a Division of Epidemiology, Karolinska Hospital, Stockholm County Council and Institute of Environmental Medicine, Karolinska Institutet, Sweden.
b Department of Orthopaedics, University Hospital, Uppsala, Sweden.
c Department of Community and Family Medicine, Dartmouth Medical School, New Hampshire, USA.
d Department of Orthopaedics, Karolinska Hospital, Sweden.
e Department of Medical Epidemiology, Karolinska Institutet, Stockholm, Sweden.
f Department of Medicine, University Hospital, Uppsala, Sweden.
g The Swedish Hip Fracture Study Group comprised Akke Alberts, John A Baron, Thomas Dolk, Bahman Y. Farahmand, Olof Johnell, Lena Lindén, Sverker Ljunghall, Karl Michaëlsson, Per-Gunnar Persson, K-G Thorngren, Mats Thorslund, Carl Zetterberg and Lena Zidén.
Reprint requests to: Bahman Y Farahmand, Division of Epidemiology/Norrbacka, S-171 76 Stockholm, Sweden. E-mail: Bahman.Y.Farahmand{at}imm.ki.se
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Abstract |
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Methods To study the association between hip fracture risk and recreational physical activity at various ages, changes in activity during adult life, occupational physical activity and how risks vary by adult weight change, we performed a population-based case-control study among postmenopausal women aged 5081 years residing in six counties in Sweden in 19931995. The analysis consisted of 1327 women with hip fracture and 3262 randomly selected controls. Information on leisure physical activity before age 18, at 1830 years and during recent years was based on a questionnaire. Data on occupational physical activity were collected through an independent classification of job titles obtained from record linkage with census data from 1960, 1970 and 1980.
Results There was a protective effect of recent leisure physical activity. Compared to women who reported no leisure activity, the odds ratios (OR) were 0.79 (95% CI : 0.621.00), 0.67 (95% CI : 0.540.84) and 0.48 (95% CI : 0.390.60) for women who exercised <1 h per week, 12 h per week, and 3+ h per week, respectively. These decreased OR were more pronounced in women who had lost weight after 18 years of age than in those who had gained weight. Women with high physical activity at both 1830 years and during recent years did not have a stronger protection than those with isolated high activity late in life, after accounting for recent activity. Occupational physical activity was not associated with hip fracture risk in this study.
Conclusions Recent physical activity is protective against hip fracture. The protective effect is most pronounced in women who had lost weight after age 18.
Keywords Case-control study, epidemiology, exercise, hip fracture, physical activity
Accepted 20 October 1999
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Introduction |
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Methods |
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We used the Swedish population register to recruit controls. A random sample of 3307 women aged 7080 years was drawn, frequency matched to the expected distribution of cases with regard to age (5-year age groups) and county of residence. Potential controls aged 5069 years and also residents of the study population (n = 1565) were selected in a parallel case-control study of breast cancer.23 Of a total of 4872 candidate controls, 610 were born outside Sweden, 157 died before we contacted them, 44 had senility or psychosis and 2 were blind so 4059 were eligible for the study.
We mailed all subjects a questionnaire regarding medical history and lifestyle habits. The questionnaire also requested information regarding weight at age 18, current weight and height and recreational physical activity.
On average, cases were interviewed 3 months after the hip fracture. Cases and controls who did not respond to the postal questionnaire were recontacted first by mail, then by telephone. A supplementary telephone interview was performed to complete and clarify responses for about 50% of participating subjects. Some women refused the full questionnaire but accepted a less extensive telephone interview. Among the women contacted, 1328 (82.5%) cases and 3312 (81.6%) controls participated, of whom 202 (15.2%) of the cases and 497 (15.0%) of the controls responded exclusively to the less extensive telephone interview. All women who reported having natural menses (1 case and 50 controls) were classified as premenopausal and excluded from analysis.
Information regarding recreational physical activity was requested for three periods of life (before age 18, 1830 years, and in recent years). This was assessed by the following question adopted from the MEDOS hip fracture study:19,24,25 Do you or did you ever practice sports or physical exercise during leisure time? Subjects were provided with four response options: (1) never; (2) <1 h weekly; (3) 12 h weekly and (4) >2 h weekly. In some analyses, we combined the response options (1) and (2) into one category. Physical exercise during ages 1830 was compared with activity during recent years to classify adult changes in activity. Responses were divided into five categories: unchanged low, decreased, unchanged moderate, increased and unchanged high activity. Cigarette smoking was defined as never, former or current. Use of postmenopausal oestrogens was divided into ever and never use and included, in addition to medium potency oestrogens, oral or local treatment with oestriol or unspecified oestrogens. Body mass index (BMI) was calculated as the ratio of weight (kg) and height squared (m2). Changes in body mass were measured by comparing recent weight with the reported weight at age 18. The women were classified as having unchanged weight (±3 kg), increased (gain of 3+ kg) or decreased (loss of 3 kg) weight.
Information on occupational physical activity was obtained through record linkage with data collected during the national censuses in 1960, 1970 and 1980. Personal identification numbers were used to link study subjects to the census data. Using job titles, three independent specialists in occupational medicine classified the occupational physical demands as very high, high (agricultural worker, founder, metalworker, storeman and woodman, etc.), moderate (nursery school teachers, midwives, nurses, upholsterer and glazier, etc.), light (administrators, architects, chemists, engineers and meteorologists,) or sedentary (accountant, dental technician, lawyer's work, telephone operator, watchmaker) activity. As previously described,26 we included only occupations for which two experts agreed perfectly and the third was within one category. This resulted in a total of 202 rated occupations. We were unable to score activity levels for occupations in art, music, housework, military, etc. (46 titles).
We used unconditional logistic regression analysis to obtain unconditional maximum likelihood estimates of odds ratios (OR) and 95% CI.27 All OR were adjusted for age in five categories according to Table 1. Adjustment of leisure physical activity for occupational exercise, and vice versa produced similar estimates and are not shown. In Tables 24
we also adjusted for BMI in five categories as described in Table 1
. Further adjustment one at a time for use of postmenopausal oestrogens, smoking and previous self-reported diseases (diabetes, infarction, hypertension or stroke) left the results materially unchanged and these analysis will not be presented. Interactions were assessed through product terms in the logistic models.
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Results |
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Recent physical exercise was associated with a decreased risk of hip fracture: women who were active 3 h per week had about a 50% reduction in risk as compared to sedentary women. This decreased risk was not affected by adjustment for activity before 18 years of age and at ages 1830 years. In the minimally adjusted analysis, exercise at these earlier intervals was also associated with reduced hip fracture risk. However, these OR became close to unity after adjustment for recent recreational activity (Table 2
).
The protective effect of recent physical activity varied modestly with adult weight change. Among women who lost 3 kg after age 18, recreational exercise for
3 h per week was associated with a 76% reduction in risk (OR = 0.24, 95% CI : 0.140.42) compared with those who were inactive. The corresponding estimate among those who gained
3 kg, was only a 38% reduction in risk (OR = 0.62, 95% CI : 0.460.82) (Table 3
). The interaction of physical activity and weight change was statistically significant (P = 0.05).
In Table 4 the age- and BMI-adjusted results appear to indicate that continued physical activity conferred a stronger protection than isolated activity late in life. However, after further adjustment for recent activity these decreased OR were all close to unity.
Occupational exercise had no consistent association with risk. Compared with subjects in the most sedentary jobs in 1960, 1970 or 1980, those reporting more active work had OR close to unity. Even the most active occupations did not confer a materially decreased risk. Analyses incorporating occupational activity reflected by two consecutive censuses also did not show any relationship (data not shown).
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Discussion |
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Although many previous studies have reported a decreased risk of hip fracture associated with high recent physical activity,221 there are relatively limited data regarding exercise earlier in life. In the present study no effect of early activity was seen after adjustment for recent activity. A previous investigation11 found a more pronounced protective effect of earlier activity than that in the years before the fracture, but two other studies4,19 observed slightly stronger effects for current activity. In these analyses, however, earlier activity was not taken into account in the evaluation of current activity, and vice versa.
The information we obtained enabled us to evaluate whether changes in physical exercise patterns influence hip fracture risk. To our knowledge, this has not been investigated previously. Women with increased physical activity and those who maintained high activity at both younger and older ages experienced the lowest risks of hip fracture. However, these decreased risks were all explained by recent activity. Thus, it is never too late to start to be physically active.
The importance of exercise for bone mass can be seen from two perspectives. First, although the importance of peak mass for fracture risk in the elderly remains to be clarified, it is likely to affect bone mass late in life. Peak bone mass, achieved in early adult life, might be influenced by the skeletal loading associated with physical activity during childhood, puberty, and early adult life. Some cross-sectional studies have demonstrated a slightly positive association between bone mass in children and adolescents and their physical activity2830 although others have been unable to find such correlations.31 Second, even after peak bone mass is achieved, bone tissue adapts to mechanical loading; bone mass will be reduced unless there are daily physical stresses in similar amounts as previously. Indeed, weight-bearing exercise in sedentary postmenopausal women prevents bone loss and may induce modest increases in bone mass.32 These basic considerations indicate that only continued and on-going activity would be expected to be of benefit, even though present activity is the most important. Strength training exercise is effective among postmenopausal women not only in preserv-ing bone mass but also in improving muscle mass, strength and balance.32,33 Among elderly individuals, risks for falls is an important determinant of hip fracture risk in addition to bone density. The severity of the fall may be reduced by improved muscle strength and balance.34
In our study, the protective effect of physical activity was particularly strong in women who lost weight after age 18. These results support findings from a recent cohort study in which physical activity had a beneficial effect on bone density in women who lost weight or whose weight remained stable, but not in women who gained weight.35 The most important mechanisms thought to explain increased osteoporosis risk in women with weight loss are reduced mechanical loading of the skeleton and decreased extraglandular production of oestrogens in adipose tissueboth well-known stimuli for bone gain and preservation.36 Furthermore, women with low mechanical bone loading as a result of low physical activity level, low body weight, or a low adult weight gain seem to benefit the most from hormone replacement therapy to reduce the risk of hip fracture.37 We thus suggest that interventions such as oestrogen supplementation or increased physical activity should best be targeted to those with greatest risk of fracture to gain optimal relative benefit from the treatment.
Few previous studies have focused on the association between occupational physical activity and hip fracture, and the results have been conflicting. A case-control study from Australia13 found that high levels of occupational physical activity at age 20 increased fracture risk, while activity at age 50 was not associated with risk. In contrast, a case-control study from England8 found that sedentary work at age 50 was associated with a markedly increased risk of hip fracture, and a large case-control study19 reported that occupational physical activity during the recent past was protective, but not earlier activity. In a case-control study from Toronto, women with more than 20 years experience in physically active jobs had about 50% the hip fracture risk of women with more than 20 years of less active work.17 In a large cohort study from Norway, intensive physical activity at work was also associated with more than a 50% reduction in the incidence of hip fracture.12
Census data has the advantage of not being biased by case-control status or perceptions of physical activity. Nonetheless, information on physical activity from job titles is somewhat crude and it is likely that misclassification biased our findings toward unity. Moreover, less than 50% of our subjects had employment outside the home and could be classified with regard to occupational physical activity. Thus the analyses using these data had limited statistical power. Moreover, since we found no effect of early recreational activity, it is possible that the time periods referred to by census data (ages 2566) are sufficiently early to be unrelated to hip fracture risk at later ages.
The misclassification of information on leisure physical activity is also a potential source of error in this study. Moreover, it is likely that data on earlier physical exercise may be less accurate than that for recent activity and this differential measurement error could explain why no association with early activity was found after adjustment for current activity. Few studies have specifically investigated the magnitude of agreement between originally reported information on physical activity and corresponding retrospective information. Retrospective information on vigorous activity would probably be more reliable than that for less intensive activity,38,39 and retrospective information on physical activity up to 10 years previously may be reported relatively well.38 Thus, we believe that information on physical exercise was non-differentially misclassified, and if anything a conservative bias may be present in our data.
The strengths of the present study include its large size and population-based design, and our aggressive attempts to identify all cases. Some possible cases and controls (e.g. those with known senility, alcoholism and psychosis) were excluded because of the relatively complex questionnaire. We were also able to account for many potential confounding factors.
Our study suggests that recent leisure physical activity has a protective influence on risk of hip fracture. This protective effect varied moderately with weight change after age 18. Women who lose weight during adult life have the highest risks of fracture and so are also those who may benefit most from exercise. We found that even among women who have been inactive previously, the potential preventive effect of exercise may be substantial. Preventive actions should stimulate sedentary women to start to exercise and these actions should be targeted specifically on women who have lost weight during adult life.
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Acknowledgments |
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References |
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