk of developing asthma and asthma-like symptoms, and identify high risk industries that could be targeted for future intervention.
MATERIALS AND METHODS
The NHANES III was conducted in 1988–94, by the National Center for Health Statistics, to collect data on the health and nutrition of a representative sample of the non-institutionalised United States population. Detailed descriptions of the sampling strategy have been described elsewhere.20 Briefly stated, a stratified cluster sampling design was used to gather information on the health of about 40 000 Americans, aged 2 months and older with no preset upper age limit.
Definitions of variables
Due to the variable nature of asthma and in the absence of any gold standard, diagnosis of asthma and OA becomes very difficult. There were no direct questions asked in the NHANES III project to assess the proportion of asthma related to workplace exposure. We therefore constructed two working definitions of work related asthma: (a) physician diagnosed work related asthma (work related asthma), based on responses in the affirmative to both questions, “has a doctor ever told you that you had asthma?” (Question HAC1E) and “are any of the symptoms wheezing, whistling, stuffy, itchy, or runny nose, watery, itchy eyes brought on by work environment?” (Hereby referred to as work related conjunctivits, rhinitis, or asthma; question HAL14D); and (b) symptom based on work related asthma (work related wheezing), based on those who responded in the affirmative to both questions, “have you had wheezing or whistling in your chest at any time in the past 12 months? (item HAL6)” and “are any of the symptoms: wheezing, whistling, stuffy, itchy, or runny nose, watery, itchy eyes brought on by work environment? (item HAL14D)”.
Based on the response to the question on work related conjunctivits, rhinitis, or asthma (item HAL14D), a subset of 10 391 subjects from the NHANES III dataset was selected. People who responded that they were not working at the time of interview (n=3564) were excluded, leaving the total sample size of 6827. The variable used to define work related asthma was created by combining only those subjects who responded in the affirmative (n=188) and in the negative (n=4834) to both HAC1E and HAL14D for the total sample of 5022. A similar concordant pair approach was used to define work related wheezing and yielded a sample of 4573, which was included in the final analysis. Thus, the final sample included 188 cases of work related asthma and 454 cases of work related wheezing.
Other variables included in the analysis were atopy (defined as an affirmative response to the question “has a doctor ever told you that you had hay fever?”), smoking (non-smokers, past smokers, and current smokers), race or ethnicity (non-hispanic whites, non-hispanic blacks, Mexican-Americans, and other), and poverty income ratio (below poverty level, above poverty level). The poverty income ratio was computed as a ratio of the annual family income as the numerator and the poverty threshold, the age of the family reference person, and the calendar year in which the family was interviewed as the denominator.
Definition of industry categories
The NHANES III questionnaire included a comprehensive section on occupational history. Questions related to the longest industry in which the person worked (item HAS19R) were asked of all adult study subjects interviewed during the survey. The longest industry of work was defined as, “what kind of business or industry did you work in the longest time?” Originally, industrial categories were classified based on categories defined by the 1980 United States Bureau of the Census.21 The longest held industry information was available for 6557 (96.04%) eligible subjects. Among the cases with work related asthma, occupational history was available for 185 (98%) subjects and among those with work related wheezing, occupational history was available for 438 (96.5%) subjects.
In the NHANES III dataset, longest worked industrial categories were originally aggregated into 44 industrial sets. In this study these were further collapsed into 28 based on review by an industrial hygienist (table 1) to have an optimal number of observations in each industrial group for meaningful statistical analysis. The industrial hygienist was blinded to the subject’s asthma status.
A referent industry category was defined at the outset. Referent categories were constructed by collapsing industry categories where the potential of exposure to asthmagens were minimal and included “banking and other finance” (code 29); “insurance and real estate” (code 30); “social services” (code 41); and “public administration, except justice, public order, and safety” (code 44)”. All other industries, not included in the referent category, were considered to be at risk.
Due to the complex multistage survey design used in the NHANES III, STATA statistical software (STATA, College Station, TX), which allows incorporation of sampling weights, strata, and primary sampling units, was used to analyze the data. The sampling weights include adjustments for non-response and unequal probability of selection used in the sampling design. Simple descriptive statistics were used to describe the study population and calculate the prevalences, expressed as percentages, of work related asthma and wheeze, followed by multivariate logistic regression analysis to explore the association between each industry group and the outcome variable. All odds ratios (ORs) calculated were initially adjusted for age, sex, race or ethnicity, poverty income ratio, atopy, and smoking. However, addition of race or ethnicity and poverty income ratio in the model did not change the OR significantly and were removed from the final analysis to keep the model simple.
The population attributable risk (PAR) was calculated separately for work related asthma and work related wheezing using the following formula:where Pe=prevalence of exposure among cases (industrial categories was used as a surrogate measure of exposure); OR=ORs for at risk industries. The ORs were adjusted for age, sex, atopy, and smoking. For calculation of PAR, the initially defined referent category was used as a low risk industrial category and all other industrial groups were categorised as at risk industries (table 1).
Table 2 shows the general demographic characteristics of the study population. The estimated prevalences of work related asthma and work related wheezing were 3.7% and 11.5% respectively. The prevalence of atopy was highest in the age group 30–49. When restricted to the age group 20 to 44 years, the prevalence rates of work related asthma and wheeze did not change significantly (3.8% and 13% respectively, table 3). The overall prevalence of medically diagnosed asthma, wheezing, and work related symptoms of wheezing, conjunctivitis, rhinitis, and asthma are shown in table 3. Table 4 shows prevalence of work related asthma and wheeze by selected characteristics. Atopic people have a higher prevalence of work related asthma and wheeze than non-atopic people. Current smokers have a higher prevalence of work related wheeze than non-smokers and ex-smokers. However, no differences were found for work related asthma.
Risk of work related asthma by industry
Table 5 presents a summary of risk of work related asthma. There were considerable variations in risk by industry. The prevalence and ORs of association with work related asthma were only significantly increased for the entertainment industry (OR 5.96, 95% CI 1.58 to 22.45). However, a greater than two-fold increase in risk was found for agriculture, forestry and fishing; rubber, plastics, and leather products; lumber and wood products; electrical machinery; transportation equipment and trucking; wholesale trade; repair services; health related services; educational services; and justice, public order, and safety industries.
Risk of work related wheezing by industry
The estimated prevalence and ORs of wheezing were significantly increased for five industries (table 6). These included agriculture, forestry and fishing (OR 2.67, 95% CI 1.44 to 4.97); construction (OR 3.11, 95% CI 1.49 to 6.47); electrical machinery (OR 2.25, 95% CI 1.02 to 4.95); repair services (OR 3.35, 95% CI 1.35 to 8.33); and lodging places (OR 4.10, 95% CI 1.39 to 12.114). The odds of association with work related wheezing were also more than two-fold higher for textile mill products; rubber, plastics, and leather products; transportation equipment; communications; and entertainment and recreation services. A significantly lower risk was found for the industrial group that included chemicals, petroleum, and coal products (OR 0.19; 95% CI 0.05 to 0.81). However, results were based on only three cases.
Population attributable risk
There were 185 cases of work related asthma and 437 cases of work related wheezing identified with occupational history. Of the 185 cases of work related asthma, 163 (89.45%) worked in the at risk industries. Among the 437 cases of work related wheezing, 392 (90.47%) worked in the at risk industries. The ORs of association for industries initially defined as at risk were 1.69 (95% CI 0.74 to 3.88) for work related asthma and 1.46 (95% CI 0.95 to 2.26) for work related wheezing. The PAR estimated by industry was 36.5% for work related asthma and 28.5% for work related wheezing.
This study analyzed the data from the NHANES III to determine the prevalence and risk factors of work related asthma and work related wheezing and to define industries at risk in the adult United States population.
There were certain limitations in this study. The working definitions of work related asthma and work related wheezing used in this study, have not previously been validated. For several industries, we were not able to assess the risk reliably, as indicated by wide 95% CIs, due to few cases. It is possible that workers self selected themselves out of the industries where exposures may worsen their asthmatic symptoms. This healthy worker effect is a common problem in all cross sectional epidemiological studies. We tried to minimise this effect by using longest industry worked in our analysis. There were about 3500 subjects who, in response to the question on work related conjunctivitis, rhinitis, and asthma (item HAL14D), reported that they were not working at the time of interview. Further analysis of these subjects indicated that a high proportion of them reported medically diagnosed asthma and wheezing. It is possible that these subjects left their job or stopped working because of their asthma and represent serious cases, which would have resulted in an underestimation of the prevalence of work related asthma and wheezing in this analysis. Many comparisons were made in our analysis; therefore it is possible that some of our results may have been due to chance alone. There is a paucity of empirical research in which analysis has been by industrial group, which limited our comparisons with the literature. Our analysis was limited to use of the self reported industrial group, collapsed into categories, and was used as a surrogate measure of workplace exposure. This further limited our ability to compare directly the findings with others reported in the literature for certain industrial groups. Finally, the definition used for atopy may have also led to some misclassification, as some atopic people may not have had symptoms of hay fever. Given the strength of the association found, however, between this measure of atopy and both work related asthma and work related wheezing, the influence of this misclassification is likely to have been small.
The prevalence of work related asthma was 3.7%, whereas 11.5% of survey respondents reported work related wheeze. These rates are within the wide range reported in various countries.3,7,9–11,22 The PAR estimates were 36.5% for work related asthma and 27% for work related wheezing, suggesting that an estimated 27%–37% of cases of work related asthma and wheezing in the NHANES III adult study population would have been prevented if exposures encountered in the at risk industries were eliminated, assuming that the exposure is causally related to the disease. These figures are within the range reported in earlier population based studies,7,12,13 but higher than those reported in studies from various other industrialised countries.22–24 Blanc and Toren,13 in a recent review of 43 attributable risk estimates from various countries, found that the estimates of attributable risk of asthma due to occupational exposures varied from 2% to 33% (median, 15% in high quality studies).
The higher estimates of PAR found in our analysis could be due to several reasons, including differences in study population and case definitions used to define work related asthma or the approach used to classify industries. Alternately, the lower PAR reported in other countries may reflect true differences in industrial and occupational exposures encountered in those regions.
This study identified several industrial groups that were associated with work related asthma and work related wheezing. An increased risk of work related asthma or work related wheezing was found in agriculture, forestry and fishing; entertainment industry; educational services; construction; textile mill products; electrical machinery, equipment, and supplies; repair services; and lodging places.
A more than two-fold increased risk of work related asthma and wheeze was identified for the agriculture, forestry, and fishing industry. Working in the agriculture sector is associated with numerous occupational health hazards. This industrial group includes farmers and poultry workers, among others, with potential exposures to various respiratory irritants and potential asthmagens including organic dust, numerous organic chemicals—for example, insecticides, biocides, fertilisers—various plant antigens, and various other chemicals.16 Several studies have reported an increased risk of asthma and asthmatic symptoms among agriculture workers including farmers, poultry workers, and grain elevator workers. Farmers were reported to have a similarly high risk of asthma in Spain (OR 3.81), New Zealand (OR 4.16), and other industrialised countries.10,22 Farmers accounted for about half of reported cases of occupational asthma in Finland in 1990.25 Poultry workers have also been shown to have an increased risk of work related asthma and asthmatic symptoms26,27 and significantly lower lung function values.28 Similarly, increases in the prevalence of asthma have also been reported among grain elevator workers.29 The consistently increased risk found among agricultural workers in earlier studies, and the similar results found in this analysis strongly suggest a causal association between agricultural exposures and asthma.
A three-fold increased risk for work related wheezing, but not work related asthma, was found for the construction industrial group. Construction is one of the largest industries in the United States. Workers in the construction industry may be exposed to increased concentrations of construction dust, wood dust, various paints, asphalt, and dust from concrete and masonry, as well as gases and vapours. Few population based studies have reported similar associations in this industry17,30; others found no such association.22,24 It is possible that the risk of asthma varies within the construction industry and the choice of study population may in part be responsible for the inconsistency found in the results. In the construction industry, exposure to wood dust has been reported to be associated with increased risk of asthma.31,32 We did not find any association with work related asthma. This could partly be due to the healthy worker effect, as subjects with asthma may tend to avoid working in the dusty trades. Alternately, work related wheezing could be due to conditions other than asthma—for example, chronic bronchitis or emphysema. However, we adjusted our analysis for smoking, which may have diminished the effect if any. Although we did not find an increased risk for work related asthma, the significantly increased risk found with work related wheeze suggests that workers in the construction industry may be at a greater risk than reported in earlier studies.
A two-fold increased risk of work related wheeze, but not work related asthma, in the textile industrial group was found in this analysis. Workers in a textile industry are potentially exposed to cotton and other fibre dusts, textile dyes, and fabric printing and treatment chemicals. Textile workers have often been reported to have an excess risk of asthma.17,23 In a community based case-control study of risk factors of work related asthma in different occupational groups in Singapore, Ng et al17 reported more than a five-fold increased risk of asthma among textile workers. In a study by Zuskin et al,33 occupational asthma was present among 6% of workers exposed to textile dye. These same authors, in another study, reported significant changes in pulmonary function indices across the shift among synthetic textile workers.34 Some workers may also have been exposed to cotton dust, which can cause byssinosis, a condition clinically similar to asthma.
Risk in the industrial group electrical machinery, equipment, and supplies is less well recognised. Our study found a twofold increase in the risk of work related asthma and wheezing in this industrial group. The results, however, were significant only for work related wheeze. The industries included in this group are involved in processes with potential for exposure to several irritants and allergens including metal machining fluids, lubricants, solvents, paints and coatings, adhesives, soldering fluxes, and various chemicals used in semiconductor manufacturing. Several case reports have described the development of occupational asthma from exposure to fumes generated from soldering flux.35,36 However, in a cross sectional study of female workers doing manual soldering with flux cored solder wire and using administrative staff as controls, Lee et al37 did not find any increase in the prevalence of asthmatic symptoms, nor did they detect any cases of occupational asthma. Workers with 5 or more years of experience, however, had a significant reduction in the ratio between forced expiratory volume in 1 second and forced vital capacity (FEV1/FVC). McCurdy et al38 in a large cross sectional survey of semiconductor workers, reported a significantly increased risk of persistent wheezing among fabrication workers. Several case reports have described exposures to adhesives—for example, cyanoacrylates—associated with occupational asthma.39,40 However, in a large occupational cohort of 450 workers, exposure to cynacrylates was not found to be associated with asthma, using FEV1/FVC <70% as the criterion for case definition.41 Although it was not our intent to comprehensively review all possible exposures that may occur in the electrical machinery, equipment, and supplies industry, neither is it possible to determine what the actual individual exposures were, although we can reason that the potential for exposure to asthmagens is high in this group, or at least in subpopulations within the group, and the findings from this analysis could benefit from additional study.
A strong association between work related asthma and wheeze and the repair industrial group was found in this analysis. Workers in this industrial group include vehicle mechanics who are at increased risk of exposures to several agents including spray paints, degreasing solvents, and welding fumes. Spray paints may contain various isocyantes, well known to cause allergy mediated occupational asthma.30,42 Welding fumes contain a complex mixture of particulate material and gases and are strong respiratory irritants. Welders have been shown to experience an accelerated annual decline in FEV143 which may possibly lead to permanent respiratory impairment. In a study by Kogevinas et al,10 welders showed a significantly increased risk of asthma. Similarly, exposure to welding fumes was associated with a two-fold increased risk of asthma among Swedish workers, consistent with the findings of our study.23 These earlier data, combined with the results from this study, support a causal association between potential exposures encountered in this industrial group and asthma.
A four-fold increased odds of association between employment in the lodging industry with work related wheezing was found in this analysis. The exposures of concern in the lodging industry are mostly related to cleaning substances, which include solvents, sensitisers, and other volatile compounds. The risk of asthma among cleaners is not well established. In a study prompted by a case report of occupational asthma in a detergent industry, Vanhanen et al44 reported a prevalence of sensitisation to enzymes as 22% among workers exposed to detergent enzymes. In a prospective study by Nielsen and Bach,45 female cleaners were found to have high risk of developing respiratory symptoms. Few population based studies have reported an increased risk of asthma among cleaners. In a study by Kogevinas et al10 a greater than two-fold increased risk of asthma among cleaners was reported. Recently, in a multicountry population based study, based on the European Community respiratory health survey, the same authors reported an increased OR of asthma as high as 4.50 among cleaners, similar to the results reported in our study. The risk was consistent across different countries.22 A similar excess risk of asthma among cleaners was also reported by Ng et al in Singapore.17 The present evidence in the literature and strong association found in our study suggests that cleaners are at a high risk of developing occupational asthma.
This study found more than a five-fold increase in the risk of work related asthma in the entertainment industry. This group, which includes artists, designers, and photographers, has rarely been studied before. It includes workers with potential exposures to chemicals used in art media, stage set production, theatrical make up and photographic chemicals.46 In a community based study Forastiere et al47 reported an increased risk of adult asthma among women in occupations related to entertainment. Nakano et al48 recently described a case of occupational asthma resulting from exposure to pyrazolone dye used in silver halide photographic paper. Given the paucity of reports in the literature, our results suggest that this association could benefit from further studies.
Analysis from this study also found an increased risk of work related asthma in workers in the educational services. Asthma among teachers has not been studied before. Teachers are more likely to be exposed to environmental indoor allergens, which can be strong risk factors for asthma.49 Alternately, the increased risk found in this analysis could reflect self selection of subjects with asthma into this occupation. However, further studies are needed to determine whether the associations found are real or just a random finding.
In conclusion, findings from this population based study indicate that several industries are associated with an increased risk of work related asthma and work related wheezing and that 27% to 37% of the work related asthma and wheeze is attributable to selected at risk industrial groups. Most of the risks in this analysis were consistent with findings from other population based studies. Our findings provide impetus for further research and actions which prioritise OA on the public health agenda.
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