Economic evaluation of a population-based osteoporosis intervention for outpatients with non-traumatic non-hip fractures: the “Catch a Break” 1i [type C] FLS

Health Link is a pre-existing province-wide publicly funded program for patient support and it proffers health advice and counseling by trained staff. Health Link also has the infrastructure to act as a platform for various health-related initiatives such as InformAlberta [18] and CaB. First, administrative and claim data from emergency departments (ED) and ambulatory urgent care centers across Alberta were reviewed to identify patients who may have had a low-trauma (fragility) non-hip fracture. Of note, patients with hip fractures (who are hospitalized, undergo surgical fixation, spend weeks to months in hospital or inpatient rehabilitation facilities, and often transferred to long-term care) were deemed not suitable for CaB because these patients are almost impossible to contact within 6 weeks of fracture and need more intensive osteoporosis management [19]. Indeed, based on high-quality randomized trials, guidelines recommend an inpatient-based nurse case manager or orthogeriatric service (i.e., a 3i [= type A]) to deal with frail and hospitalized hip fracture patients [2]. Thus, CaB was designed to help outpatients with non-traumatic non-hip fractures.

Once patients were identified by administrative data, Health Link staff contacted patients by phone 6 weeks post-fracture and conducted a standardized osteoporosis screening risk assessment using an electronic questionnaire [11, 19] similar to FRAX or CAROC [2, 3]. Participants deemed “high risk” for osteoporosis and recurrent fracture (e.g., a 10-year risk of major osteoporotic fracture = 20% or risk of hip fracture = 3% [2, 3]) were asked to follow up with their family physician for investigations and management of osteoporosis. Participants were also mailed osteoporosis educational materials. Notification of screening results, along with current diagnostic and treatment guidelines, was sent to the family physician of record. High-risk participants who had not yet seen their family physician were contacted at 3 and 6 months with reminders. All participants were contacted at 12 months to complete a final assessment; this cohort represents the CaB intervention group [19].

We stratified fractures into four groups: upper extremity (including rib fractures since rates of low BMD and recurrent fracture are nearly identical to that of upper extremity fractures); spine; pelvis (since rates of low BMD and recurrent fracture are similar to that of hip fracture); and “other” (primarily ankle) fractures [20]. For the mature CaB intervention running for 1 year, we determined that 4633 participants would complete the intervention out of 7323 potentially eligible patients.

Using these same programmatic data, we also simulated a control group (i.e., usual care) based on the outpatients enrolled in CaB that were newly started on bisphosphonate treatment in 6–12 weeks after their non-traumatic non-hip fracture. Because these outpatients had fracture, they were potentially eligible for CaB, but since they were already newly treated, they did not receive any further interventions or follow-up. They were otherwise drawn from exactly the same population and have the same age, sex, incident fracture distributions, and so on, as those who entered CaB. For this control cohort, it was assumed that rates of BMD tests, rates of low bone mass, rates of long-term adherence and persistence with bisphosphonates, and all downstream costs and event rates were the same as for the patients who received the full CaB intervention and were followed for 1 year. For between-group comparisons, chi-squared and t tests as appropriate were used and a two-sided p value of 0.05 was considered statistically significant.

The cost-effectiveness analysis takes a third party healthcare payor perspective and compares the group of outpatients with fracture receiving the CaB intervention to a simulated usual care control group by using a decision analytic model that incorporates Markov processes. Data regarding population at risk, fracture types, and achieved rates of treatment were drawn directly from CaB. Cost-effectiveness was assessed through a decision analytic model incorporating Markov processes to estimate incremental costs and effectiveness based on quality-adjusted life years (QALYs) gained [21‐25]. In general, interventions are considered cost-effective when they either (1) cost less and are more effective or (2) cost more but are more effective than a comparator, but society is willing to pay for this additional cost. In the latter scenario, the incremental cost-effectiveness ratio (ICER), the ratio of incremental cost to incremental health effect, is commonly compared to some threshold level that reflects the amount a society is willing to pay for an additional unit of health [26]. This threshold represents the opportunity cost, relating to health outcomes foregone, by the reallocation of resources needed for the intervention [27]. A QALY-based threshold of $50,000 USD (about $55,000 in 2014 $CDN [28]) is often suggested [29] while a UK study [27] empirically estimated a threshold of £12,936 (about $24,000 in 2014 $CDN); we used these thresholds in our assessments of societal “willingness-to-pay.” We took a lifetime horizon and the perspective of a third party public healthcare payer.

Figure 3 illustrates the model, displaying two study arms and, for each arm, four osteoporosis-related diagnosis and treatment pathways possible in 12 months following fracture. The proportion of patients within each group was derived from CaB data (Table 1). Then, three unique Markov processes were constructed (Fig. 3), and these were distinguished only by their transition probabilities: low bone mass and receiving osteoporosis treatment (M1), low bone mass detected but not receiving osteoporosis treatment (M2), and normal bone mass and appropriately not treated (M3). M1 and M3 represent high-quality guideline-concordant care.

The structure of the Markov process was adapted from the IOF cost-effectiveness reference model [23‐25] and our prior work [14‐16]. The model incorporates 15 health states that simulate the movement of patients from the time of fracture identification at age 50 years to the age of 100 years or death (see Fig. 4). All patients entered the model at one of four initial post-fracture health states (upper extremity, spine, pelvis, other) derived from CaB data. Then, a proportion of the cohort moves to one of the other 11 states once per annual cycle, in accordance with transition probabilities derived from rates specific to the type of subsequent fracture incurred, presence or absence of low bone mass, treatment induced and fracture type-specific reductions in subsequent fractures, and population-based and age-specific death rates.

The model incorporates three simplifying assumptions. First, patients were considered to have normal (T-scores better than or equal to −1.1 at all skeletal sites measured) or treatably low levels of bone mass (T-scores worse than −1.1, encompassing densitometric osteopenia and osteoporosis) based on BMD measurements. Second, we assumed all patients were treated with alendronate or risedronate (hereafter referred to as bisphosphonate treatment), because they are generic and the most widely prescribed bisphosphonates in Canada and have the greatest weight of evidence available for fracture reduction. Last, we assumed that no additional non-hip fractures would occur after a hip fracture, although repeat hip fractures were permitted [23‐25].

The mean values and standard errors of all parameters used in the model are presented in Table 5. The key inputs are summarized below:

Conventional one-way deterministic sensitivity analyses were conducted to evaluate the robustness of the model. First, we evaluated the impact of excluding “other” fractures from CaB. Collectively, these “other” fractures are not independently associated with an increased risk of subsequent fragility fractures or low bone mass [20]. Second, we assessed the consequences of a 25% decrease (or increase) in the intervention cost. Third, although bisphosphonates are commonly used as the base case analyses in many osteoporosis-related cost effectiveness models [44], other more expensive or “on patent” oral bisphosphonates (e.g., ibandronate) might be used; thus, we conducted sensitivity analyses wherein drug costs were doubled and tripled. Fourth, we re-ran our models assuming only 35% fracture reduction with bisphosphonates; this is the value used by the IOF [25] and approximates the lower bounds of published 95% confidence intervals [31]. Fifth, we included an analysis of the impact of 50% medication adherence rather than the 80% adherence used in the base case and employed recent projections that estimated bisphosphonate effectiveness would thence be only 30% of what could be achieved with optimal adherence [44, 45]. Sixth, we explored the impact of reducing the proportion of patients who persisted with their medication from 60 to 30%. Seventh, because patients may derive a mortality reduction with bisphosphonates, we included a sensitivity analysis to assess an 11% bisphosphonate-related mortality reduction 1 year post-fracture [46]. Eighth, we included the potential for increased mortality following a vertebral fracture and handled it in the same way we incorporated increased mortality after a hip fracture. Ninth, although we used the currently recommended 3% discount rate for both costs and benefits [34], we examined the impact of using higher and lower discount rates. Last, we conducted a two-way sensitivity analysis that simultaneously excluded “other” fractures and reduced intervention costs by 25% as these are the two aspects of the intervention that healthcare administrators could change.

We also conducted a probabilistic sensitivity analysis to assess the impact of parameter uncertainty. Probability distributions were assigned to all variables for which there was uncertainty associated with the base case. We chose a gamma distribution to generate random values for unit costs but otherwise used a beta distribution and then undertook 10,000 simulations. Results were summarized using a cost-effectiveness acceptability curve, which represents the percent of simulations that were cost-effective for each study arm at various potential levels of societal willingness-to-pay. All analyses were conducted using the TreeAge Pro Healthcare Module 2016 (TreeAge Software Inc., Williamstown, MA).

The base case model suggests that, over their lifetime, patients exposed to the CaB intervention would be less likely to fracture again compared with usual care. For every 10,000 patients that participated in CaB, an additional 400 patients would be treated with bisphosphonates, resulting in the avoidance of about 4 hip fractures and 14 major osteoporotic fractures in total and a modest gain of 12 QALYs vs usual care (Table 3). Those gains were achieved at an incremental cost of $11 per patient compared to usual care or about $9200 per QALY gained.

One-way sensitivity analyses indicated that the results of the base case were reasonably robust to most plausible scenarios, i.e., achieving either an ICER of less than $55,000 or dominating usual care (that is, less costly and more effective, see Table 4). The three exceptions were a 500% increase in bisphosphonate price, reduction of treatment persistence to 30% (from the base case of 60%), and assuming only 50% adherence to treatment among those who persisted with treatment for at least 1 year (vs base case of 80%, see Table 4).

Of note, there are some scenarios over which CaB administrators might have direct influence and could improve cost-effectiveness. Namely, if “other” fractures were excluded from case-finding, then incremental costs would be reduced to 0, while the incremental effectiveness would improve slightly. Similarly, decreasing intervention costs by 25% by reducing the time spent on detailed risk assessment could also reduce incremental cost to 0. Indeed, the two-way sensitivity analysis showed, by simultaneously excluding “other” fractures and reducing intervention costs by 25%, that incremental cost would decline to −$11 per patient (i.e., CaB would be cost-saving) and the incremental effect could increase to 0.0014 QALYs. Thus, instead of being very cost-effective, the CaB intervention would in fact “dominate” usual care.

The majority of simulations (71%) fell in Quadrant I (Fig. 1), indicating that the intervention costs more than the usual care but was also more effective. The remainder of the simulations (29%) fell into Quadrant IV, indicating that the intervention was dominant, i.e., less costly and more effective than usual care. The cost-effectiveness acceptability curve for the intervention (red curve Fig. 2) indicates that the intervention would not be cost-effective if society’s willingness-to-pay was set at 0, i.e., the intervention must be cost-neutral or cost-saving to be adopted. At the origin, where the threshold is 0, the probability that the intervention is cost-effective is only 29%. However, the estimated ICER for the intervention is $9167 and lower than either of the thresholds described earlier. Specifically, based on the uncertainty contained in our model, the probability of the intervention being cost-effective is 64% in relation to the $24,000 threshold (B), but 85% if the $55,000 threshold (C) were deemed appropriate.