Screening for Postmenopausal Osteoporosis: A Review of the Evidence for the U.S. Preventive Services Task ForceFREE

We identified no studies about the effectiveness of screening in reducing osteoporotic fractures. Without direct evidence from screening studies, recommendations about screening need to rely on evidence that risk factor assessment or bone density testing can adequately identify women who could ultimately benefit from treatment.

Hundreds of studies report associations between risk factors and low bone density and fractures in postmenopausal women (24). The most comprehensive study of risk factors in a U.S. population is the Study of Osteoporotic Fractures, a good-quality prospective study of 9516 women 65 years of age and older (25). In this study, 14 clinical risk factors were identified as significant predictors of hip fracture in multivariable models (age; maternal hip fracture; no weight gain; height; poor self-rated health; hyperthyroidism; current use of benzodiazepines, anticonvulsants, or caffeine; not walking for exercise; lack of ambulation; inability to rise from a chair; poor scores on two measures of vision; high resting pulse; and any fracture since 50 years of age). The relative risk for hip fracture per decrease of 1 SD in calcaneal bone density was 1.6 (95% CI, 1.3 to 1.9). This was comparable to the magnitude of the relative risks of most of the other significant predictors in the model, which ranged from 1.2 to 2.0. Women with at least 5 of the 14 risk factors had increased rates of hip fractures compared with those who had 0 to 2 risk factors at all levels of calcaneal bone density.

To determine which risk factors could be important in women younger than 65 years of age, we reviewed eight observational studies of risk factors and fractures of various types conducted in populations in which at least 50% of participants were younger than 65 years of age. Table 1 lists risk factors that were statistically significant predictors for fractures in multivariable models (26-33). These results could not be quantitatively combined because risk factors were defined differently in each study.

Results of risk factor studies have been used to assess risk in individuals. We identified 10 cross-sectional studies that described methods of determining risk for low bone density for individual women based on selected clinical risk factors (Table 2) (34-43). The most common methodologic limitations of these studies are lack of validation and lack of generalizability because of small numbers of patients or nonrepresentative patients. We also identified 8 studies of clinical risk factors to determine fracture risk (Table 2) (44-51). None of these studies received a good rating for internal validity. Four studies evaluated hip fracture outcomes, two evaluated vertebral fractures, and two evaluated all types of fractures. These studies described the association of risk factors with fractures known to have occurred already (four case–control studies) or how well they would predict fractures in the future (four prospective cohort studies).

A recent study compared the performance of five clinical decision rules for bone density testing among 2365 postmenopausal women 45 years of age or older who were enrolled in a community-based study of osteoporosis in Canada (52). These rules included guidelines from the National Osteoporosis Foundation (53); the Simple Calculated Osteoporosis Risk Estimation (SCORE) rule (age, weight, ethnicity, estrogen use, presence of rheumatoid arthritis, history of fractures) (41); the Osteoporosis Risk Assessment Instrument (ORAI) (age, weight, current use of hormone replacement therapy) (43); the Age, Body Size, No Estrogen rule (54); and body weight criterion (weight < 70 kg) (38). None of the decision rules had good discriminant performance. In this study, SCORE and ORAI had the highest area under the receiver-operating characteristic curves (0.80 and 0.79, respectively [sensitivity, 99.6% and 97.5%; specificity, 17.9% and 27.8%, respectively]). Details of how to use SCORE and ORAI are given in Table 2.

Several technologies are available to measure bone density (55-58), although correlations among different bone density devices are low (0.35 to 0.60) (59-79). Dual-energy x-ray absorptiometry is considered the gold standard because it is the most extensively validated test against fracture outcomes. When used in the same patients, dual-energy x-ray absorptiometry machines from different manufacturers differ in the proportion of patients diagnosed as having osteoporosis by 6% to 15% (80-85). Published studies consistently show that the probability of receiving a diagnosis of osteoporosis depends on the choice of test and site (86-90). One analytic study, for example, found that 6% of women older than 60 years of age would receive a diagnosis of osteoporosis if dual-energy x-ray absorptiometry of the total hip were used as the only test, compared with 14% with dual-energy x-ray absorptiometry of the lumbar spine, 3% with quantitative ultrasonography, and 50% with quantitative computed tomography (87).

The likelihood of receiving a diagnosis of osteoporosis also depends on the number of sites tested. Testing in the forearm, hip, spine, or heel generally identifies different groups of patients. For example, a physician cannot definitively say that a patient does not have osteoporosis on the basis of a forearm test alone. Conversely, although test results at any site are associated to some degree with fractures at other sites, a physician may not be able to assess whether a patient with a low T-score on a hand or forearm test has substantial bone loss at other sites.

A meta-analysis assessed 23 publications from 11 separate prospective cohort studies published before 1996 (91). Nearly all of the data were from women in their late 60s or older. No studies of ultrasonography were included. The meta-analysis indicated that dual-energy x-ray absorptiometry at the femoral neck predicted hip fracture better than measurements at other sites and was comparable to forearm measurements for predicting fractures at other sites (92-94). For bone density measurements at the femoral neck, the pooled relative risk per decrease of 1 SD in bone density was 2.6 (CI, 2.0 to 3.5). In direct comparisons, heel ultrasonography was slightly worse than but comparable to dual-energy x-ray absorptiometry of the hip in women older than 65 years of age (Table 3)(92, 94-100). For both tests, a result in the osteoporotic range is associated with an increased short-term probability of hip fracture. No data compare dual-energy x-ray absorptiometry and ultrasonography for prediction of fracture in women younger than 65 years of age.

The National Osteoporosis Risk Assessment study (30) recently evaluated the performance of peripheral densitometry in predicting fractures. This prospective study of ambulatory postmenopausal women 50 years of age or older with no previous osteoporosis diagnoses recruited 200 160 participants from 4236 primary care practices in 34 U.S. states. Women received baseline T-scores by measuring bone density at the heel (single-energy x-ray absorptiometry or quantitative ultrasonography), forearm (peripheral dual-energy x-ray absorptiometry), or finger (peripheral dual-energy x-ray absorptiometry). After 12 months of follow-up, women with T-scores less than or equal to −2.5 had an adjusted risk for all types of fractures that was 2.74 (CI, 2.40 to 3.13) times higher than women with normal baseline bone density. Results varied by type of test and site; those identified as osteoporotic by dual-energy x-ray absorptiometry had higher fracture rates. Tests were not compared with dual-energy x-ray absorptiometry of the femoral neck, and the study did not describe how tests performed by age group or risk category.

The U.S. Food and Drug Administration has approved hormone replacement therapy, bisphosphonates, raloxifene, and calcitonin for osteoporosis prevention or treatment, or both. Our review of estrogen and selective estrogen receptor modulators is presented elsewhere (101).

A recent meta-analysis (102) of 11 randomized trials (103–113) enrolling 12 855 women found that at least 5 mg of alendronate per day reduced vertebral fractures in 8 trials (relative risk, 0.52 [CI, 0.43 to 0.65]). Alendronate also reduced forearm fractures in 6 trials involving 3723 participants (dosage, ≥ 10 mg/d; weighted relative risk, 0.48 [CI, 0.29 to 0.78]), hip fractures in 11 trials involving 11 808 participants (dosage, ≥ 5 mg/d; weighted relative risk, 0.63 [CI, 0.43 to 0.92]), and other nonvertebral fractures in 6 trials involving 3723 participants (dosage, 10 to 40 mg/d; weighted relative risk, 0.51 [CI, 0.38 to 0.69]). These trials included follow-up data ranging from 1 to 4 years; effect sizes for longer periods of use are not known. We evaluated data from these trials to determine whether women who have a similar overall risk for fracture but different bone densities derive similar benefit from treatment. This question is clinically important because accepted criteria for initiating treatment are lacking.

The Fracture Intervention Trial (FIT) of alendronate was conducted with two groups of participants and provides some information about levels of risk. One group (FIT-I) included a higher-risk sample of 2027 women who had T-scores of −1.6 or lower and preexisting vertebral fractures (104). The 3-year risk for hip fracture was 2.2% in the placebo group and 1.1% in the alendronate group (relative hazard, 0.49 [CI, 0.23 to 0.99]), and the 3-year risk for any clinical fracture was 18.2% in the placebo group and 13.6% in the alendronate group (relative hazard, 0.72 [CI, 0.58 to 0.90]). A second study from FIT (FIT-II) included a lower-risk sample of 4432 women who also had T-scores of −1.6 or lower but did not have preexisting vertebral fractures (114). The 4-year incidences of hip fracture (1.1%) and any clinical fractures (14.1%) in the placebo group were lower than those observed in the FIT-1 placebo group. In FIT-II, only the subgroup of treated patients who had T-scores lower than −2.5 (n = 1627) had a significant risk reduction for all clinical fractures, from 19.6% to 13.1% (relative risk, 0.64 [CI, 0.50 to 0.82]). No reduction in risk for fractures was seen in patients who had T-scores between −1.6 and −2.5.

The results from FIT suggest that women with more risk factors for fracture relating to bone structure and integrity, such as age, very low bone density, or preexisting vertebral fractures, derive the greatest absolute benefit from treatment. However, FIT did not examine other nonskeletal risk factors, such as psychomotor impairment, poor gait, and other factors that increase the risk for falling. The effect of some of these risk factors on the benefit of treatment was examined in a randomized trial of another bisphosphonate, risedronate (115). Risedronate had no effect on hip fracture rates among women 80 years of age or older who had one or more risk factors for falls but who did not necessarily have low bone density. In the same report, in women 70 to 79 years of age with severe osteoporosis (T-score < −3), risedronate reduced hip fractures by 40% (relative risk, 0.6 [CI, 0.4 to 0.9]; number needed to treat for benefit, 77).

Trial results are not applicable to a screening program unless the trials included patients who would be identified by screening the general population. We examined recruitment and eligibility characteristics of the 10 published randomized trials of alendronate to assess whether selection biases or other biases might have affected their generalizability (Table 4)(103-112). Overall, the trials included relatively healthy women with low bone density who were not using estrogen. Except for participants in two trials involving women who had recently gone through menopause and were not osteoporotic, most participants were older than 65 years of age.

The FIT-II is the largest study and provided the most detailed description of recruitment and results (107). In FIT-II, researchers recruited the sample of 4432 women by mailing a query to more than 1 million women selected from the general population in 11 cities. Women who had medical problems (for example, dyspepsia) or who used estrogen were excluded. Fifty-four thousand women (approximately 5.4%) responded by telephone; of these, 26 137 (52%) had a screening visit. A higher than expected proportion of these (65%) had sufficiently low bone density to enroll in the study. Of this 65%, 57% were classified as “ineligible, did not wish to continue, or screened after recruitment to this arm.” It is not clear from this description how many patients did not meet the eligibility criteria. In addition, an unspecified number of patients (up to 28 000) were found to be ineligible at the initial stage of recruitment. The demographic characteristics of eligible and screened but excluded participants were not reported. None of the other randomized trials disclosed any details of how their samples were recruited or how many respondents were found to be ineligible before randomization.

In other clinical areas, the results of industry-sponsored trials were significantly more favorable to newer therapies than trials funded by nonprofit organizations (116, 117). Because all 11 trials of alendronate were funded wholly or in part by the manufacturer, we were unable to assess the influence of sponsorship on effect size. If effectiveness of treatments is less than estimated in these trials, the efficiency of screening to identify candidates for treatment will be reduced and the number needed to screen for benefit will increase.

Several potential harms are associated with screening and treatment. A test result indicating osteoporosis could produce anxiety and perceived vulnerability (118) that may be unwarranted. On a quality-of-life questionnaire, women with osteoporosis voiced significantly more fears than women who had normal bone density (119). Some women may be falsely reassured if abnormal results from last year's dual-energy x-ray absorptiometry of the hip appear “improved” on this year's normal calcaneal ultrasonogram. The potential time, effort, expense, and radiation exposure of repeated scans over a lifetime have not yet been determined.

Potential harms may also arise from inaccuracies and misinterpretations of bone density tests. The variation among techniques, along with the lack of methods to integrate bone density results with clinical predictors, makes it difficult for clinicians to provide accurate information to patients about test results. In one study, physicians found densitometry reports confusing and were not confident that their interpretations of T-scores were accurate (120). False-positive results could lead to inappropriate treatment, and false-negative results could lead to missed treatment opportunities.

Harms of treatment depend on the medication used. Overall, gastrointestinal side effects occur in approximately 25% of patients taking alendronate, but in controlled trials these rates were usually not significantly higher than those for placebo. High rates of serious gastrointestinal side effects have been observed among Medicare enrollees taking alendronate (121). The long-term adverse effects of alendronate are unknown.

Costs of screening vary with technique, and average 2000 Medicare reimbursement rates were $133 for dual-energy x-ray absorptiometry and $34 for ultrasonography (122). Abnormal results on ultrasonography may require confirmatory dual-energy x-ray absorptiometry before treatment because clinical trials are based on entry criteria using dual-energy x-ray absorptiometry. Most women would require repeated tests over several years before receiving a diagnosis of osteoporosis and leaving the screening pool. Treatment costs also vary; alendronate currently costs approximately $3 per daily dose.

To estimate the effect of screening 10 000 postmenopausal women for osteoporosis on reducing hip and vertebral fractures, we created an outcomes table based on assumptions from the reviewed studies (Table 5). These estimates include age-specific prevalence rates expressed in 5-year age intervals (123) and treatment effects based on trial results (risk reduction, 37% for hip fracture and 50% for vertebral fracture) (102, 104, 115, 124). We estimated an adherence rate of 70% based on reports of adherence and side effects from treatment trials, assuming less optimal adherence in the general population.

When the assumptions in Table 5 are used, if 10 000 women 65 to 69 years of age underwent bone densitometry (dual-energy x-ray absorptiometry of the femoral neck), 1200 would be identified as high risk (T-score ≤ −2.5). If these women were offered treatment that resulted in a 37% reduction in hip fracture risk and a 50% reduction in vertebral fracture risk and 70% adhered to therapy, then 14 hip fractures and 40 vertebral fractures would be prevented over a 5-year period. The number of women in this age group needed to screen to prevent one hip fracture in 5 years would be 731, and the number of women with low bone density needed to treat for benefit would be 88. The number needed to screen to prevent one vertebral fracture would be 248, and the number needed to treat for benefit would be 30. Treatment has significant costs and potential harms; when the number needed to screen for benefit is high, the balance of benefits and harms may become unfavorable. These numbers become more favorable in older persons because the prevalence of osteoporosis increases steadily with age.

There is interest in whether risk assessment can be used to select patients for bone densitometry, which is costly. Our literature review indicated that the prevalence of osteoporosis, the predictability of densitometry, and the effectiveness of treatment might be lower for younger than for older postmenopausal women. To determine whether it is useful to consider clinical risk factors when screening younger postmenopausal women, we also included risk estimates for clinical risk factors in a sensitivity analysis. Our review of observational studies with younger postmenopausal women indicated that three consistent predictors of fracture are increasing age, low weight or body mass index, and nonuse of hormone replacement therapy (defined by current use, ever use, or certain durations of use). These three variables are also used in ORAI to identify women with low bone density (43) and were the variables most strongly associated with low bone density in a study enrolling mostly younger postmenopausal women in the United States (125). On the basis of these studies, we estimated that one of these risk factors increases the probability of having osteoporosis by up to 100% and increases the risk for fracture by 70% (relative risk, 1.7).

For younger age groups, the presence of clinical risk factors influences outcomes. For example, only five hip fractures are prevented over 5 years when all women 60 to 64 years of age are screened; however, nine hip fractures are prevented if women have a factor that increases fracture risk by 70%. For women 60 to 64 years of age who have such a risk factor, the number needed to screen is 1092 and the number needed to treat for benefit is 72 to prevent 1 hip fracture. These numbers approach those of women 65 to 69 years of age (Figure).