Introduction

Osteoporotic fractures are a fundamental cause of morbidity and mortality [1, 2]. Hence, osteoporosis is a major public health problem and imposes a substantial financial burden to the society [1, 35]. The prevalence and costs associated with osteoporosis is expected to increase even further due to the ageing of the population [6, 7].

Advanced age is an important and independent risk factor for osteoporosis and fractures [8]. Fracture risk is much higher in the elderly than in the young, even given the same bone mineral density (BMD) [811]. In Sweden, regarded as a high-risk country for osteoporosis [8, 12], about 47% of females and 17% of males aged 80–84 years have osteoporosis [13], the mean age of hip fracture is 80 years for women and 76 years for men [14] and the average 10-year probability of an osteoporotic fracture is about 27% for women and 13% for men aged 85 years [11].

Therefore, one would expect that use of osteoporosis drugs increases with increasing age. However, there are indications that the oldest old may be undertreated for osteoporosis [1518]. Studies have shown that it is particularly cost-effective to treat osteoporosis at higher ages [19], and people with advanced ages are well-represented in randomised clinical trials (RCTs) of pharmacological treatment of osteoporosis compared to other geriatric disorders. Thus, there is sufficient documentation from RCTs supporting use of bisphosphonates, calcium + vitamin D and raloxifene in people aged 75 years and older, as concluded by The Swedish Council on Technology Assessment in Health Care [20, 21].

The aim of this study was to investigate whether age is associated with use of osteoporosis drugs (i.e., bisphosphonates, calcium + vitamin D supplements and raloxifene) in a large population of older people.

Materials and methods

Study population

The individual-based Swedish Prescribed Drug Register (SPDR) was introduced in July 2005 and contains data with unique personal identification numbers for all dispensed prescriptions to the whole population of Sweden (about nine million inhabitants). The data collection is administered by the state-owned National Corporation of Swedish Pharmacies and then transferred to the Centre for Epidemiology at the National Board of Health and Welfare, which is responsible for keeping the register [22]. The SPDR is intended for epidemiological studies, research and statistics within the health care area. Missing data due to personal identification number is about 0.3% [23].

We analysed non-identifiable data from individuals aged ≥75 years who were registered in the SPDR from October to December 2005, with information about every individual’s age, sex, type of residential area (urban/rural) and dispensed drugs (amount of prescribed drug, when the prescription was filled, and prescribed dosage (i.e., from the prescriptions written by the prescribers)). After exclusion of the 0.2% (1,125/732,230) individuals with missing data on place of residence, the study population consisted of 731,105 older people (450,482 women and 280,623 men).

Information from the 3-month period about when the prescription was filled, the amount of drug and the prescribed dosage was processed to calculate the duration of drug exposure [24, 25]. When the prescribed dosage was incomplete or missing, we used defined daily doses (DDDs) [26] to calculate the duration of drug exposure. The DDD is the assumed average dose per day for a drug used for its main indication in adults [26]. We assumed 0.9 DDDs for regularly used drugs (based on calculations for regularly used drugs among the elderly in the study population) and 0.45 DDDs (50% of 0.9) for drugs prescribed as needed, as indicated on the prescription. In addition, we assumed one DDD for dermatological and eye preparations.

A list of current prescriptions was constructed based on the calculations of the duration of drug exposures for every individual on the arbitrarily chosen date of 31 December 2005. If a patient was dispensed the same drug in different doses during the study period, this was counted as one dispensed drug.

This study was approved by the ethical board in Stockholm (Dnr 2006/948-31).

Definitions

Osteoporosis drugs were classified according to their Anatomical Therapeutic Chemical code [26] (M05BA and M05BB for bisphosphonates (etidronic acid, clodronic acid, pamidronic acid, alendronic acid, ibandronic acid, risedronic acid and zoledronic acid), A12AX for the combination of calcium + vitamin D and G03XC01 for raloxifene). Patients on several osteoporosis drugs were categorised as users of all separate drugs. Calcitonin was used by only 20 people, and, therefore, excluded from this study. We also excluded hormone replacement therapy (HRT) because these drugs were in 2005 mainly used for treatment of climacteric symptoms.

Age was categorised into four groups: 75–79 (reference), 80–84, 85–89 and ≥90 years. Number of other drugs, used as a proxy for comorbidity [27, 28], consisted of the number of prescriptions filled by the person other than the osteoporosis drugs under study (i.e., bisphosphonates, calcium + vitamin D supplements and raloxifene). This variable was divided into four categories: 0–4 (reference), 5–9, 10–14 and ≥ 15 drugs.

Type of residential area was classified according to a Statistics Sweden scale into six categories of so called homogeneity regions (H1–H6) depending on the population density and the number of inhabitants in the nearest vicinity of the main city in that municipality [29].

According to this official homogeneity region classification, the two highest density categories (H1, H2) include only the largest cities in Sweden: Stockholm, Göteborg and Malmö/Lund. H3 consists of municipalities with more than 90,000 inhabitants within a 30 km radius from the centre of that municipality. H4 includes municipalities with more than 27,000 but less than 90,000 inhabitants from the centre of that municipality and also more than 300,000 inhabitants within a 100 km radius from the same centre. H5 is identical to H4 except that there are less than 300,000 inhabitants from the centre of the municipality. Finally, H6 consists of municipalities with less than 27,000 inhabitants within a radius of 30 km from the municipality centre. H4–H6 were classified as rural (reference) and H1–H3 as urban areas [30].

Statistical analysis

Men and women were analysed separately. Multivariate logistic regression was used to analyse whether age was associated with filled prescription of osteoporosis drugs, after adjustment for type of residential area and number of other drugs. The results are shown as odds ratios (ORs) with 95% confidence intervals (CIs). SPSS 14.0 for Windows (SPSS, 1989–2005) was used for the analyses.

Results

Mean age among the 731,105 elderly was 82.5 years in women and 81.4 years in men (Table 1). Osteoporosis drugs were used by 16.1% of the women (bisphosphonates, 5.4%; calcium + vitamin D supplements, 14.2% and raloxifene, 0.3%) and 3.4% of the men (bisphosphonates, 0.9% and calcium + vitamin D supplements, 3.1%). The users of bisphosphonates and raloxifene were younger than the non-users of osteoporosis drugs, whereas the male users of calcium + vitamin D supplements were older (Table 1). Figures 1, 2 and 3 show that the prevalence of the three types of osteoporosis drugs was lowest in the oldest old (≥90 years), except for calcium + vitamin D supplements among men. The prevalence of bisphosphonates decreased after 80–84 years, particularly in women (Fig. 1). The use of calcium + vitamin D supplements was most common in the age group 85–89 years (Fig. 2), whereas the prevalence of raloxifene decreased with increasing age throughout the age span (Fig. 3).

Table 1 Characteristics of the study population according to use of osteoporosis drugs, 2005
Fig. 1
figure 1

Prevalence of bisphosphonates according to age (450,482 women and 280,623 men)

Fig. 2
figure 2

Prevalence of calcium + vitamin D supplements according to age (450,482 women and 280,623 men)

Fig. 3
figure 3

Prevalence of raloxifene according to age (450,482 women)

Furthermore, users of osteoporosis drugs had on average more non-osteoporosis drugs than the non-users (Table 1). Also, users of osteoporosis drugs lived in urban areas to a greater extent than the non-users.

The multivariate logistic regression analyses (Table 2) showed that the probability of use of bisphosphonates declined with increasing age [ORwomen = 0.36 (95% CI 0.34–0.38) and ORmen = 0.46 (95% CI 0.37–0.56) for age ≥90 years compared with 75–79 years], after adjustment for type of residential area and number of other drugs. Raloxifene was also negatively associated with age [ORwomen = 0.24 (95% CI 0.18–0.32) for age ≥90 years compared with 75–79 years]. Calcium + vitamin D supplements, however, showed a divergent pattern. In men, these drugs showed an increased probability of use with age, although there was a slight decrease in those aged ≥90 years compared with 85–89 years. In women, the lowest likelihood of use of calcium + vitamin D supplements occurred in the oldest old [ORwomen = 0.81 (95% CI 0.78–0.83) for age ≥90 years compared with 75–79 years]. Use of osteoporosis drugs, particularly raloxifene, was associated with living in an urban area (Table 2). Moreover, use of other drugs was strongly associated with osteoporosis drug use, particularly in men.

Table 2 Adjusted odds ratios (ORs) with 95% confidence intervals (95% CIs) for dispensed osteoporosis drugs in 450,482 women and 280,623 men in Sweden, 2005

Discussion

Main findings

In our nationwide population of older people, about 16% of the women and 3% of the men used any osteoporosis drug, which is low compared with the estimated osteoporosis occurrence in Sweden [13]. Thus, it seems like osteoporosis is undertreated in elderly Swedes and particularly in the oldest old (≥90 years). These findings are in concordance with results from previous studies regarding age and treatment with osteoporosis drugs [15, 28, 31, 32]. One reason for this finding may include physicians’ wish to minimise polypharmacy in the frail oldest old [32]. However, use of many drugs was strongly associated with use of osteoporosis drugs [28, 32], so this explanation seems less probable. Other explanations might be physicians’ and elderly patients’ attitudes and knowledge of osteoporosis and osteoporosis drugs, older patient’s lack of communication skills (maybe due to cognitive impairment) and non-adherence in the oldest old [33].

The prevalence of bisphosphonates was generally low (5% for women and 1% for men) and higher age, particularly in women, was associated with decreased use of bisphosphonates. Treatment with bisphosphonates is well-documented in the elderly and these drugs have an overall favourable safety profile [6, 8, 34]. The cost-effectiveness of bisphosphonates in the elderly has also been established [8, 3537]. Thus, there seem to be opportunities for improvement in treatment with bisphosphonates in older Swedes. Nevertheless, the Hip Intervention Program Study Group concludes that the bisphosphonate risedronate reduces the risk of hip fracture in elderly women with confirmed osteoporosis but not in elderly women selected primarily on the basis of risk factors other than low BMD [38]. The selective oestrogen receptor modulator raloxifene is a newer type of osteoporosis drug, and, hence, not as well-studied as the bisphosphonates. Raloxifene is mainly regarded as suitable for postmenopausal women, who would previously been prescribed HRT [15, 34], which would explain the decreased use in the older participants in our study.

The most common type of osteoporosis drug was calcium + vitamin D supplements, which is in concordance with previous research [31]. Calcium + vitamin D supplements are regarded as less potent than bisphosphonates and raloxifene, and are most likely only effective in deficient patients [8, 34]. In women, the prevalence and likelihood of use of calcium + vitamin D supplements were lowest in the oldest old, even though frail older women confined to institutions sustain fewer fractures if given calcium + vitamin D supplements [39]. To our knowledge, there are no evidence-based guidelines supporting a reduced use in the oldest old women.

In concordance with previous studies [17, 31, 32, 40, 41], it seems as if men are particularly undertreated for osteoporosis, although mortality for most osteoporotic fractures has been reported to be higher in men than in women [42]. Nevertheless, osteoporosis in men has only recently been broadly recognised [43] and the treatment rates may be expected to increase as the awareness of male osteoporosis improves. Moreover, the stronger association observed in our study between use of other drugs and use of osteoporosis drugs in men, indicates that males treated for osteoporosis may have more comorbid conditions than their female counterparts. Thus, men seem to be in a worse condition than women when treated for osteoporosis.

Furthermore, living in an urban area was associated with a higher probability of osteoporosis treatment. Explanations for this finding may be a higher rate of osteoporosis and fractures in urban areas [4447] longer distance to BMD testing in rural areas [28] and availability of specialist care.

Limitations

The cross-sectional design of our study does not allow us to draw conclusions regarding causality. The SPDR does not include information about the underlying indications and diagnoses for prescription of drugs. We also lacked information about comorbidity. However, we did control for a proxy for overall comorbidity (i.e., number of other drugs) [27, 28].

We analysed data on elderly patients registered in the SPDR from October to December 2005, which corresponded to 91% of the population aged 75 years and older in Sweden (according to Statistics Sweden’s census data from 31 December 2005). The SPDR does not include data on over-the-counter drugs, which only concerns calcium + vitamin D supplements in this study. Calcium + vitamin D supplements can be purchased both with and without a prescription in Sweden. However, we were specifically interested in prescribing practise regarding osteoporosis drugs. Therefore, the lack of information about use of non-prescription drugs was not a substantial problem in this particular study. Also, the register does not include drugs used in hospitals or from drug storerooms sometimes used in nursing homes, which may lead to an underestimation of older people’s drug use. Moreover, our method is built on an assumption that all current drugs were dispensed during the observed 3-month period, which is based on the fact that drugs are prescribed for use during at most 90 days in Sweden. Therefore, we might have missed drugs that were dispensed before the 3-month period and used at a slower rate than intended. At the same time, we might have included drugs that were dispensed during the 3-month period but discontinued prematurely. In addition, our method is based on interpretations of the dispensed drugs’ dosages written by the prescribers, as well as assumptions about DDDs when information about dosage was incomplete or missing (about 15% of the regularly used drugs) [24, 25].

Finally, a general limitation of studies on drug registers is that data on dispensed drugs are not synonymous with neither prescribed nor used drugs. Some prescriptions may never be filled at pharmacies and adherence to treatment can be low [33].

Conclusions

Our results indicate an undertreatment of osteoporosis, particularly with bisphosphonates, in the oldest old in Sweden. Future research in other large study populations is needed for understanding the mechanisms behind this age effect.