Development of clinical utility of zoledronic acid and patient considerations in the treatment of osteoporosis

Abstract

Osteoporosis is a major health concern, which results in the increased risk of fractures. There is a high risk for the first or consecutive fractures leading to considerable morbidity and debilitating consequences if osteoporosis is untreated. Currently, bisphosphonates are the mainstay of treatment for osteoporosis though long-term persistence and adherence to bisphosphonates, especially those taken orally, remain low. This medication noncompliance has serious consequences on osteoporotic patients as it is associated with a significantly higher fracture risk. Intravenous (IV) zoledronic acid (ZOL), developed to increase compliance by overcoming the frequent and burdensome dosing requirements of oral bisphosphonates, is the first and the only once-yearly bisphosphonate globally approved for use in the treatment of up to 6 indications of osteoporosis. Several clinical studies have documented that a single infusion of IV ZOL resulted in decreased bone turnover and improved bone density for at least 12 months post infusion. This article traces the development of ZOL’s clinical utility and evaluates its patient preference by collating data from all major clinical trials, studying the efficacy and safety of ZOL in the treatment of osteoporosis and other benign bone disorders.

Keywords:

• bisphosphonates
• patient preference
• efficacy
• safety
• Paget’s disease

Introduction

Osteoporosis

Osteoporosis, a chronic disease that affects an estimated 200 million people worldwide, is characterized by decreased bone mass, as well as weakened bones, with an increased risk of fractures. Often diagnosed late and subsequent to a fracture, it leads to significant morbidity and mortality.^1,2 Osteoporosis can be classified into 2 forms: primary and secondary. Primary osteoporosis results from cumulative bone loss as people age and go through changes in their sex hormones. Secondary osteoporosis results from a variety of medical conditions, diseases, or use of certain medications that adversely affect skeletal health.³ The World Health Organization (WHO) defines osteoporosis as a bone mineral density (BMD) with a T-score of ≥2.5 standard deviations below the gender-specific young adult mean (ie, T-score ≤ −2.5), as measured by dual energy X-ray absorptiometry (DXA).⁴ However, total fracture risk reflects both BMD-dependent and BMD-independent risk factors, and the new WHO absolute fracture risk algorithm takes into account BMD, age, smoking, alcohol intake, personal or parental history of fracture, body mass index, corticosteroid use, and rheumatoid arthritis to predict individual patients 10-year probability of sustaining osteoporotic fractures.^5,6

Bisphosphonates

Bisphosphonates, which inhibit osteoclastic activity, are the most commonly used medications for the treatment of osteoporosis.^7,8 Several formulations of bisphosphonates are currently available. Alendronate (ALN), risedronate (RIS), and ibandronate are oral bisphosphonates that have been widely used for the treatment of postmenopausal osteoporosis (PMO). These bisphosphonates were originally approved as a once-daily formulation. However, low adherence to daily therapy coupled with recognition of the long skeletal retention of these bisphosphonates led to the evolution of less-frequently-dosed but bioequivalent formulations.^9,10 Current bisphosphonate regimens include once-weekly ALN or RIS, once- or twice-monthly ibandronate and RIS, quarterly intravenous (IV) ibandronate, and once-yearly IV ZOL.⁸

Zoledronic acid

Zoledronic acid (ZOL) (Aclasta^®/Reclast^®; Novartis Pharma AG, Basel, Switzerland), a third-generation bisphosphonate available as an IV formulation (5 mg given once-yearly, recommended with daily supplementation of 500–1,200 mg elemental calcium plus 400–800 U of vitamin D), is approved globally for up to 6 indications.

1. Treatment of PMO in women to reduce the incidence of hip, vertebral, and nonvertebral fractures and to increase BMD

2. Prevention of clinical fractures after hip fracture in men and women

3. Treatment of osteoporosis in men

4. Treatment and prevention of glucocorticoid-induced osteoporosis (GIO)

5. Prevention of PMO (in the United States)

6. Treatment of Paget’s disease of bone

In May 2009, ZOL was approved by the US Food and Drug Administration for use, once every 2 years to prevent osteoporosis in postmenopausal women with osteopenia in the United States.¹¹ ZOL (Zometa^®; Novartis Pharma AG, Basel, Switzerland) is also approved for the treatment of hypercalcemia of malignancy (HCM) and advanced malignancies involving bone.¹²

This article traces the development of ZOL’s clinical utility by collating data from all major clinical trials, studying the efficacy and safety of ZOL in the treatment of primary and secondary osteoporosis and other benign bone disorders. This article also reviews the patient preferences for different osteoporosis medications with a special focus on ZOL. The pharmacology and mechanism of action of ZOL are not reviewed in this article as both have been extensively reviewed previously.^13–24

Studies evaluating the therapeutic utility of ZOL

Clinical studies

Treatment of PMO

The clinical utility of ZOL in the treatment of PMO was evaluated in 3 randomized and 2 open-label trials.

Early studies of ZOL

The potential of IV ZOL in the treatment of PMO was initially assessed by Reid et al²⁵ in a placebo-controlled, dose-ranging, 1-year study. This phase II study randomized 351 postmenopausal women aged 45–80 years to receive placebo or one of the following 5 ZOL regimens: 0.25 mg, 0.5 mg, or 1 mg at 3-month intervals; a single 4-mg dose; or 2 doses of 2 mg administered 6 months apart. Mean lumbar spine and femoral neck BMD was, on average, 4.3%–5.1% (P < 0.001) and 3.1%–3.5% (P < 0.001), respectively, higher in all the ZOL treatment groups vs the placebo group at the end of the study period. Significant decreases in bone turn over markers (BTMs) were also observed at the end of the study (49%–52% decrease in serum type I collagen C telopeptide [CTx] with ZOL vs 8% decrease in CTx with placebo; P < 0.01). These results indicated that ZOL infusions given even at intervals of up to 1 year produce similar effects on bone turnover and bone density as those achieved with daily oral dosing with bisphosphonates of proven efficacy against fractures.

The above 1-year trial had 2 consecutive, open-label, 2-year extension phases. The objective of these extension studies was to assess the long-term efficacy and safety of prolonged use of ZOL for a further 4 years. A total of 119 women who completed the 1-year core study entered the next phase. Majority of the patients who entered the first extension study received 1 mg ZOL every 3 months (total annual dose, 4 mg), and others with 0.5 mg ZOL every 3 months (total annual dose, 2 mg). Patients who entered the second extension study received either calcium only or ZOL 4 mg. All patients entering the active treatment arm of the second extension had previously received ZOL 4 mg per year during core and extension 1 studies. Patients received treatment for 2, 3, or 5 years. Study results showed that BMD increased in all 3 subgroups by the end of the 5-year study period in lumbar spine (6.4%–9%), proximal femur (4.9%–5.5%), distal radius (2.2%–3%), and total body (3.6%–5%), whereas BTMs decreased. However, there was an insufficient reduction in BTMs and moreover levels of alkaline phosphatase and CTx increased from month 24 onwards in patients treated for up to 5 years.²⁶

The long duration of the study allowed trends to be identified regarding the degree of reduction in bone modeling achieved by ZOL and suitability of 4 mg as a total annual dose. The results showed that ZOL 4 mg once-yearly increased BMD and was effective in reducing BTMs over 5 years. However, detailed analysis of BTM changes suggested that the 4-mg dose caused insufficient reduction in remodeling activity and may not suffice to maintain the suppression of bone resorption.²⁶ This upward trend in BTMs, leading to insufficient reduction of bone turnover to keep stable reduction in remodeling activity, was similar to a previous trial in which an IV bisphosphonate (ibandronate) was underdosed.²⁷ Therefore, the authors concluded that the same mechanism could also play a role in this study and to achieve a more pronounced suppression of bone turnover, a higher IV dose of ZOL might be required.²⁶

The health outcomes and reduced incidence with zoledronic acid once yearly-pivotal fracture trial

The Health Outcomes and Reduced Incidence with Zoledronic Acid Once Yearly-Pivotal Fracture Trial (HORIZON-PFT) was a large, international, multicenter, randomized, double-blind, placebo-controlled trial of 3 years duration in which 7,765 patients with PMO were randomized to receive either a 15-minute IV infusion of ZOL (5 mg) or placebo.²⁸ This study showed that ZOL significantly reduced morphometric vertebral, clinical vertebral, hip, and nonvertebral fractures by 70%, 77%, 41%, and 25%, respectively (Table 1). The 3-year risk reduction (70%) in the incidence of the vertebral fractures with ZOL exceeded the reduction previously observed for oral bisphosphonates and other therapeutic interventions.^28–35 Assessment of bone structure and microarchitecture was also performed in a subgroup of patients. Overall, the findings from the study indicated preservation of trabecular bone structure in the ZOL group at 3 years.³⁶

Table 1 Summary of key efficacy data for ZOL in the treatment of osteoporosis and Paget’s disease

Study	No. of patients, N	Study design	Intervention	Key efficacy results
Black et al^Citation28 (HORIZON-PFT)	7,765	3-year, randomized, double-blind, placebo-controlled clinical trial in postmenopausal osteoporosis patients	ZOL 5 mg; placebo	70% reduction in morphometric vertebral fractures over 3 years 41% reduction in hip fractures over 3 years 25% reduction in nonvertebral fractures over 3 years
Lyles et al^Citation43 (HORIZON-RFT)	2,127	Multicenter, randomized, double-blind, placebo-controlled, parallel-group 5-year trial in patients who had already sustained hip fracture; median follow-up was 1.9 years	ZOL 5 mg; placebo	28% reduction in mortality after hip fracture 35% risk reduction of all new clinical fractures 46% risk reduction of all new clinical vertebral fractures and 27% risk reduction in new nonvertebral fractures ZOL improved BMD at total hip and femoral neck ZOL demonstrated fracture prevention across all patients, even those at highest risk of fracture
McClung et al^Citation37	225	1-year, double-blind, double-dummy study in postmenopausal osteoporosis patients	ZOL 5 mg; ALN 70 mg	Lumbar spine BMD remained stable with both treatments at 12 months 78.7% of patients preferred a once-a-year infusion to weekly oral therapy at the end of study
Saag et al^Citation38	128	24-week, multicenter, randomized, double-blind, double-dummy, active-controlled trial in postmenopausal osteoporosis patients	ZOL 5 mg; ALN 70 mg	Significantly greater relative change in urine NTx values at week 1 with ZOL vs ALN ZOL group had significantly lower mean urine NTx values throughout the 24-week study vs the ALN group ZOL caused greater and more rapid reduction in BTMs compared with weekly ALN
Reid et al^Citation59 (GIO trial)	833	1-year, multinational, multicenter, randomized, double-blind, double-dummy, stratified, active-controlled clinical trial in the prevention and in the treatment of GIO	ZOL 5 mg; RIS 30 mg	ZOL demonstrated superior BMD increase at 12 months compared with oral daily RIS in both subpopulations ZOL significantly decreased levels of β-CTx and P1NP compared with oral daily RIS in both the prevention and the treatment subpopulations 84% of all patients preferred annual IV over daily oral pills
Reid et al^Citation65 (Paget’s diseasecore studies)	357	2 identical, 6-month, randomized, double-blind, active-controlled trials in patients with Paget’s disease	ZOL 5 mg; RIS 30 mg	96% of patients achieved therapeutic responsea with ZOL vs 74% with RIS at 6 months 88.6% of patients achieved normal alkaline phosphatase with ZOL vs 57.9% with RIS ZOL produced significantly greater reductions in alkaline phosphatase than RIS
Hosking et al^Citation66 (Paget’s disease-extension study)	267	Eligible patients from both core studies reexamined 24 months after treatment	ZOL 5 mg; RIS 30 mg	98% of those given ZOL maintained therapeutic responsea vs 57% of those given RIS at 24 months
Boonen et al^Citation53 (geriatric osteoporosis)	3,887	A post hoc subgroup analysis of pooled data from the HORIZON-PFT and HORIZON-RFT.	ZOL 5 mg; placebo	At 3 years, incidence of any clinical, vertebral and non-vertebral fracture was significantly lower in ZOL group compared with placebo group (10.8% vs 16.6%, 1.1% vs 3.7%, and 9.9% vs 13.7%, respectively).
Orwoll et al^Citation48 (male osteoporosis)	302	Multicenter, double-blind, active-controlled, parallel-group study for 24 months in hypogonadal men	ZOL 5 mg; ALN 70 mg	ZOL increased BMD at lumbar spine, total hip, femoral neck, and trochanter and was noninferior to ALN at 24 months. At month 12, the median changes from the baseline of markers for bone resorption β-CTx, urine NTx and P1NP formation, serum BSAP were comparable between ZOL and ALN groups.

Note:

a Therapeutic response defined as normalization of alkaline phosphate or ≥75% decrease in excess alkaline phosphatase.

Abbreviations: ZOL, zoledronic acid; HORIZON-PFT, The Health Outcomes and Reduced Incidence with Zoledronic Acid Once Yearly-Pivotal Fracture Trial; HORIZONRFT, HORIZON-Recurrent Fracture Trial; BMD: bone mineral density; ALN, alendronate; NTx, N-telopeptide of type I collagen; BTM, bone turnover markers; GIO, glucocorticoid-induced osteoporosis; β-CTx, beta-serum type I collagen C telopeptide; P1NP, serum N-terminal propeptide of type I collagen; RIS, risedronate; BSAP, bone-specific alkaline phosphatase.

First head-to-head study of ZOL vs ALN

The first head-to-head study involving ZOL and ALN was conducted by McClung et al.³⁷ This noninferiority 12-month trial included postmenopausal women (age, 45–79 years) treated with ALN for at least 1 year prior to randomization. A total of 225 patients were randomized (1:1) to receive either a single IV infusion of ZOL 5 mg plus oral placebo or a weekly 70 mg ALN plus a single IV infusion of placebo. The study showed that single-infusion ZOL maintained BMD for 12 months, following the switch from oral ALN in women with osteoporosis (Table 1). At the end of the study period, the ZOL group experienced a 0.12% (standard error [SE] = 0.273) increase from baseline in lumbar spine BMD compared with the ALN group that had a 0.828% (standard error [SE] = 0.288) increase from baseline (95% confidence interval [CI], −1.491 to 0.075). The authors concluded that patients can be switched from oral ALN to ZOL infusion with maintenance of therapeutic effect for at least 12 months.

Effect on bone resorption markers

Saag et al³⁸ investigated the onset of action and effects on bone resorption markers of a single-infusion ZOL vs weekly oral ALN. The 24-week trial randomized (1:1) 128 postmenopausal women aged 45–79 years to receive either a single IV infusion of ZOL 5 mg plus oral placebo or a weekly oral 70 mg ALN plus a single IV infusion of placebo. The primary end point was the change in N-telopeptide of type I collagen (NTx) at week 1 from baseline. A significantly lower mean urine NTx value was seen in the ZOL group compared with the ALN group at week 1 (15.2 nmol BCE [bone collagen equivalents]/mmol creatinine and 35.5 nmol BCE/mmol creatinine, respectively; P < 0.0001). Overall, ZOL caused a greater and more rapid reduction in BTMs compared with weekly ALN (Table 1). Moreover, results from this study also showed that the majority of patients were more satisfied with the annual ZOL infusion (59.8%), were more willing to take it for a long period of time (68.0%), and felt that the annual infusion was more convenient than once-weekly therapy (66.4%).

Prevention of PMO

ZOL is also approved for the prevention of PMO. The recommended regimen is a 5-mg IV infusion once every 2 years over no less than 15 minutes. Data from a 2-year, randomized, multicenter, double-blind clinical study (n = 581) showed that ZOL significantly increased BMD at lumbar spine and total hip compared with placebo at month 24 for osteopenic women in early and late menopause.³⁹

In another 2-year study in a volunteer sample of 50 postmenopausal women with osteopenia treated with ZOL or placebo,⁴⁰ ZOL decreased mean levels of each of 4 BTMs by at least 38% (range, 38%–45%) for the duration of the study (P < 0.0001). After 2 years, BMD was higher in the ZOL group than in the placebo group at an average of 5.7% (95% CI, 4.0–7.4) at the lumbar spine, 3.9% (2.2–5.7) at the proximal femur, and 1.7% (0.8–2.5) at the total body (P < 0.0001 for each skeletal site). Moreover, between-group differences in BTM and BMD were similar at 12 and 24 months.⁴⁰

Hip fractures

Hip fractures are associated with increased morbidity, functional decline, and death in older adults.⁴¹ Mortality is increased with reported rates of 15%–25% in the year following hip fracture.^41,42 The clinical efficacy of ZOL in patients with a recent, low-trauma hip fracture was investigated in a large, randomized, double-blind, placebo-controlled, multicenter 5-year study known as the HORIZON-Recurrent Fracture Trial (HORIZON-RFT) (n = 2127), which is the only trial ever conducted to study the risk of fracture incidence in patients who have already sustained a hip fracture, in which the median duration of follow-up was 1.9 years.⁴³ Patients included in the HORIZON-RFT study were men or women aged ≥50 years, who had a low-trauma hip fracture surgically repaired within the previous 90 days.⁴³ Patients were randomized (1:1) to receive IV infusions of ZOL 5 mg or placebo once-yearly. The primary measure of efficacy was new clinical fracture (excluding toe, finger, and facial bone fractures, and those occurring in abnormal bone) over the duration of the study. Secondary efficacy measures included new hip fracture, nonvertebral fracture, and vertebral fracture and the change in BMD in the nonfractured hip (measured annually with DXA); and prespecified safety end points, including death.

Data from the study showed that once-yearly ZOL 5 mg IV was effective in reducing the risk of fractures developing in patients who recently had a low-trauma hip fracture (Table 1).⁴³ ZOL significantly (P = 0.001) reduced the risk of any new clinical fracture by 35% relative to placebo, with 8.6% of ZOL and 13.9% of placebo recipients experiencing such fractures at 2 years. ZOL also reduced the risk of most secondary end point fractures. After 2 years of treatment, the risk of nonvertebral (7.6% ZOL vs 10.7% placebo recipients) and vertebral fractures (1.7% ZOL vs 3.8% placebo recipients) were also significantly reduced (P < 0.05) by 27% and 46% with ZOL relative to placebo, although the treatment groups did not significantly differ in terms of hip fracture risk (2.0% ZOL vs 3.5% placebo recipients).⁴³

BMD at both the total hip and the femoral neck improved significantly (P < 0.001) with ZOL relative to placebo after 12, 24, and 36 months of treatment. Moreover, clinically relevant losses of BMD (based on prespecified measures of bone safety) were observed in 2.4% ZOL vs 11.9% placebo recipients.⁴³

A significant reduction in all-cause mortality in patients treated with ZOL was also observed: 9.6% patients in the ZOL group and 13.3% patients in the placebo group died, a 28% reduction in deaths from any cause in the ZOL group (P = 0.01).⁴³

Post hoc analysis of the HORIZON-RFT study to examine whether the timing of the first infusion had any relationship to fracture and mortality benefit showed that patients infused 2–12 weeks after hip fracture, showed significant reduction in clinical vertebral fractures, nonvertebral fractures, and hip fractures, as well as all-cause mortality (first trial ever to show a significant reduction in mortality after using an antiosteoporosis medication).⁴⁴

Male osteoporosis

Male osteoporosis is an important public health issue and remains largely undertreated in general practice. Moreover, even though men experience fewer osteoporotic fractures than women, they have higher mortality after fracture.⁴⁵ Two analyses provide evidence for the efficacy of ZOL in the treatment of osteoporosis in men, and based on these studies, ZOL was approved in the European Union (EU).

Data analyzed from the male subpopulation of the 3-year HORIZON-RFT trial⁴³ showed that ZOL was significantly more effective than placebo in increasing total hip BMD in men at 12, 24, and 36 months and in increasing femoral neck BMD at 24 and 36 months.⁴⁶ Though the study was not powered to show a reduction in clinical fractures in men, the 2-year cumulative clinical fracture event rates were 7.45% and 8.7% for ZOL and placebo, respectively (Kaplan–Meier estimates).⁴⁶ Moreover, the study showed that men experienced greater absolute mortality benefit than women (6.4% vs 2.8%), although they had a similar reduction in the risk of death.⁴⁷

A 2-year study randomizing 302 hypogonadal men to annual ZOL 5 mg IV or weekly oral ALN 70 mg demonstrated that the ZOL group had 6.1% increase in lumbar spine BMD compared with the ALN group that had 6.2% increase at 24 months. At month 12 relative to baseline ZOL and ALN reduced serum CTx by 52% and 57%, urine NTx by 54% and 59%, serum N-terminal propeptide of type I collagen (P1NP) by 51% and 56%, serum bone-specific alkaline phosphatase (BSAP) by 22% and 25%, respectively (Table 1). The majority of subjects preferred once-yearly IV infusion of ZOL 5 mg over once-a-week oral 70 mg ALN.⁴⁸

Pediatric osteoporosis

The use of bisphosphonates in children with osteogenesis imperfecta is well established. Most of the reports in children are almost exclusively on IV pamidronate,⁴⁹ although successful treatment with the oral bisphosphonates, such as ALN,^50,51 has also been reported.

In a recently published study in children with osteogenesis imperfecta, patients were switched to ZOL (0.04–0.05 mg/kg every 4 months) for a mean of 3.4 years after pamidronate therapy (1 mg/kg per dose every 2 months) for a mean of 3.75 years. Results from the study showed that ZOL appeared to be similarly effective as pamidronate in improving vertebral BMD and in reducing fracture rates implying that ZOL may be considered a potential alternative to pamidronate infusions in this patient group.⁵²

Geriatric osteoporosis

Osteoporosis is for the most part a disease of the aged. Intravenous bisphosphonates are an option in the elderly who cannot tolerate or may have difficulty adhering to oral bisphosphonate therapy. Once-yearly infusion of ZOL may significantly improve adherence, especially in a geriatric population. Post hoc analysis of pooled data from HORIZON-PFT²⁸ and HORIZON-RFT⁴³ determining the efficacy of ZOL in osteoporotic postmenopausal women aged ≥75 years has shown that once-yearly ZOL treatment over 3 years significantly reduced the risk of any clinical fracture, clinical vertebral and nonvertebral fractures (Table 1). These findings provide evidence of the efficacy of once-yearly ZOL 5 mg IV in osteoporosis patients of advanced age.⁵³

Glucocorticoid-induced osteoporosis

Persistent use of glucocorticoids is a major cause for secondary osteoporosis, leading to bone loss and increased fracture risk.^54–58 This increased risk is apparent in some patients within 3 months of starting glucocorticoids.⁵⁶ Prevention and treatment of GIO has been established with bisphosphonates.⁵⁸ Recently once-yearly ZOL 5 mg has been approved for the prevention and treatment of osteoporosis caused by long-term use of glucocorticoids.

The approval for the GIO indication for men and women is based on the study showing that annual ZOL 5 mg IV is more effective in treating bone loss than daily oral RIS in patients with GIO. The study investigated both the prevention and the treatment of GIO in 833 men and women (288 prevention vs 545 treatment subgroups).⁵⁹ Over 1 year, ZOL produced significantly greater increases in BMD of the lumbar spine, femoral neck, trochanter, and total hip than RIS. The increase in BMD with ZOL was evident at 6 months, and ZOL was better than RIS at 12 months (Table 1).⁵⁹

Thalassemia-induced osteoporosis

Osteoporosis is an important cause of morbidity in beta-thalassemia patients. In a study by Otrock et al,⁶⁰ 18 thalassemia patients with osteoporosis were given ZOL 4 mg IV every 3 months over a period of 12 months. Patients on ZOL had a significant increase in their lumbar spine, femoral neck, trochanter, and total hip BMD measurements over the 12-month period. Patients in the control group did not have any significant change in BMD measurements. There was a significant change in the levels of osteocalcin and bone alkaline phosphatase (BAP) and also a significant decrease in the number of painful sites (bone pain) experienced by the patients.^60,61

In another study, 66 thalassemia patients with osteoporosis were randomized (1:1:1) to receive ZOL 4 mg IV, every 6 or 3 months, or to receive placebo every 3 months, for a period of 1 year. BMD of the lumbar spine, femoral neck, and wrist was determined before and 12 months after treatment. Patients treated with ZOL 4 mg IV every 6 months had no change in BMD; however, there was an increase in BMD with ZOL 4 mg IV given every 3 months. Both regimens of ZOL reduced pain.⁶² BMD remained higher than baseline after 24 months of stopping ZOL treatment.⁶³

Overall, the data from the above studies suggest that ZOL may be an effective option for the treatment of osteoporosis in thalassemia patients.^60–63

Localized transient osteoporosis

Localized transient osteoporosis (LTO; bone marrow edema) is an increasingly diagnosed condition characterized by acute onset of disabling bone pain, which typically occurs at a single skeletal site. Although its etiology is unknown, LTO has been linked to pregnancy and prolonged periods of exercise but with absence of previous trauma or surgical history, as in algodystrophy. Current treatment options are limited in number and provide inadequate efficacy except recent positive experience with IV bisphosphonates.

A study by Ringe et al⁶⁴ in 8 patients with LTO showed that ZOL was highly effective in reducing pain, measured by visual analog scale (VAS 1–10). Pain scores decreased from 9.4 (at baseline) to 0.4. BMD was restored with an average increase in the lumbar spine of 4.1% after 6 months of treatment and in the affected and unaffected hip area by 9.4% and 3.0%, respectively (difference 6.4%, P < 0.01), improving mobility and quality of life (QoL) in patients with LTO of the hip.

Paget’s disease

Paget’s disease of bone is characterized by a dramatic increase in bone turnover (both formation and resorption) at one or more skeletal sites.⁶⁵ The bone pain, skeletal deformity, pathologic fractures, secondary arthritis, neurologic complications, and deafness that may accompany this disease contribute to its substantial morbidity. Bisphosphonate therapy is the most commonly used treatment for Paget’s disease.⁶⁵

In 2005, Reid and colleagues⁶⁵ published results of a pivotal study comparing ZOL with RIS in patients with Paget’s disease. The paper combined 2 identical, double-blinded, randomized controlled trials, comparing ZOL with RIS. In the 6-month trial, patients received either a single IV infusion of ZOL 5 mg (177 patients) or a daily 30 mg RIS for 2 months (172 patients). The primary end point was normalization or a 75% reduction of serum alkaline phosphatase (SAP) levels in 6 months. A pain scale, gait, and QoL measures were assessed as well. At the completion of this study, a greater number of patients treated with ZOL (96%) achieved the primary end point compared to those treated with RIS (74%, P < 0.001). Further, ZOL provided patients with a significantly shorter median time to first therapeutic response (64 days ZOL vs 89 days RIS, P < 0.001).

In patients with Paget’s disease of bone, normalization of SAP correlates with a longer duration of biochemical remission. SAP levels were normalized in more patients in the ZOL-treated group (88.6%) than in the RIS-treated group (57.9%), P < 0.001. Bone turnover markers, including serum NTx and serum β-CTx, measuring osteoblast function (bone formation) and urinary α-CTx measuring osteoclast function (bone resorption) were all suppressed into the normal range earlier and more consistently in patients treated with ZOL, P < 0.001 (Table 1).

At a median of 190 days following the formal trial, only 0.9% of patients on ZOL showed evidence of recurrent disease activity by biochemical markers compared with 25.6% of patients on RIS, P < 0.001. Although the study was designed to demonstrate the noninferiority of ZOL compared to RIS in the treatment of Paget’s disease, the authors concluded that “ZOL appeared to be superior in terms of the degree of disease suppression, the rate of onset of effect and (on the basis of preliminary data) the persistence of these effects beyond the six-month trial period.” In addition, there was a trend toward improved QoL in patients treated with ZOL.

In a follow-up extension trial of the above study published by Hosking et al,⁶⁶ 152 patients who had been treated with ZOL and 115 patients who had been treated with RIS were followed for 18 months to determine the length of remission and durability of bone suppression. A sustained therapeutic response was noted in 98% of those treated with ZOL vs 57% of those treated with RIS (Table 1).

ZOL in oncology

Skeletal complications contribute substantially to the burden of disease in patients with bone metastases from solid tumors and in patients with multiple myeloma. Bone metastases are the most common cause of cancer-related pain and often require palliative therapy. ZOL is widely used as palliative therapy in patients with bone metastases secondary to a wide range of solid tumors, including prostate cancer, lung cancer, and renal cell carcinoma.⁶⁷

ZOL received approval for the treatment of bone metastases secondary to all solid tumor types and bone lesions from multiple myeloma based on the results of 3 large, randomized, phase III clinical trials enrolling more than 3,000 patients.

These trials demonstrated that ZOL (4 mg via 15-minute IV infusion, every 3–4 weeks) effectively reduced the incidence of skeletal complications associated with malignant bone disease for patients with breast cancer, multiple myeloma, prostate cancer, or solid tumors other than breast or prostate cancer.^68–71 The primary efficacy end point in all 3 trials was the proportion of patients who experienced at least 1 skeletal-related event (SRE), defined as a pathologic fracture, spinal cord compression, radiotherapy to bone, or surgery to bone. Change in antineoplastic therapy to palliate bone pain was also included as an SRE only in the trial evaluating patients with prostate cancer. HCM was included as an SRE in the analysis of secondary end points. The results of these 3 international trials demonstrate that ZOL has significant and durable clinical benefit in reducing skeletal complications for patients with malignant bone involvement from multiple myeloma and a variety of solid tumors, including breast, prostate, and lung cancers.^68–71 ZOL is also being studied for the prevention of aromatase inhibitor-associated bone loss in women receiving adjuvant hormonal therapy for early-stage breast cancer and also for the prevention of bone loss during androgen-deprivation therapy.^72,73

Safety and tolerability of ZOL in osteoporosis and Paget’s disease

Data from several clinical trials have demonstrated that IV ZOL is generally well tolerated in patients with osteoporosis^28,37 and Paget’s disease.^65,66 In the present section, clinically significant adverse events (AEs) associated with the use of ZOL in osteoporosis are discussed. Tolerability data of ZOL vs placebo, ALN, and RIS is also evaluated.

Clinically significant AEs associated with ZOL

Acute-phase reactions

The most common AEs observed with ZOL are acute-phase reactions, usually characterized by flu-like symptoms, headache, pyrexia, arthralgia, and myalgia. Most of these symptoms occur within the first 3 days after infusion and tend to resolve within several days after administration (Table 2).^28,74

Table 2 Summary of five most frequently reported AEs after first infusion of ZOL in the treatment of osteoporosis and Paget’s disease compared with placebo, ALN and RIS

Study	Intervention	N	Any AE, n (%)	Five typical AEs within 3 days of initial dosinga
				Pyrexia, n (%)	Myalgia, n (%)	Influenza-like symptoms, n (%)	Headache, n (%)	Arthralgia, n (%)
ZOL vs placebo
Reid et al^Citation25	ZOL
	4 × 0.25 mg	60	52 (87)	6 (10)	12 (20)	1 (2)	Not reported	9 (15)
	4 × 0.5 mg	58	50 (86)	5 (9)	6 (10)	4 (7)		8 (14)
	4 × 1 mg	53	50 (94)	7 (13)	7 (13)	2 (4)		9 (17)
	2 × 2 mg	61	56 (92)	12 (20)	10 (16)	10 (16)		15 (25)
	1 × 4 mg	60	54 (90)	9 (15)	6 (10)	9 (15)		5 (8)
	Placebo	59	45 (76)	2 (3)	1 (2)	4 (7)	Not reported	9 (15)
Black et al^Citation28 (HORIZON-PFT)	ZOL 5 mg Placebo	3862 3852	3688 (95.5) 3616 (93.9)	621 (16.1) 79 (2.1)	365 (9.5) 66 (1.7)	301 (7.8) 61 (1.6)	273 (7.1) 90 (2.3)	245 (6.3) 76 (2.0)
Lyles et al^Citation43 (HORIZON-RFT)	ZOL 5 mg Placebo	1054 1057	867 (82.3) 852 (80.6)	73 (6.9) 9 (0.9)	33 (3.1) 9 (0.9)	6 (0.6) 3 (0.3)	16 (1.5) 9 (0.9)	33 (3.1) 23 (2.2)
ZOL vs ALN
McClung et al^Citation37	ZOL 5 mg	113	98 (86.7)	Not reported	Not reported	Not reported	14 (12.4)	6 (5.3)
	ALN 70 mg	112	90 (80.4)	Not reported	Not reported	Not reported	7 (6.3)	1 (0.9)
Saag et al^Citation38	ZOL	69	63 (91.3)	4(5.8)	8 (11.6)	13 (18.8)	5 (7.2)	5 (7.2)
	ALN 70 mg	59	51 (86.4)	1 (1.7)	1 (1.7)	3 (5.1)	7 (11.9)	4 (6.8)
ZOL vs RIS
Reid et al^Citation65	ZOL 5 mg	177	146 (82.5)	13 (7.3)	13 (7.3)	17 (9.6)	12 (6.8)	Not reported
	RIS 30 mg	172	133 (77.3)	1 (0.6)	6 (3.5)	7 (4.1)	7 (4.1)	Not reported
Reid et al^Citation59 (Treatment group)	ZOL 5 mg RIS 30 mg	272 273	211 (78) 186 (68)	32 (12) 12 (4)	29 (11) 6 (2)	15 (6) 3 (1)	13 (5) 5 (2)	32 (12) 21 (8)
Reid et al^Citation59 (Prevention group)	ZOL 5 mg RIS 30 mg	144 144	111 (77) 93 (65)	21 (15) 3 (2)	9 (6) 8 (6)	10 (7) 1(1)	9 (6) 5 (3)	9 (6) 10 (7)

Note:

a The 5 symptoms listed were the most frequently cited in Black et al²⁸ and other studies.

Abbreviations: AE, adverse event; ZOL, zoledronic acid; ALN, alendronate; RIS, risedronate; N, number of patients; HORIZON-PFT, The Health Outcomes and Reduced Incidence with Zoledronic Acid Once Yearly-Pivotal Fracture Trial; HORIZON-RFT, HORIZON-Recurrent Fracture Trial.

Hypocalcemia

The incidence of hypocalcemia (a serum calcium level <2.075 mmol/L) with ZOL has been reported in some studies, although in most cases it was asymptomatic and transient.^28,38,43,65 However, in patients with low normal calcium at onset, it is recommend to start with the regular calcium/vitamin D supplementation before the infusion of ZOL.

Renal function

Evaluation of the renal safety of once-yearly ZOL 5 mg in several studies has shown that administration of ZOL was not associated with any long-term detrimental effects on renal function. Generally, the renal effects were short term, mild, and transient.^28,43,59 A minimal infusion time of ZOL of 15 minutes, however, is mandatory to avoid an impairment of renal function.

Cardiovascular: atrial fibrillation

Individual studies of ZOL have found an increased incidence of atrial fibrillation (AF); however, larger epidemiological studies have found no increased risk of AF in patients receiving bisphosphonate treatment.

The only study in the HORIZON clinical trial program where AF was significantly increased as serious AE (SAE) was the HORIZON-PFT study; AF, as SAE, was found to be more frequent in patients who received ZOL compared with placebo (1.3% ZOL vs 0.5% placebo; P < 0.001).²⁸ Of the 50 events that occurred in patients receiving ZOL, 47 (94%) occurred >30 days after infusion, when ZOL was no longer detectable in systemic circulation. Furthermore, electrocardiograms performed on a subset of 559 patients before and 9–11 days after treatment found no differences between the treatment groups.

In the HORIZON-RFT study, which included an older patient population with more comorbidities compared with other osteoporosis trials, the incidence of serious AF was similar with ZOL and placebo (1.0% ZOL vs 1.2% placebo).⁴³ When ZOL was compared with RIS in patients with GIO, no serious AF was reported in either of the treatment arms.⁵⁹

Osteonecrosis of the jaw

In patients receiving high cumulative doses of IV bisphosphonates to prevent SRE associated with bone metastases or HCM, cases of osteonecrosis of the jaw (ONJ) have been reported. As most of these patients were also receiving cytotoxic chemotherapy or corticosteroids, it is difficult to determine the true impact of bisphosphonate treatment on risk of ONJ. In patients receiving lower cumulative doses of bisphosphonates for treatment of osteoporosis, very rare cases of ONJ have been reported.

The safety data from the HORIZON-PFT study showed that of the 7,714 patients in the study, there were only 2 cases of possible ONJ: one in a patient receiving ZOL and other in a patient receiving placebo. Both patients experienced delayed healing associated with infection, and both conditions were resolved after antibiotic therapy or debridement. In several other studies with ZOL for the treatment of osteoporosis and Paget’s disease, no cases of ONJ were reported.^43,59,66

Overall, the incidence of ONJ in osteoporotic patients receiving ZOL is very low, and this can be managed with no special treatment beyond routine dental care.⁷⁵

Tolerability

ZOL vs placebo

Data from the HORIZON trials show that ZOL was generally well tolerated, and there was no significant difference between the ZOL and placebo groups in terms of number of patients who had SAEs, or discontinued follow-up due to an AE. In the HORIZON-PFT study, the number of patients with AEs was significantly higher in the ZOL group (95.5% ZOL vs 93.9% placebo; P = 0.002), driven primarily by larger number of AEs associated with postdose symptoms.²⁸ However, in the HORIZON-RFT study, the difference in the number of AEs between both groups was not significant (82.3% ZOL vs 80.6% placebo).⁴³

The incidence of death was significantly lower in ZOL than that in placebo recipients in the HORIZON-RFT study (9.6% ZOL vs 13.3% placebo; P = 0.01), but not in the HORIZON-PFT study (3.4% ZOL vs 2.9% placebo).^28,43

The tolerability profile of ZOL was generally similar to that of placebo with regard to most cardiovascular-related AEs, and no long-term renal toxicity was associated with ZOL in patients from either the HORIZON-PFT or the HORIZON-RFT study.^28,43

ZOL vs ALN

The overall incidence of AEs in recipients of ZOL 5 mg IV (once-yearly) was generally similar to that seen in recipients of oral ALN 70 mg once-weekly in a comparative trial of 1-year duration (86.7% vs 80.4%).³⁷ No patient died during the course of the study. Treatment-emergent SAEs were reported in 10.6% of ZOL recipients compared with 9.8% of ALN recipients; no SAEs were considered to be study drug related. Only 3.5% ZOL recipients and 0.9% ALN recipients discontinued treatment because of AEs. Within the first 3 days of initial drug administration, treatment-emergent AEs occurred in 36.3% of ZOL recipients compared with 21.4% of ALN recipients (Table 2). Three or more days after initial administration, the incidence of treatment-emergent AEs was broadly similar in ZOL and ALN recipients (77.9% vs 73.2% of patients).³⁷

Safety results from a study by Saag et al³⁸ showed that a comparable proportion of patients reported AEs in each treatment group (ZOL 5 mg, 91.3%; ALN 70 mg, 86.4%). Transient, flu-like symptoms were the most common AEs in the ZOL group and resulted in a higher frequency of AEs in the group during the first 3 days of treatment (Table 2). After 3 days, AE rates were similar in both groups (79.7% ZOL vs 78.0% ALN). There were no deaths during this study. SAEs occurred in 2 patients in the ZOL group (osteoarthritis, chest pain) and 3 patients in the ALN group (1 patella fracture, 2 osteoarthritis). None were considered related to the treatment.

ZOL vs RIS

Safety data from a comparative trial of 1-year duration that tested the effectiveness of once-yearly IV ZOL 5 mg vs daily oralRIS 30 mg, for the prevention and treatment of GIO, showed that the overall incidence of SAEs was similar between the ZOL and RIS groups, but AEs were more common with ZOL than with RIS largely as a result of transient, flu-like symptoms during the first 3 days after infusion (Table 2).⁵⁹

In the treatment subgroup, the most frequently reported SAE for patients tested with ZOL and RIS was worsening rheumatoid arthritis, which was judged to be severe in 2% of patients in each drug group.

In the prevention subgroup, the most frequently reported SAE was pyrexia, which was judged to be severe in 1% of patients in each drug group. No signifcant differences were recorded between the drug groups in either the treatment or the prevention subgroups within the cardiac disorders.⁵⁹ In the treatment subgroup, the incidence of death was comparable between ZOL and RIS, (1% ZOL vs 1% RIS). However, in the prevention subgroup, it was slightly higher in the ZOL vs RIS groups (1% ZOL vs 0% RIS).

In a study by Reid et al⁶⁵ comparing ZOL with RIS in patients with Paget’s disease, the number of patients with AEs (146 ZOL vs 133 RIS; Table 2) and SAEs (9 ZOL vs 11 RIS) were similar in the 2 groups. In the first 3 days, the ZOL group had twice the number of AEs as compared to the RIS group (P < 0.001), and these were principally the flu-like symptoms, known to occur in association with the IV use of nitrogen-containing bisphosphonates (Table 2). Subsequently, the rates of AEs were similar in the 2 groups. The frequencies of gastrointestinal and renal or urinary disorders were similar in the 2 groups. An 18-month extension of the study showed that death rates and SAEs were similar between ZOL and RIS.⁶⁶

Patient considerations and treatment preference

Several large clinical trials have shown the efficacy of bisphosphonates in the treatment of osteoporosis. However, the long-term treatment with bisphosphonates is required for optimal and sustained benefit. Therefore, compliance and adherence to prescribed medication are needed for an evaluable therapeutic benefit to patients.⁷⁶

In the treatment of osteoporosis, nonadherence to bisphosphonate therapy correlates with reduced gains in BMD and lower reductions in the levels of BTMs.^77,78 In addition, nonadherence leads to an increased incidence of secondary complications associated with fractures, such as pain, nosocomial infections, and pulmonary thromboembolism, and hence to a decreased QoL.^78–81

Reasons for the suboptimal adherence to earlier developed bisphosphonates

The main reasons patients cite for not continuing to take their osteoporosis medication are the stringent dosing schedule, AEs, not feeling that treatment is working, and not believing that they have a disease that needs to be treated.⁷⁶ The commonest reasons were the strict dosing requirements for oral bisphosphonates (fasting overnight or for at least 6 hours prior to taking the medication and 30–60 min after administration) and posture (staying upright for 30–60 minutes after taking the medication), which can be inconvenient and often not feasible in the daily routine. The second most common reason for discontinuation of therapy is side effects. The main complaints with oral bisphosphonates are upper gastrointestinal irritation, dyspepsia, nausea, upper abdominal pain, vomiting, and gastroesophageal reflux. Finally, as patients often have no symptoms until they suffer a fracture, they do not feel that treatment is worth taking or do not believe they have a disease that needs treatment. They may consider the pill a burden and the inconvenience of the dosing requirements to be unnecessary.⁷⁶

Evolution of dosing regimens to overcome nonadherence

Initially, all the studies for oral bisphosphonates (ALN, RIS, and ibandronate), which showed antifracture efficacy, were conducted using a daily regimen.^{29–31,33,82} However, the burdensome dosing requirements needed for gastrointestinal protection with daily oral bisphosphonates led to the development of less-frequent oral regimens. As the half-life of bone-bound bisphosphonates is long, weekly dosing of bisphosphonates is possible; moreover, they remain at resorption sites longer than the 2-week lifespan of individual osteoclasts.⁸³ Weekly oral ALN and RIS achieved approval based on comparisons with the respective daily regimens.^84,85 Weekly oral ibandronate has also shown noninferior efficacy to the daily regimen⁸⁶ but has not been marketed. Bisphosphonate pharmacology also makes possible monthly, intermittent, quarterly, or yearly dosing. To improve adherence and persistence, these extended interval regimens were developed. Monthly oral ibandronate, the first approved monthly bisphosphonate regimen, was supported by comparison trials with the daily regimen and is in use since 2005.^34,87 An intermittent oral RIS regimen (2 consecutive days monthly) was approved in April 2007,⁸⁸ and a once-monthly RIS dosing regimen was approved in April 2008.⁸⁹

Intravenous bisphosphonate regimens do not require stringent dosing requirements as oral bisphosphonates, and therefore, it provides alternative options for osteoporosis patients unable to take oral bisphosphonates. Quarterly IV ibandronate injection (3 mg/3 months) became, in 2006, the first IV bisphosphonate to be approved for PMO in the United States and in the EU. Quarterly IV ibandronate has shown efficacy in PMO with a similar safety profile to the monthly oral regimen.⁹⁰ This was followed by once-yearly ZOL 5 mg IV, which is approved globally for up to 6 indications in osteoporosis. It provides the greatest extended dosing interval and reduces concerns about oral administration, gastrointestinal intolerance, and bioavailability. The efficacy and safety of ZOL have been demonstrated from several large randomized trials.^28,37,38,43

Patient preference for once-yearly ZOL dosing

A once-yearly IV ZOL has been preferred by a majority of trial outpatients in 2 separate trials, who switched to ZOL from weekly oral ALN.^37,38 McClung et al³⁷ reported that 79% of patients preferred an annual infusion of ZOL vs weekly oral ALN. Similarly, Saag et al³⁸ reported that a majority of patients (66%) preferred for annual ZOL vs weekly ALN. Moreover, patients who cannot tolerate or do not prefer oral dosing may opt for yearly IV infusion of ZOL.²⁸ Intravenous regimens may also be particularly advantageous for elderly patients residing in long-term care facilities or those with impairments affecting self-management of medication.⁹¹

Optimizing the dosing interval for ZOL

Optimizing the dosing interval for ZOL is important. It is likely that even less frequent administration of ZOL will become more acceptable to patients and hence associated with greater adherence to long-term therapy. It has been demonstrated that the duration of antiresorptive action of a single 5-mg dose of ZOL exceeds 12 months, and it would be worth evaluating the antifracture efficacy of ZOL with a dosing interval of more than 12 months.⁹²

Place of ZOL in the treatment of osteoporosis

In randomized clinical trials, ZOL 5 mg has been proven to be effective in reducing the risk of vertebral, nonvertebral and hip fractures, and to be generally well tolerated in PMO.²⁸ ZOL is the only bisphosphonate to have demonstrated significant risk reduction at all major osteoporotic fracture sites. The 70% relative risk reduction in vertebral fracture at 3 years demonstrated by once-yearly ZOL 5 mg²⁸ is numerically greater than the relative risk reductions shown by ALN (44%)⁸² or RIS (49%).⁹³ ZOL 5 mg has also been shown to be effective in the prevention of clinical fracture in patients (male and female) who have previously experienced a low-trauma hip fracture.⁴³ ZOL 5 mg is the only agent with demonstrated efficacy in this indication. ZOL is also significantly more effective than RIS in preventing and treating GIO.⁵⁹ Most recently, the efficacy of ZOL in treating osteoporosis in men has also been demonstrated.^47,48 The formulation and administration regimen of ZOL 5 mg ensures year-long effectiveness. Thus, it presents an attractive alternative to other daily, weekly, or monthly bisphosphonate therapies. Moreover, several studies are underway to determine the efficacy of ZOL compared with other bisphosphonates, ie, ZOL is being compared with pamidronate in heart- and lung-transplant-related osteopenia and osteoporosis, with ALN in heart and liver transplantations and with ALN in kidney and kidney/pancreas transplantations.⁹⁴

Conclusions

The main aim of treatment in osteoporosis is to reduce the risk of fractures, thereby reducing fracture-associated morbidity and mortality. A once-yearly administration of ZOL 5 mg has the potential to help meet this main clinical need of patients with osteoporosis because clinical evidence suggests that it is more effective than oral bisphosphonates in reducing the risk of vertebral and hip fractures, and it improves compliance through provision of medication over the entire 1-year period in a formulation that is well tolerated.

Review criteria

Searches were performed using PubMed to find material published in English between 2000 and 2009. We used the search terms zoledronic acid, bisphosphonates, osteoporosis, secondary osteoporosis, clinical utility, adherence, patient preference, and Paget’s disease to find full-text articles and abstracts. Reference lists from various articles were also searched for further sources.

Abbreviations

AE	=	adverse event
AF	=	atrial fibrillation
ALN	=	alendronate
BAP	=	bone alkaline phosphatase
BCE	=	bone collagen equivalents
BMD	=	bone mineral density
BSAP	=	bone specific alkaline phosphatase
BTMs	=	bone turn over markers
CTx	=	Serum type I collagen C telopeptide
DXA	=	dual energy X-ray absorptiometry
EU	=	European Union
GIO	=	glucocorticoid-induced osteoporosis
HCM	=	hypercalcemia of malignancy
HORIZON-PFT	=	The Health Outcomes and Reduced Incidence with Zoledronic Acid Once Yearly-Pivotal Fracture Trial
HORIZON-RFT	=	The Health Outcomes and Reduced Incidence with Zoledronic Acid Once Yearly-Recurrent Fracture Trial
IV	=	intravenous
LTO	=	localized transient osteoporosis
NTx	=	N-telopeptide of type I collagen
ONJ	=	osteonecrosis of the jaw
P1NP	=	serum N-terminal propeptide of type I collagen
PMO	=	postmenopausal osteoporosis
QoL	=	quality of life
RIS	=	risedronate
SAE	=	serious adverse event
SAP	=	serum alkaline phosphatase
SE	=	standard error
SRE	=	skeletal-related event
US	=	United States of America
VAS	=	visual analog scale
WHO	=	World Health Organization
ZOL	=	zoledronic acid

Acknowledgements

The author wishes to thank Swati Machwe (Novartis Healthcare Pvt. Ltd., India) for providing editorial support during the preparation of the manuscript.

Disclosure

The author has served in the past as an advisor and given lectures for Novartis and other companies in the field of osteoporosis.