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In earlier studies, determinants of socioeconomic gradient in mobility have not been measured comprehensively.
To assess the contribution of chronic morbidity, obesity, smoking and physical workload to inequalities in mobility.
This was a cross‐sectional study on 2572 persons (76% of a nationally representative sample of the Finnish population aged 55years). Mobility limitations were measured by self‐reports and performance rates.
According to a wide array of self‐reported and test‐based indicators, persons with a lower level of education showed more mobility limitations than those with a higher level. The age‐adjusted ORs for limitations in stair climbing were threefold in the lowest‐educational category compared with the highest one (OR 3.3 in men and 2.9 in women for self‐reported limitations, and 3.5 in men and 2.2 in women for test‐based limitations). When obesity, smoking, work‐related physical loading and clinically diagnosed chronic diseases were simultaneously accounted for, the educational differences in stair‐climbing limitations vanished or were greatly diminished. In women, obesity contributed most to the differences, followed by a history of physically strenuous work, knee and hip osteoarthritis and cardiovascular diseases. In men, diabetes, work‐related physical loading, musculoskeletal diseases, obesity and smoking contributed substantially to the inequalities.
Great educational inequalities exist in various measures of mobility. Common chronic diseases, obesity, smoking and workload appeared to be the main pathways from low education to mobility limitations. General health promotion using methods that also yield good results in the lowest‐educational groups is thus a good strategy to reduce the disparities in mobility.
Mobility is an essential part of functioning, and a vital element of independent living and quality of life.1,2 Inequalities in mobility have been amply studied3,4,5,6,7: those with lower socioeconomic status, measured either by education, occupation or income, have more mobility limitations than those with a higher status.
Not much is known, however, about the factors that mediate the effect of socioeconomic position on disability. Chronic diseases, detrimental health behaviours and adverse occupational exposures are known risk factors for disability.8,9,10 Being unequally distributed among the social classes,11,12,13 they serve as potential pathways through which socioeconomic status may influence disability.11,14,15,16,17 However, the evidence to support this is relatively scant. Lifetime occupational exposures, both physical and psychological, have been found to contribute to the social class differences in self‐reported locomotor disability in early old age.17 Smoking, alcohol use, physical activity and body mass index reduced socioeconomic disparities in functioning to some extent,14,16,18 with differential effect in men and women.15 Some studies suggest that adjusting for comorbidity has a negligible effect on disparities,19,20,21 whereas others point to a more marked impact.5,22 The major limitation of these studies is that they rely on self‐reported data on diseases. Because less‐educated persons more often under‐report chronic conditions than those with higher education,23 the effect of diseases on socioeconomic differences in functioning might be obscured. Furthermore, information is lacking on which specific diseases and behavioural factors contribute most to socioeconomic differences in functioning. The central challenge in reducing the socioeconomic disparities is to identify specific factors that can be intervened by health and social policy.
This study describes educational differences in a wide array of objectively measured and self‐reported mobility tasks in the general elderly population. The focus is on assessing the contribution of smoking and obesity, a history of physically strenuous work and specific clinically diagnosed chronic conditions to educational differences in mobility, by individually and sequentially controlling for these potential mediating factors.
The Health 2000 Survey was a comprehensive cross‐sectional health interview and examination survey conducted in 2000–1.24 The two‐stage stratified cluster sample represented the Finnish adult population. Subjects aged 80 years were emphasised by doubling the sampling fraction. This study concerns persons aged 55 years (n=3392). Persons participating in the home‐based interview and clinic‐based examination were eligible for these analyses (1503 (73%) women, mean age 67.6 years; 1069 (80%) men, mean age 65.8 years).
The study was approved by the Ethics Committee for Epidemiology and Public Health in the Hospital District of Helsinki and Uusimaa, Finland.
Information on the level of general and vocational education was gathered in the interview and combined into three categories: low, primary school or less, no vocational training; intermediate, no general education beyond some secondary school combined with low vocational training/school, or secondary school with no vocational training beyond a basic course; high, matriculation examination, or secondary school with vocational school, or a degree from a vocational institute, polytechnic or university. The median years of schooling in low, intermediate and high levels of education were 6, 8 and 12 years, respectively. The proportion of women in low‐educational, intermediate‐educational and high‐educational groups was 28%, 51% and 21%, and in men it was 32%, 48% and 20%, respectively.
The health interview included questions on moving about in the house, walking about 0.5 km without resting, running 100 m, walking 100 m while carrying a 5 kg bag, climbing up one flight of stairs without resting, riding a bicycle, and travelling by train, bus or tram. The respondents were classified as having limitations if they reported any difficulties or were unable to perform the activity. Mobility was measured using performance tests. Limited performance was coded in each test separately as follows: the inability or impaired performance in squatting and stair climbing (two steps up and down), a walking speed of <1.2 m/s when completing a 6.1 m course, the inability to rise from a chair without the help of the arms, and the inability to hold a semitandem position for 10 s (standing balance).25 Stair climbing, an ability essential for independent living in the society, was chosen as an indicator for mobility in the explanatory analyses. It correlated fairly well with other mobility indicators (r=0.4–0.7). The contents of self‐reported and test‐based items were close enough enabling us to evaluate whether the contribution of the potential mediating factors to the educational differences is parallel across self‐reported and objectively measured mobility.
Information on diseases was based on the clinical diagnoses made by the field doctors at the health examination. They applied uniform diagnostic criteria based on current clinical practice, according to written instructions. The following diseases were included: angina pectoris, myocardial infarction, heart failure, intermittent claudication, cerebrovascular disease, diabetes, asthma, knee and hip osteoarthritis, low‐back syndrome, chronic arthritis, injuries, neurological disease and dementia. Depressive and anxiety disorders during the past 12 months were determined by a mental health interview. Binocular visual acuity was measured from a distance of 4 m using a test chart, and classified as reduced if the score was <0.3.
Smoking behaviour, inquired in the interview, was classified as non‐smokers, former smokers and current smokers. Body mass index (kg/m2) was based on weight and height measurements and classified into five categories: underweight (<20), normal (20–24.9), overweight (25–29.9), moderate obesity (30–34.9) and severe obesity (35).
Information on lifetime exposure to (1) heavy physical work and (2) working in a kneeling or squatting position for at least 1 h per day was based on self‐reporting. A sum index for the years of exposure to these factors in the latest and five longest‐lasting jobs over a lifetime was created and classified into tertiles. The cut‐off values for tertiles were 1 and 30 years in women, and 5 and 45 years in men.
The analyses were conducted using SUDAAN software, which takes sampling design into account.26 The observations were weighted to reduce bias due to non‐response and to correct for oversampling of those aged 80 years.27
Binary logistic regression analyses were used to describe educational differences separately in men and women. Model‐adjusted prevalences of mobility limitations by educational group were calculated using predicted marginals.27
Test‐based and self‐reported limitations in stair climbing were chosen as dependent variables in the explanatory analyses in the logistic regression models. The interaction between age and education was not significant in either outcome. The selection of the factors that were included in the explanatory analyses was based on three criteria: (1) they have been shown to be related to mobility disability, (2) they were associated with test‐based or self‐reported stair climbing (p<0.05), and (3) they were associated with education (p value for trend <0.1), in either women or men. The base model included age and education as independent variables. The effect of each factor on the educational differences in stair climbing was then examined individually. Finally, two additional models were fitted. In addition to age and education, the first one included smoking, body mass index and physical workload. The second model was further adjusted for chronic conditions. The ORs for low‐educational and intermediate‐educational groups obtained from these models were compared with the base model by calculating the relative decline of excess risk as follows: [(OR(basemodel)−OR(basemodel+intermediaryfactor(s)))/(OR(basemodel)‐1)]*100.28,29 Owing to missing values, 187 observations were excluded from the final models.
A clear gradient across the educational groups was observed in most of the self‐reported and test‐based indicators (fig 11).). Among women, the ORs describing the relative difference between the lowest‐educational and the highest‐educational groups was 2.89 in self‐reported and 2.17 in test‐based stair‐climbing limitations; among men, the values were 3.30 and 3.53, respectively. Several chronic conditions and other factors were associated with these indicators, and their prevalence also varied by education (table 11).
Among women, adjusting for obesity, work‐related physical loading, knee and hip osteoarthritis and cardiovascular diseases most strongly reduced the educational differences in self‐reported stair climbing (fig 2A2A).). Adjusting for all chronic conditions produced a reduction of 38% between the lowest and highest educated groups. Health behaviours explained a third of the differences, but this was due to body mass index only, as smoking had no effect. Figure 2B2B gives a rather similar picture according to test‐based limitations; the effects of obesity and osteoarthritis were even greater, while cardiovascular diseases contributed less. In women, simultaneous adjustment for behavioural and work‐related factors lowered the excess risk of the test‐based or self‐reported mobility limitations of lower‐educational groups in contrast with the high‐educational group by 46–61%, depending on the group and the measure (table 22,, model 1). When the chronic conditions were also adjusted for, the educational differences in the test‐based limitations vanished, but, despite a major reduction (72% and 61% in the intermediate‐educational and the low‐educational groups, respectively), the differences remained statistically significant in self‐reported difficulties (table 22,, model 2).
In men, work‐related physical loading, health behaviours, diabetes and musculoskeletal diseases substantially reduced the risk of self‐reported disability of the lowest‐educated group compared with the highest‐educated group (fig 3A3A).). The effects on the excess risk of the intermediate‐educational group were inconsistent, with some factors decreasing and others increasing mobility limitation risks. The contribution of work‐related physical loading and obesity were considerably weaker in the test‐based performance (fig 3B3B).). More than half (56–69%) of the differences in self‐reported difficulties among men were explained by controlling for behavioural and work‐related factors simultaneously (table 22).). A further reduction occurred when chronic conditions were also taken into account. The sequential adjustment of the mediating factors reduced the educational differences less in test‐based than in self‐reported limitations. However, the differences lost statistical significance in the final model.
The findings from this nationally representative sample of elderly Finnish adults add new evidence to the existing literature about social position and functioning by extending the scope from self‐reporting to objectively measured mobility, and furthermore, by assessing the mechanisms through which low education translates to poorer functioning. We found large differences in mobility between educational groups. Furthermore, the excess risk of mobility limitations of those with lower education, compared with the highest educated, was largely due to the higher prevalence of obesity, chronic conditions and history of physically strenuous work in the lower‐educational groups.
A similar pattern of educational differences was present in a wide array of self‐reported and test‐based mobility measures. In addition to the generally used indicators of walking and stair climbing, the least educated performed worse than their more‐educated peers in tasks requiring strength (squatting, carrying a bag), balance (bicycling, tandem stand) and aerobic capacity (running). Our results are in congruence with the previous findings on elderly populations from different countries.3,4,5,6,7,20,30
A large proportion of the educational differences in mobility was mediated through smoking and obesity. Obesity had a great impact on disparities in women in particular, while smoking reduced the differences in men. There are two obvious reasons for the gender difference: firstly, the strength of the association of mobility with obesity and smoking varied for men and women, and secondly, the educational distribution of the factors was different between the genders. Obesity affected mobility more seriously in women; also the educational differences in body mass index were more pronounced than in men. In all educational groups, few elderly women smoked, whereas there was a clear gradient for men: less‐educated men smoked more frequently than their better‐off counterparts.
Several studies have focused on the role of health behaviours and obesity on socioeconomic inequalities in functioning,14,15,16,18,19 but most of them fail to show the gender‐specific effect of individual behaviours. The degree to which obesity and smoking contributed to the disparities in our data corresponds with the results of Lantz et al,16 who investigated the effect of smoking, alcohol consumption, overweight and physical inactivity on socioeconomic inequalities in self‐assessed physical functioning over a 7.5‐year period. After simultaneous adjustment for behaviours, the OR for the walking and stair‐climbing problems of the least‐educated group compared with the highest‐educated group fell from 2.96 to 2.21, corresponding to a 38% decline in excess risk among the least educated. In contrast, Clark et al19 observed no effect of health behaviours on the association of education and onset of limitations in walking and stair climbing over a 2‐year follow‐up.
Our study adds to the existing body of knowledge by showing that a substantial part of the educational gradient in mobility limitations is attributable to the history of workload, which is a challenge to the occupational healthcare. Our finding is in line with prior studies showing the contribution of ergonomic and physical working conditions on self‐reported health11,31,32 and functioning.17 Heavy physical loading is an important risk factor for osteoarthritis, and thereby causes mobility restrictions.33 In addition, physically demanding work may be connected with adverse behaviours, such as smoking, unhealthy dietary habits and obesity, which are more common in lower‐occupational groups.11,32 This indirect effect was also seen in our analyses: workload lost most of its explanatory power when health behaviours were controlled for. The strength of our finding is that the history of physically strenuous work covered practically the entire working life—that is, the last (or current) and five longest‐lasting jobs. It can be assumed that the effects of the exposure on mobility accumulate over time, and therefore lifetime exposure explains the educational differences better than the current situation.34 The use of lifetime exposure to work factors enabled us to analyse the whole sample and not just those who were currently working, thus avoiding the “healthy worker” bias.
Mobility limitations among the elderly are often caused by chronic conditions, with multiple environmental and personal factors influencing and modifying this dynamic disablement process.2,35 Almost 40% of the educational differences in mobility limitations were explained by chronic conditions. Our results parallel those observed by Graciani et al.5 However, others have reported a negligible effect of chronic conditions on the socioeconomic disparities in self‐reported walking and stair‐climbing ability.19,21 The inconsistency concerning the effect of chronic conditions may stem from several sources—for example, the comprehensiveness and severity of diseases considered, the reliability of their measurement and the approach used to adjust the diseases in the multivariate models.
Two recent studies have focused on the effect that a specific disease has on the educational differences in mobility. Koster et al14 found that self‐reported knee pain was among the factors contributing most to the differences in walking and stair climbing. Nusselder et al36 reported that arthritis, low‐back complaints (in men) and heart disease/stroke contributed to the differences in mobility‐related disability‐free life expectancy. The results of these studies and the present findings accentuate the importance of prevention and effective treatment of musculoskeletal and cardiovascular diseases to reduce the socioeconomic differences in mobility.
This study was based on a representative sample of the elderly Finnish population with a high level of participation. The analyses were limited to those who had both health interview and examination data. Even though the persons who did not attend the proper health examination were more disabled than those who participated,25 no indication of results biased by this non‐participation was noted, as the association between education and mobility was similar among those who only had the health interview compared with those who also had the examination (data not shown).
The cross‐sectional design of the study restricts causal inferences. The temporal order of education, intermediary factors and mobility limitations cannot be determined. However, reversed causation is assumed to be minimal since education is generally acquired in early adulthood. More problematic is the temporal order of the intermediary factors and mobility limitations, as functional limitations may induce new health problems.35
The mechanisms through which education is connected with mobility are complicated. Although we were able to cover many of the potential mediating factors, other factors could also be relevant. Physical activity protects against the decline in functional ability,9,37 but because of its close and reciprocal associations with mobility it was not included in the analyses. The same also applies to alcohol use: only women who did not drink had an increased risk of mobility limitations. It is plausible that women who do not drink have stopped drinking because of disabling medical reasons. Compared with total abstaining, moderate alcohol consumption may also be related to a decreased risk of having disabling cardiovascular events.37
In this study, information on diseases was confirmed by a doctor in a comprehensive health examination, as opposed to self‐reported data in prior studies. More valid verification of the chronic conditions may therefore have revealed their effect better. The accuracy of self‐reported musculoskeletal diseases has been found to be quite poor, whereas cardiovascular diseases are distinguished more reliably on the basis of self‐report.38,39 Educational differences in misreporting may bias the prevalence of morbidity,23,38 thus also modifying its effect on inequalities. Guralnik et al8 have pointed out that different diseases have task‐specific impacts on functioning. Because we analysed a specific task (stair climbing) and separate diseases, the impact of diseases on educational differences are probably greater than in studies using a summary measure of disability and a simple count measure of diseases.9 Finally, the functional capacity of the participants and their diagnoses were determined independently of each other. This further supports the validity of our findings, as the over‐reporting of diseases has been found among those with self‐reported mobility limitations.39
The prevalence of mobility limitations is higher among persons with lower socioeconomic status compared with persons with a higher status.
An educational gradient was found in a comprehensive set of self‐reported and test‐based mobility indicators. Specific factors contributing to the educational differences in mobility were identified: in women a substantial part of the educational gradient was attributable to obesity, history of physically strenuous work, and musculoskeletal and cardiovascular diseases, while in men diabetes and smoking also had an important effect.
Information on the identified factors that contribute to the educational differences in mobility can be used in health and social policy when planning targeted interventions. General health promotion, using methods that yield good results in the lowest‐educational groups, is a good strategy to reduce the disparities in mobility.
Our study demonstrated large educational inequalities in various measures of self‐reported and test‐based mobility. Common chronic diseases, obesity, smoking and workload appeared to be the main pathways from low education to mobility limitations. General health promotion, using methods that also yield good results in the lowest‐educational groups, is thus a good strategy to reduce the disparities in mobility.
We thank the Health 2000 participants and field personnel, and Tommi Härkänen, PhD for valuable advice concerning the statistical methods.
Funding: This study was financially supported by the Academy of Finland (grant 205631) and by the Research Programme of KTL on Health Inequalities.
Competing interests: None.