Original Article

Bisphosphonates and Fractures of the Subtrochanteric or Diaphyseal Femur

Dennis M. Black, Ph.D., Michael P. Kelly, M.D., Harry K. Genant, M.D., Lisa Palermo, M.A., Richard Eastell, M.D., Christina Bucci-Rechtweg, M.D., Jane Cauley, Ph.D., Ping Chung Leung, M.D., Steven Boonen, M.D., Ph.D., Arthur Santora, M.D., Anne de Papp, M.D., and Douglas C. Bauer, M.D. for the Fracture Intervention Trial and HORIZON Pivotal Fracture Trial Steering Committees

N Engl J Med 2010; 362:1761-1771May 13, 2010

Abstract

Background

A number of recent case reports and series have identified a subgroup of atypical fractures of the femoral shaft associated with bisphosphonate use. A population-based study did not support this association. Such a relationship has not been examined in randomized trials.

Full Text of Background...

Methods

We performed secondary analyses using the results of three large, randomized bisphosphonate trials: the Fracture Intervention Trial (FIT), the FIT Long-Term Extension (FLEX) trial, and the Health Outcomes and Reduced Incidence with Zoledronic Acid Once Yearly (HORIZON) Pivotal Fracture Trial (PFT). We reviewed fracture records and radiographs (when available) from all hip and femur fractures to identify those below the lesser trochanter and above the distal metaphyseal flare (subtrochanteric and diaphyseal femur fractures) and to assess atypical features. We calculated the relative hazards for subtrochanteric and diaphyseal fractures for each study.

Full Text of Methods...

Results

We reviewed 284 records for hip or femur fractures among 14,195 women in these trials. A total of 12 fractures in 10 patients were classified as occurring in the subtrochanteric or diaphyseal femur, a combined rate of 2.3 per 10,000 patient-years. As compared with placebo, the relative hazard was 1.03 (95% confidence interval [CI], 0.06 to 16.46) for alendronate use in the FIT trial, 1.50 (95% CI, 0.25 to 9.00) for zoledronic acid use in the HORIZON-PFT trial, and 1.33 (95% CI, 0.12 to 14.67) for continued alendronate use in the FLEX trial. Although increases in risk were not significant, confidence intervals were wide.

Full Text of Results...

Conclusions

The occurrence of fracture of the subtrochanteric or diaphyseal femur was very rare, even among women who had been treated with bisphosphonates for as long as 10 years. There was no significant increase in risk associated with bisphosphonate use, but the study was underpowered for definitive conclusions.

Full Text of Discussion...

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Media in This Article

Figure 1Process for Review of Hip and Femur Fractures from Three Clinical Trials.

Table 1Review of Fracture Location in Three Randomized Trials of Bisphosphonates.

Article Activity

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Article

Several case series have described cases of “atypical” subtrochanteric and diaphyseal fractures of the femoral shaft and have suggested that the risk may be increased in long-term users of bisphosphonates.1-13 Descriptions of associated atypical characteristics vary but have been described as a simple transverse or oblique (<30 degrees) fracture with cortical beaking and diffuse cortical thickening.2 Clinical associations that have been mentioned in some reports include low-level trauma, prodromal pain or evidence of a previous stress fracture, contralateral changes, and the use of specific concomitant drugs (including corticosteroids),9,10 antiresorptive drugs (including hormone-replacement therapy),10 and proton-pump inhibitors.13 However, these case reports and series have not had either a controlled or a prospective design and have not systematically examined risk factors.

More recently, a population-based registry evaluated hip and subtrochanteric and diaphyseal femur fractures14 and compared their incidence in alendronate users with that in nonusers. All three fracture types were more common in alendronate users. Given the known efficacy of alendronate for a reduction in the rate of hip fracture, the higher rates of all three types of fracture among alendronate users were attributed to the increased use of alendronate among high-risk patients rather than an increase in risk associated with alendronate. This confounding by indication is a bias often seen in nonrandomized studies.15 The authors concluded that there was no evidence of an increased risk of fracture of the subtrochanteric or diaphyseal femur with either short-term or long-term use of a bisphosphonate. However, population-registry studies have limitations, including their observational, nonrandomized nature, a limited ability for covariate adjustment, and incomplete details with respect to fractures (e.g., precise morphologic features and the presence or absence of trauma).

Randomized, controlled trials may provide unbiased information about femoral-shaft fractures. We evaluated the effect of bisphosphonates on such fractures by reevaluating femur fractures from three large, controlled, blinded, randomized trials of bisphosphonates with more than 14,000 patients and more than 51,000 patient-years of follow-up for up to 10 years.

Methods

Study Design

We examined the incidence of fracture of the subtrochanteric or diaphyseal femur in three large, randomized trials: two that studied the use of oral alendronate (a placebo-controlled phase 3 trial and a randomized extension to 10 years of follow-up) and a placebo-controlled trial of zoledronic acid (infused annually). The trials used similar protocol-specified procedures for original collection and classification of fractures. We reviewed the fractures, using identical methods for the three studies, to identify and describe femoral-shaft fractures and assess atypical features if possible.

Evaluation of Three Trials

Fracture Intervention Trial (FIT)

In this trial, 6459 women over the age of 65 years with a bone mineral density T score of less than −1.6 were recruited16 and randomly assigned to receive daily alendronate (at a dose of 5 mg for 2 years and 10 mg thereafter) or placebo and were followed for 3 to 4.5 years.16-18 Relevant data included demographic characteristics, bone mineral density scores, the use of concomitant medications, previous osteoporosis therapies, adverse events, and levels of biochemical markers of bone turnover.

FIT Long-Term Extension (FLEX) Trial

After the FIT trial ended, women were offered open-label alendronate for 1 year, after which a randomized extension trial began.19 A total of 1099 women who were originally assigned to receive alendronate underwent a second randomization to receive alendronate at a daily dose of 5 mg (in 30% of subjects) or 10 mg (in 30% of subjects) or placebo (in 40% of subjects) and were followed for 5 more years. At baseline in the FLEX trial, the mean duration of alendronate therapy was 5 years; by the end of the trial, the mean duration was 10 years for women who were assigned to the continued alendronate group.

HORIZON Pivotal Fracture Trial

In the Health Outcomes and Reduced Incidence with Zoledronic Acid Once Yearly (HORIZON) Pivotal Fracture Trial (PFT), 7736 women were randomly assigned to receive an annual infusion of 5 mg of zoledronic acid or placebo and were followed for 3 years.20 Inclusion criteria included an age between 65 and 85 years and a bone mineral density T score of less than −2.5 or less than −1.5 in women with a vertebral fracture. Other information included previous osteoporosis medications and concurrent use of all prescription medications, bone mineral density score, and biochemical markers of bone turnover in approximately 20% of the subjects.

Fracture Reporting and Adjudication

The procedures for central adjudication of clinical fractures at the University of California, San Francisco (UCSF), were almost identical in the three studies. Subjects were specifically queried about fractures at study visits. With positive reports, investigators at the clinical site obtained documentation of all fractures, including those associated with trauma. The primary adjudication document was usually either a preoperative radiology report or the surgical medical record. Original radiographs were not generally obtained unless documentation was insufficient or inconclusive.

In the FIT and FLEX trials, hip fractures were classified as involving the femoral neck, the intertrochanteric region, or “miscellaneous hip.” In the HORIZON-PFT trial, a fifth category of subtrochanteric fracture was added. Classification was based on the determination of community radiologists, as interpreted by the central adjudicator at UCSF and was not standardized across clinical centers. These procedures were developed to classify types of hip fractures, not to classify femoral-shaft fractures.

Review of Fractures

Procedures

In 2008, after the publication of reports of atypical femoral-shaft fractures, we began a systematic review of fracture documentation. We used available radiographic and surgical reports to review fractures that originally had been classified as occurring in the hip (with the exception of those involving the femoral neck) and all other femur fractures. The review was performed by a radiologist who was not aware of study-group assignments and who specifically evaluated the location and any atypical features of fractures.

Location of Fractures

In our study, the region of interest was a fracture confined to the area below the lesser trochanter and above the distal metaphyseal flare (hereafter termed subtrochanteric and diaphyseal femur fractures). We excluded all periprosthetic fractures, pathologic fractures (i.e., those occurring in bone weakened by another disease process), and fractures associated with high-energy trauma. Other fracture categories included intertrochanteric only, intertrochanteric to subtrochanteric, and distal metaphysis.

Assessment of Atypia

For fractures meeting the criteria for location, we used radiographs (which were rarely available) for morphologic evaluation. Morphologic measurements included transverse or oblique versus spiral, abnormal cortical thickening (focal or generalized), cortical beaking, medial spiking, and any contralateral similarities. When radiographs were not available, atypical features in the radiology report were recorded.

Study Oversight

The original studies were designed by the steering committees in collaboration with the sponsors (Merck for the FIT and FLEX trials and Novartis for the HORIZON-PFT trial). UCSF investigators were responsible for the collection and adjudication of fracture data for all three studies. All other aspects of data collection were the responsibility of UCSF investigators for the FIT trial and of the sponsors for the FLEX and HORIZON trials. In each study, investigators developed publication guidelines that specified full participation of academic investigators together with sponsors in the publication of results. The two lead academic authors designed the study we report here and wrote the initial draft of the manuscript with substantial input from the other authors. Data analyses were performed solely by members of the UCSF group, who had full access to the study data. Representatives of the sponsors reviewed the final drafts of the manuscript. All authors vouch for the completeness and accuracy of the data.

Statistical Analysis

For each trial, we calculated the risk per 10,000 person-years according to treatment and the relative hazard of fracture of the subtrochanteric or diaphyseal femur for subjects receiving bisphosphonates, as compared with control subjects. We also tabulated selected characteristics for individual subjects, including age, trauma level, and the duration of and adherence to treatment. When available, we compared biochemical-marker values for subjects who were receiving treatment but before the occurrence of a fracture with reference ranges for premenopausal women.21

Results

Subtrochanteric and Diaphyseal Fractures

In all three trials, there were 283 hip or femur fractures (Figure 1Figure 1Process for Review of Hip and Femur Fractures from Three Clinical Trials.). Excluded from the review were 135 femoral-neck or subcapital fractures and 13 periprosthetic, pathologic, or high-energy fractures and 1 hip fracture with insufficient information to classify the location. Of the remaining 134 fractures, 12 were fractures of the subtrochanteric or diaphyseal femur that occurred in 10 women (for whom only one radiograph was available). With 12 fractures during 51,287 patient-years in the three studies, the combined rate was 2.3 per 10,000 patient-years.

FIT Trial

In the FIT trial, we reviewed 31 fractures, of which a majority were either intertrochanteric or extended from the intertrochanteric to the subtrochanteric region (Figure 1). Only two fractures met the criteria for fracture of the subtrochanteric or diaphyseal femur (one in each study group), with an overall rate of 0.8 per 10,000 person-years. The relative hazard among subjects receiving alendronate, as compared with those receiving placebo, was 1.03 (95% confidence interval [CI], 0.06 to 16.46) (Table 1Table 1Review of Fracture Location in Three Randomized Trials of Bisphosphonates.). Details regarding individual patients are shown in Table 2Table 2Characteristics of 10 Patients with 12 Fractures of the Subtrochanteric or Diaphyseal Femur.. Neither of the two women reported having received previous antiresorptive therapy. Levels of biochemical markers for serum C-terminal telopeptide of type 1 collagen (CTX) and serum procollagen type 1 N-propeptide (P1NP) for the women who received alendronate were below the lower limit of the premenopausal range, although the level of bone-specific alkaline phosphatase (BSAP) was within the premenopausal range. One woman was 69 years of age, and the other was 75. Neither reported a history or current use of corticosteroids or proton-pump inhibitors or any diseases affecting bone metabolism.

Horizon-PFT Trial

For the HORIZON-PFT trial, we reviewed 84 hip or femur fractures in 82 women. Five women had six fractures that met the location criteria for fracture of the subtrochanteric or diaphyseal femur; of these women, three were receiving zoledronic acid (2.8 per 10,000 person-years) and two were receiving placebo (1.9 per 10,000 person-years) (relative hazard for zoledronic acid, 1.50; 95% CI, 0.25 to 9.00) (Table 1). The mean age of the five women was 71 years and 2 years below the study mean of 73 years. In three women receiving zoledronic acid, one had simultaneous fractures of both femoral shafts, one had a transverse fracture but no beaking and no focal or generalized cortical thickening on radiography, and one had a spiral fracture on radiography, although the morphologic features were not described as “atypical” in case reports.

For these five fracture events, three events in women receiving zoledronic acid occurred after minimal trauma (a fall from standing height or less), and two events in women receiving placebo occurred after a fall from a stair, step, or curb. Two women (one receiving zoledronic acid and one receiving placebo) reported taking concurrent antiresorptive therapy (raloxifene and injectable calcitonin, respectively), and one woman (who had two simultaneous fractures) reported having previously taken a bisphosphonate (>4 years before baseline) and hormone-replacement therapy. No women reported previous use of corticosteroids. Two women reported having hip pain at some point before the fracture, and the woman with simultaneous fractures had reported “bone pain” at two previous annual visits. Biochemical markers were not assessed in these patients.

FLEX Trial

In the FLEX trial, we reviewed 19 hip or femur fractures, and 4 fractures (occurring in 3 women) met the criteria for fracture of the subtrochanteric or diaphyseal femur: 2 of 662 women receiving alendronate (6.3 per 10,000 patient-years) and 1 of 437 women receiving placebo (4.7 per 10,000 patient-years; relative hazard in the alendronate group, 1.33; 95% CI, 0.12 to 14.67). All women had previously taken alendronate in the FIT trial (mean duration at FLEX baseline, 5 years).19 The two women receiving alendronate had fractures more than 1000 days after randomization but had discontinued therapy 3 years earlier. None of the three women reported previous use of antiresorptive drugs or corticosteroids. One woman receiving alendronate (Subject 8 with two fractures) reported the use of a proton-pump inhibitor. In all three women with fractures in the location of interest, biochemical markers of bone turnover before fracture were substantially above the lower reference value for premenopausal women. The average age of the women (80 years) was about 7 years above the mean in the study. Three fractures occurred after a fall from standing height, while the fourth was due to trauma not associated with a fall.

Discussion

Data from three large, placebo-controlled, randomized trials indicate that the risk of fracture of the subtrochanteric or diaphyseal femur associated with the use of bisphosphonates was extremely low. Although the point estimates of the relative risk with bisphosphonate use suggested no association, confidence intervals were wide because of the small number of events. In addition, in the FLEX trial (the largest and longest randomized extension study of long-term bisphosphonate use), despite an average of 10 years of alendronate use, the risk of fracture of the subtrochanteric or diaphyseal femur was low, with no significant increase among women who continued to receive alendronate for 10 years, as compared with those who discontinued the drug, although again confidence intervals were wide. In all three studies, atypical features could not be fully assessed, since radiographs were not generally available.

The low risk of femoral-shaft fracture is consistent with recent results from a Danish population-based registry.14 That study showed low rates overall, and women receiving alendronate had no higher risk than that caused by their underlying osteoporotic fragility. A recent study that was based on national discharge and medical-claims data in the United States reported similarly low rates of femoral-shaft fracture,22 which made up less than 10% of all hip fractures. In the three studies that we reviewed, even among women with up to 10 years of bisphosphonate exposure, the risk of fracture of the subtrochanteric or diaphyseal femur ranged from one to six cases per 10,000 patient-years. If we had been able to assess atypical characteristics (e.g., cortical thickness and fracture morphology) and limit our consideration to atypical fractures, we probably would have excluded some additional events; this would have further reduced the risk. This assumption is supported by one study showing that only one quarter of subtrochanteric and diaphyseal fractures had atypical features23 and another study showing that approximately one third of low-energy femoral-shaft fractures were transverse or oblique with a small angle.24 Although we can confidently conclude that absolute rates of such fractures are low, wide confidence intervals preclude definitive conclusions regarding the relative risk of treatment.

In the studies that we analyzed here and in other studies, bisphosphonates have been shown to decrease the rates of both vertebral and nonvertebral (including hip) fractures in women with osteoporosis.17,18,20,25 Among women with osteoporosis in the FIT25 and HORIZON-PFT20 trials,25 the estimated numbers of women who would need to be treated were 90 to prevent one hip fracture, 35 to prevent one nonvertebral fracture, and 14 to prevent one morphometric vertebral fracture (Table 3Table 3Comparison of Number of Patients Who Would Need to Be Treated for 3 Years with Bisphosphonates to Prevent One Fracture and the Hypothetical Number Associated with an Increase of One Subtrochanteric or Diaphyseal Fracture.). Thus, we estimated that treating 1000 women with osteoporosis for 3 years would prevent about 100 fractures: 71 vertebral fractures and 29 nonvertebral fractures, including 11 hip fractures.

On the basis of our studies, we estimated that bisphosphonate treatment would result in an annual rate of 2.3 subtrochanteric or diaphyseal fractures per 10,000 patient-years in untreated women with osteoporosis. This rate is consistent with those of the Danish registry study14 and a recent population-based study.22 According to the hypothetical relative risks, the increase in the number of such fractures per 1000 women who are treated for 3 years would be 0.3 events if the relative risk were 1.5, 0.7 events if the relative risk were 2.0, and 1.4 events if the relative risk were 3.0 (Table 3). When balanced against the prevention of 100 fractures, the hypothetical risk is quite small and would be even smaller if the risk were limited to fractures with atypical features.

The Danish observational study showed no relationship between the use of bisphosphonates and the risk of femoral-shaft fracture,14 consistent with our findings. However, these results contrast with those of some case series. For example, one case series2 identified 20 women who had fractures with atypical features (e.g., transverse morphology, cortical thickening, or a low-level trauma), 19 of which were diagnosed in women receiving bisphosphonates. The lack of a control group (together with an inconsistent definition of atypia across case studies) increases the challenge of interpreting discrepancies among the studies. But results from case series suggest that patients taking bisphosphonates who have persistent thigh pain, evidence of a stress fracture, or a contralateral femur fracture should be carefully evaluated for further testing and possible interventions.

It has been suggested that an increased risk of atypical femoral-shaft fracture associated with the use of bisphosphonates may be confined to a small subgroup of patients.3,9 This hypothesis suggests that future studies should attempt to identify risk factors for subtrochanteric or diaphyseal fracture in patients receiving bisphosphonates. Case reports have suggested several risk factors, particularly the concomitant use of corticosteroids.9,10 Other proposed risk factors include concurrent use of proton-pump inhibitors13 and markedly suppressed bone turnover, perhaps owing to the use of multiple antiresorptive medications.8,10 In the HORIZON-PFT trial, one woman in the placebo group who had a femoral-shaft fracture was also receiving injected calcitonin; in the zoledronic-acid group, one woman was also receiving raloxifene, and another had a relevant history of taking multiple antiresorptive medications. In the FIT trial, one woman in the alendronate group had low levels of biochemical markers of bone turnover, but in the FLEX trial, such levels were all well within the premenopausal reference range. Most of the initial case series did not include data on the use of concurrent medications.5,23 Other characteristics that have been suggested as risk factors include a younger age at the time of bisphosphonate initiation, a low pretreatment level of bone turnover, and normal bone mineral density.10 However, none of the characteristics that have been postulated to increase the risk of femoral-shaft fracture among women receiving bisphosphonates have been systematically or prospectively studied.

Our results from the FLEX trial did not show a significant increase in the risk of fracture of the subtrochanteric or diaphyseal femur after 10 years of alendronate use, despite suggestions that a longer duration of use may increase risk. Data regarding duration from the case studies have been mixed. The mean duration in the cases reported by Neviaser et al.2 was 7 years, but the duration of therapy has varied from 2 to 4 years in other reports,8,10,12 suggesting that long-term use of bisphosphonates may not be necessary to increase risk. The Danish registry study showed no increase in risk with long-term use (>10 years). It would be important to identify the effect of the duration of bisphosphonate use so that it could be weighed against benefits in clinical decision making regarding continuing therapy.

Although most of the reported cases of atypical femoral-shaft fracture among bisphosphonate users have occurred in women receiving alendronate (the most commonly used bisphosphonate), cases of such fractures also have been reported among users of ibandronate and risedronate.8,10,12 Furthermore, we found cases of femoral-shaft fracture in patients receiving zoledronic acid, as well as in those receiving placebo, so there is no definitive evidence or theoretical reason to believe that any possible increase in risk would be limited to alendronate.

Rare conditions such as atypical femoral-shaft fractures are difficult to study. The ideal study would be a long, placebo-controlled, randomized trial involving tens of thousands of patients, a study design that is neither feasible nor ethical, given the known efficacy of bisphosphonates to reduce the overall risk of fracture. More rigorous observational studies with the use of a population database with both archived fracture radiographs and medication information might be more feasible.

Although our study was based on randomized trials, it has important limitations. First, we did not have access to radiographs and therefore could not evaluate the atypical features of these fractures. Second, although the studies that we evaluated were large, there were insufficient numbers of events to make definitive conclusions. Third, by design, the use of many potentially confounding medications, including corticosteroids, was excluded from all three studies. The use of other antiresorptive medications was allowed in the HORIZON-PFT trial but excluded in the FIT and FLEX trials. Finally, the two placebo-controlled trials lasted only 3 to 4.5 years and thus could not assess whether the risk of fracture increased with treatment duration. Although the FLEX trial included women who were treated up to 10 years, all women had received bisphosphonates for at least 3 years; therefore, the trial could address only the question of bisphosphonate continuation versus discontinuation.

We conclude that the risk of fracture of the subtrochanteric or diaphyseal femur associated with bisphosphonate use is very low, even in women with osteoporosis who received bisphosphonates for up to 10 years. Given the limitation of a small number of events and wide confidence intervals, these studies did not show a significant increase in the risk of subtrochanteric or diaphyseal fracture with 3 to 4 years of use of alendronate or zoledronic acid or up to 10 years of alendronate use.

Supported by Merck and Novartis.

Dr. Black reports receiving grants (to UCSF) from Merck, Novartis, Amgen, and Roche and travel reimbursements from Merck and Novartis; Dr. Genant, receiving consulting and lecture fees and grant support from Merck and Novartis; Ms. Palermo, receiving support from Nycomed for data analysis; Dr. Eastell, serving on advisory boards for Procter & Gamble and the Medical Research Council and receiving consulting fees from Amgen, AstraZeneca, GlaxoSmithKline, Medtronics, Nastech, Nestle, Fonterra Brands, Novartis, Ono Pharma, Osteologix, Pfizer, Lilly, Sanofi-Aventis, Tethys, Unilever, Unipath, Inverness Medical, Ortho Clinical Diagnostics, OSI Prosidion, and Roche, lecture fees from Takeda, Lilly, Amgen, National Osteoporosis Foundation, Procter & Gamble, and GlaxoSmithKline Nutrition, and travel expenses from Novartis; Dr. Bucci-Rechwig, being a full-time employee of and having an equity interest in Novartis; Dr. Cauley, receiving consulting fees from Novartis; Drs. Santora and de Papp, being full-time employees of and having equity interests in Merck; and Dr. Bauer, receiving consulting fees from Amgen and lecture fees from Merck. Disclosure forms provided by the authors are available with the full text of this article at NEJM.org.

No other potential conflict of interest relevant to this article was reported.

This article (10.1056/NEJMoa1001086) was published on March 24, 2010, at NEJM.org.

We thank Lewis Nusgarten for help in compiling the fracture records for review and Thuy Le for assistance in the preparation of the manuscript.

Source Information

From the University of California at San Francisco, San Francisco (D.M.B., M.P.K., H.K.G., L.P., D.C.B.); University of Sheffield, Sheffield, United Kingdom (R.E.); Novartis Pharmaceuticals, East Hanover, NJ (C.B.-R.); University of Pittsburgh, Pittsburgh (J.C.); Chinese University of Hong Kong, Hong Kong (P.C.L.); Katholieke Universiteit Leuven, Leuven, Belgium (S.B.); and Merck Research Laboratories, Rahway, NJ (A.S., A.P.).

Address reprint requests to Dr. Black at 185 Berry St., Suite 5700, University of California, San Francisco, San Francisco, CA 94107, or at dblack@psg.ucsf.edu.

References

References

1. 1

   Lenart BA, Lorich DG, Lane JM. Atypical fractures of the femoral diaphysis in postmenopausal women taking alendronate. N Engl J Med 2008;358:1304-1306
   Full Text | Web of Science | Medline

2. 2

   Neviaser AS, Lane JM, Lenart BA, Edobor-Osula F, Lorich DG. Low-energy femoral shaft fractures associated with alendronate use. J Orthop Trauma 2008;22:346-350
   CrossRef | Web of Science | Medline

3. 3

   Visekruna M, Wilson D, McKiernan FE. Severely suppressed bone turnover and atypical skeletal fragility. J Clin Endocrinol Metab 2008;93:2948-2952
   CrossRef | Web of Science | Medline

4. 4

   Odvina CV, Zerwekh JE, Rao DS, Maalouf N, Gottschalk FA, Pak CY. Severely suppressed bone turnover: a potential complication of alendronate therapy. J Clin Endocrinol Metab 2005;90:1294-1301
   CrossRef | Web of Science | Medline

5. 5

   Goh SK, Yang KY, Koh JS, et al. Subtrochanteric insufficiency fractures in patients on alendronate therapy: a caution. J Bone Joint Surg Br 2007;89:349-353
   CrossRef | Web of Science | Medline

6. 6

   Armamento-Villareal R, Napoli N, Panwar V, Novack D. Suppressed bone turnover during alendronate therapy for high-turnover osteoporosis. N Engl J Med 2006;355:2048-2050
   Full Text | Web of Science | Medline

7. 7

   Cheung RK, Leung KK, Lee KC, Chow TC. Sequential non-traumatic femoral shaft fractures in a patient on long-term alendronate. Hong Kong Med J 2007;13:485-489
   Medline

8. 8

   Armamento-Villareal R, Napoli N, Diemer K, et al. Bone turnover in bone biopsies of patients with low-energy cortical fractures receiving bisphosphonates: a case series. Calcif Tissue Int 2009;85:37-44
   CrossRef | Web of Science | Medline

9. 9

   Somford MP, Draijer FW, Thomassen BJ, Chavassieux PM, Boivin G, Papapoulos SE. Bilateral fractures of the femur diaphysis in a patient with rheumatoid arthritis on long-term treatment with alendronate: clues to the mechanism of increased bone fragility. J Bone Miner Res 2009;24:1736-1740
   CrossRef | Web of Science | Medline

10. 10

    Odvina CV, Levy S, Rao S, Zerwekh JE, Sudhaker Rao D. Unusual mid-shaft fractures during long term bisphosphonate therapy. Clin Endocrinol (Oxf) 2009 March 19 (Epub ahead of print).
    

11. 11

    Capeci CM, Tejwani NC. Bilateral low-energy simultaneous or sequential femoral fractures in patients on long-term alendronate therapy. J Bone Joint Surg Am 2009;91:2556-2561
    CrossRef | Web of Science | Medline

12. 12

    Kwek EB, Goh SK, Koh JS, Png MA, Howe TS. An emerging pattern of subtrochanteric stress fractures: a long-term complication of alendronate therapy? Injury 2008;39:224-231
    CrossRef | Web of Science | Medline

13. 13

    Ing-Lorenzini K, Desmeules J, Plachta O, Suva D, Dayer P, Peter R. Low-energy femoral fractures associated with the long-term use of bisphosphonates: a case series from a Swiss university hospital. Drug Saf 2009;32:775-785
    CrossRef | Web of Science | Medline

14. 14

    Abrahamsen B, Eiken P, Eastell R. Subtrochanteric and diaphyseal femur fractures in patients treated with alendronate: a register-based national cohort study. J Bone Miner Res 2009;24:1095-1102
    CrossRef | Web of Science | Medline

15. 15

    Walker AM. Confounding by indication. Epidemiology 1996;7:335-336
    Web of Science | Medline

16. 16

    Black DM, Reiss TF, Nevitt MC, Cauley J, Karpf D, Cummings SR. Design of the Fracture Intervention Trial. Osteoporos Int 1993;3:Suppl 3:S29-S39
    CrossRef | Web of Science | Medline

17. 17

    Black DM, Cummings SR, Karpf DB, et al. Randomised trial of effect of alendronate on risk of fracture in women with existing vertebral fractures. Lancet 1996;348:1535-1541
    CrossRef | Web of Science | Medline

18. 18

    Cummings SR, Black DM, Thompson DE, et al. Effect of alendronate on risk of fracture in women with low bone density but without vertebral fractures: results from the Fracture Intervention Trial. JAMA 1998;280:2077-2082
    CrossRef | Web of Science | Medline

19. 19

    Black DM, Schwartz AV, Ensrud KE, et al. Effects of continuing or stopping alendronate after 5 years of treatment: the Fracture Intervention Trial Long-term Extension (FLEX): a randomized trial. JAMA 2006;296:2927-2938
    CrossRef | Web of Science | Medline

20. 20

    Black DM, Delmas PD, Eastell R, et al. Once-yearly zoledronic acid for treatment of postmenopausal osteoporosis. N Engl J Med 2007;356:1809-1822
    Full Text | Web of Science | Medline

21. 21

    Glover SJ, Gall M, Schoenborn-Kellenberger O, et al. Establishing a reference interval for bone turnover markers in 637 healthy, young, premenopausal women from the United Kingdom, France, Belgium, and the United States. J Bone Miner Res 2009;24:389-397
    CrossRef | Web of Science | Medline

22. 22

    Nieves JW, Bilezikian JP, Lane JM, et al. Fragility fractures of the hip and femur: incidence and patient characteristics. Osteoporos Int 2010;21:399-408
    CrossRef | Web of Science | Medline

23. 23

    Lenart BA, Neviaser AS, Lyman S, et al. Association of low-energy femoral fractures with prolonged bisphosphonate use: a case control study. Osteoporos Int 2009;20:1353-1362
    CrossRef | Web of Science | Medline

24. 24

    Salminen S, Pihlajamaki H, Avikainen V, Kyro A, Bostman O. Specific features associated with femoral shaft fractures caused by low-energy trauma. J Trauma 1997;43:117-122
    CrossRef | Web of Science | Medline

25. 25

    Black DM, Thompson DE, Bauer DC, et al. Fracture risk reduction with alendronate in women with osteoporosis: the Fracture Intervention Trial. J Clin Endocrinol Metab 2000;85:4118-4124
    CrossRef | Web of Science | Medline

Citing Articles (84)

Citing Articles

1. 1

   P. Hadji, D. Gamerdinger, W. Spieler, P. H. Kann, H. Loeffler, K. Articus, R. Möricke, V. Ziller. (2012) Rapid Onset and Sustained Efficacy (ROSE) study: results of a randomised, multicentre trial comparing the effect of zoledronic acid or alendronate on bone metabolism in postmenopausal women with low bone mass. Osteoporosis International 23:2, 625-633
   CrossRef

2. 2

   Pawel Szulc. (2012) The role of bone turnover markers in monitoring treatment in postmenopausal osteoporosis. Clinical Biochemistry
   CrossRef

3. 3

   C. Haile Chesnut, Charles H. Chesnut. (2012) Can PET-CT Imaging and Radiokinetic Analyses Provide Useful Clinical Information on Atypical Femoral Shaft Fracture in Osteoporotic Patients?. Current Osteoporosis Reports
   CrossRef

4. 4

   Ann V. Schwartz. (2012) Clinical Aspects of Diabetic Bone Disease: An Update. Clinical Reviews in Bone and Mineral Metabolism
   CrossRef

5. 5

   N. Nicolaou, Y. Agrawal, M. Padman, J. A. Fernandes, M. J. Bell. (2012) Changing pattern of femoral fractures in osteogenesis imperfecta with prolonged use of bisphosphonates. Journal of Children's Orthopaedics
   CrossRef

6. 6

   Brian McClune, Navneet S. Majhail, Mary E.D. Flowers. (2012) Bone Loss and Avascular Necrosis of Bone After Hematopoietic Cell Transplantation. Seminars in Hematology 49:1, 59-65
   CrossRef

7. 7

   Uma Gunasekaran, Neena Agarwal, Madan H. Jagasia, Shubhada M. Jagasia. (2012) Endocrine Complications in Long-Term Survivors After Allogeneic Stem Cell Transplant. Seminars in Hematology 49:1, 66-72
   CrossRef

8. 8

   Maurice Audran, Bernard Cortet, Thierry Thomas. (2011) What do we know about atypical femoral fractures? Insights and enigmas. Joint Bone Spine 78:6, 568-571
   CrossRef

9. 9

   Kristian Bjørgul, Astor Reigstad. (2011) Atypical fracture of the ulna associated with alendronate use. Acta Orthopaedica 82:6, 761-763
   CrossRef

10. 10

    Rami El Rachkidi, Marie-Laure Sari-Leret, Stephane Wolff. (2011) Atypical Bilateral Pedicle Fracture in Long-Term Bisphosphonate Therapy. Spine 36:26, E1769-E1773
    CrossRef

11. 11

    Scott A. Guelcher, Julie A. Sterling. (2011) Contribution of Bone Tissue Modulus to Breast Cancer Metastasis to Bone. Cancer Microenvironment 4:3, 247-259
    CrossRef

12. 12

    J. Compston. (2011) Pathophysiology of atypical femoral fractures and osteonecrosis of the jaw. Osteoporosis International 22:12, 2951-2961
    CrossRef

13. 13

    Jonathan D. Adachi, Kenneth Lyles, Steven Boonen, Cathleen Colón-Emeric, Lars Hyldstrup, Lars Nordsletten, Carl Pieper, Chris Recknor, Guoqin Su, Christina Bucci-Rechtweg, Jay Magaziner. (2011) Subtrochanteric Fractures in Bisphosphonate-Naive Patients: Results from the HORIZON-Recurrent Fracture Trial. Calcified Tissue International 89:6, 427-433
    CrossRef

14. 14

    R. Lenz, M. Ellenrieder, R. Skripitz, R. Bader, C. Pautke, W. Mittelmeier, T. Tischer. (2011) Bisphosphonatinduzierte Stressfrakturen am Femur. Der Orthopäde 40:12, 1111-1118
    CrossRef

15. 15

    Crystal K. Tjhia, Clarita V. Odvina, D. Sudhaker Rao, Susan M. Stover, Xiang Wang, David P. Fyhrie. (2011) Mechanical property and tissue mineral density differences among severely suppressed bone turnover (SSBT) patients, osteoporotic patients, and normal subjects. Bone 49:6, 1279-1289
    CrossRef

16. 16

    A. Zarza Pérez, J. L. Martín Alguacil, B. Campos Melenchón, A. D. Delgado Martínez. (2011) Low-energy spontaneous femoral fractures in patients with long-term bisphosphonate therapy. European Journal of Orthopaedic Surgery & Traumatology
    CrossRef

17. 17

    Fei-Yuan Hsiao, Weng-Foung Huang, Yi-Ming Chen, Yu-Wen Wen, Yu-Hsiang Kao, Liang-Kung Chen, Yi-Wen Tsai. (2011) Hip and Subtrochanteric or Diaphyseal Femoral Fractures in Alendronate Users: A 10-Year, Nationwide Retrospective Cohort Study in Taiwanese Women. Clinical Therapeutics 33:11, 1659-1667
    CrossRef

18. 18

    Lluís Pérez Edo, Alberto Alonso Ruiz, Daniel Roig Vilaseca, Alberto García Vadillo, Nuria Guañabens Gay, Pilar Peris, Antonio Torrijos Eslava, Chesús Beltrán Audera, Jordi Fiter Aresté, Luis Arboleya Rodríguez, Jenaro Graña Gil, Jordi Carbonell Abelló, Joan Miquel Nolla, Susana Holgado Pérez, Esteban Salas Heredia, Jaime Zubieta Tabernero, Javier Del Pino Montes, Josep Blanch i Rubió, Manuel Caamaño Freire, Manuel Rodríguez Pérez, Santos Castañeda, Dacia Cerdá, Carmen Gómez Vaquero, Javier Calvo Catalá, Manel Ciria, Estíbaliz Loza. (2011) Actualización 2011 del consenso Sociedad Española de Reumatología de osteoporosis. Reumatología Clínica 7:6, 357-379
    CrossRef

19. 19

    Judith Haschka, Friederike Kühne, Christian Muschitz, Thomas Pirker, Roland Kocijan, Christina Bittighofer, Angela Trubrich, Heinrich Resch. (2011) The 5-year follow-up of a cortical stress fracture resulting in a spontaneous atypical subtrochanteric femoral fracture in a female patient with severe osteoporosis and bisphosphonate therapy over 15 years. Wiener klinische Wochenschrift 123:21-22, 684-687
    CrossRef

20. 20

    Barbara J. Messinger-Rapport, John E. Morley, David R. Thomas, Julie K. Gammack. (2011) Clinical Update on Nursing Home Medicine: 2011. Journal of the American Medical Directors Association 12:9, 615-626.e6
    CrossRef

21. 21

    Lluis Pérez Edo, Alberto Alonso Ruiz, Daniel Roig Vilaseca, Alberto García Vadillo, Nuria Guañabens Gay, Pilar Peris, Antonio Torrijos Eslava, Chesús Beltrán Audera, Jordi Fiter Aresté, Luis Arboleya Rodríguez, Jenaro Graña Gil, Jordi Carbonell Abelló, Joan Miquel Nolla, Susana Holgado Pérez, Esteban Salas Heredia, Jaime Zubieta Tabernero, Javier Del Pino Montes, Josep Blanch i. Rubió, Manuel Caamaño Freire, Manuel Rodríguez Pérez, Santos Castañeda, Dacia Cerdá, Carmen Gómez Vaquero, Javier Calvo Catalá, Manel Ciria, Estíbaliz Loza. (2011) 2011 Up-Date of the Consensus Statement of the Spanish Society of Rheumatology on Osteoporosis. Reumatolog ía Cl ínica (English Edition) 7:6, 357-379
    CrossRef

22. 22

    Karen Tipples, Anne Robinson. (2011) Optimal Management of Cancer Treatment-Induced Bone Loss. Drugs & Aging 28:11, 867-883
    CrossRef

23. 23

    Pongthorn Narongroeknawin, Nivedita M. Patkar, Bita Shakoory, Archana Jain, Jeffrey R. Curtis, Elizabeth Delzell, Philip H. Lander, Robert R. Lopez-Ben, Michael J. Pitt, Monika M. Safford, David A. Volgas, Kenneth G. Saag. (2011) Validation of Diagnostic Codes for Subtrochanteric, Diaphyseal, and Atypical Femoral Fractures Using Administrative Claims Data. Journal of Clinical Densitometry
    CrossRef

24. 24

    Kazuo Ishizuna, Daisuke Ota, Atsushi Fukuuchi, Megumi Teraoka, Akiko Fujii, Masaya Mori, Tsunehiro Nishi. (2011) A case of femoral diaphyseal fracture after long-term treatment with zoledronic acid. Breast Cancer
    CrossRef

25. 25

    Maurice Audran, Bernard Cortet, Thierry Thomas. (2011) Que sait-on des fractures fémorales atypiques ? Entre progrès et inconnues. Revue du Rhumatisme 78:5, 423-426
    CrossRef

26. 26

    J.R. Caeiro-Rey, I. Etxebarria-Foronda, M. Mesa-Ramos. (2011) Atypical fractures associated with the long term use of bisphosphonates. The current situation. Revista Española de Cirugía Ortopédica y Traumatología (English Edition) 55:5, 392-404
    CrossRef

27. 27

    S. Bobo Tanner. (2011) Choosing a Treatment for Patients at the Time a Fracture is Presented. Current Osteoporosis Reports 9:3, 156-159
    CrossRef

28. 28

    René Rizzoli, Jean-Yves Reginster. (2011) Adverse drug reactions to osteoporosis treatments. Expert Review of Clinical Pharmacology 4:5, 593-604
    CrossRef

29. 29

    Ian R. Reid. (2011) Bisphosphonates in the treatment of osteoporosis: a review of their contribution and controversies. Skeletal Radiology 40:9, 1191-1196
    CrossRef

30. 30

    J.R. Caeiro-Rey, I. Etxebarria-Foronda, M. Mesa-Ramos. (2011) Fracturas atípicas relacionadas con el uso prolongado de bifosfonatos. Estado de la situación. Revista Española de Cirugía Ortopédica y Traumatología 55:5, 392-404
    CrossRef

31. 31

    Jie Zhang, Kenneth G. Saag, Jeffrey R. Curtis. (2011) Long-term Safety Concerns of Antiresorptive Therapy. Rheumatic Disease Clinics of North America 37:3, 387-400
    CrossRef

32. 32

    Roger H Jay, Sarah L Marrinan. (2011) Osteoporosis treatment and the older patient. Reviews in Clinical Gerontology 21:03, 233-245
    CrossRef

33. 33

    René Rizzoli, Jean-Yves Reginster, Steven Boonen, Gérard Bréart, Adolfo Diez-Perez, Dieter Felsenberg, Jean-Marc Kaufman, John A. Kanis, Cyrus Cooper. (2011) Adverse Reactions and Drug–Drug Interactions in the Management of Women with Postmenopausal Osteoporosis. Calcified Tissue International 89:2, 91-104
    CrossRef

34. 34

    Robert R. Recker, Laura Armas. (2011) The Effect of Antiresorptives on Bone Quality. Clinical Orthopaedics and Related Research® 469:8, 2207-2214
    CrossRef

35. 35

    Andrew J. Laster, S. Bobo Tanner. (2011) Duration of Treatment in Postmenopausal Osteoporosis: How Long to Treat and What are the Consequences of Cessation of Treatment?. Rheumatic Disease Clinics of North America 37:3, 323-336
    CrossRef

36. 36

    Ilona Nurmi-Lüthje, Reijo Sund, Merja Juntunen, Peter Lüthje. (2011) Post-hip fracture use of prescribed calcium plus vitamin D or vitamin D supplements and antiosteoporotic drugs is associated with lower mortality: A nationwide study in Finland. Journal of Bone and Mineral Research 26:8, 1845-1853
    CrossRef

37. 37

    Hsi-Hsien Lin, Tung-Fu Huang, Shih-Chieh Hung, Hsiao-Li Ma, Chien-Lin Liu. (2011) Clinical presentation and pathological features of atypical subtrochanteric fracture after bisphosphonate treatment. European Journal of Orthopaedic Surgery & Traumatology
    CrossRef

38. 38

    Weinstein, Robert S., . (2011) Glucocorticoid-Induced Bone Disease. New England Journal of Medicine 365:1, 62-70
    Full Text

39. 39

    Yoram A. Weil, Gurion Rivkin, Ori Safran, Meir Liebergall, A. Joseph Foldes. (2011) The Outcome of Surgically Treated Femur Fractures Associated With Long-Term Bisphosphonate Use. The Journal of Trauma: Injury, Infection, and Critical Care 71:1, 186-190
    CrossRef

40. 40

    Mikko T. Ovaska, Tatu J. Mäkinen, Rami Madanat. (2011) Simultaneous bilateral subtrochanteric fractures following risedronate therapy. Journal of Orthopaedic Science 16:4, 467-470
    CrossRef

41. 41

    Michael B. Banffy, Mark S. Vrahas, John E. Ready, John A. Abraham. (2011) Nonoperative versus Prophylactic Treatment of Bisphosphonate-associated Femoral Stress Fractures. Clinical Orthopaedics and Related Research® 469:7, 2028-2034
    CrossRef

42. 42

    P. Hadji. (2011) Managing bone health with zoledronic acid: a review of randomized clinical study results. Climacteric 14:3, 321-332
    CrossRef

43. 43

    Jie Zhang, Huifeng Yun, Nicole C. Wright, Meredith Kilgore, Kenneth G. Saag, Elizabeth Delzell. (2011) Potential and Pitfalls of Using Large Administrative Claims Data to Study the Safety of Osteoporosis Therapies. Current Rheumatology Reports 13:3, 273-282
    CrossRef

44. 44

    William G. Dixon, Daniel H. Solomon. (2011) Bisphosphonates and esophageal cancer—a pathway through the confusion. Nature Reviews Rheumatology 7:6, 369-372
    CrossRef

45. 45

    Christopher J Yates, Miriam J Bartlett, Peter R Ebeling. (2011) An atypical subtrochanteric femoral fracture from pycnodysostosis: A lesson from nature. Journal of Bone and Mineral Research 26:6, 1377-1379
    CrossRef

46. 46

    Erin Hommel, Adline Ghazi, Heidi White. (2011) Minimal Trauma Fractures: Lifting the Specter of Misconduct by Identifying Risk Factors and Planning for Prevention. Journal of the American Medical Directors Association
    CrossRef

47. 47

    Yoshitomo Kajino, Tamon Kabata, Koji Watanabe, Hiroyuki Tsuchiya. (2011) Histological finding of atypical subtrochanteric fracture after long-term alendronate therapy. Journal of Orthopaedic Science
    CrossRef

48. 48

    Schilcher, Jörg, Michaëlsson, Karl, Aspenberg, Per, . (2011) Bisphosphonate Use and Atypical Fractures of the Femoral Shaft. New England Journal of Medicine 364:18, 1728-1737
    Full Text

49. 49

    Seo Young Kim, Sebastian Schneeweiss, Jeffrey N Katz, Raisa Levin, Daniel H Solomon. (2011) Oral bisphosphonates and risk of subtrochanteric or diaphyseal femur fractures in a population-based cohort. Journal of Bone and Mineral Research 26:5, 993-1001
    CrossRef

50. 50

    Ari VanderWalde, Arti Hurria. (2011) Aging and osteoporosis in breast and prostate cancer. CA: A Cancer Journal for Clinicians 61:3, 139-156
    CrossRef

51. 51

    Christian M. Girgis, Markus J. Seibel. (2011) Guilt by association? Examining the role of bisphosphonate therapy in the development of atypical femur fractures. Bone 48:5, 963-965
    CrossRef

52. 52

    Andrea Giusti, Neveen A.T. Hamdy, Olaf M. Dekkers, Sharita R. Ramautar, Sander Dijkstra, Socrates E. Papapoulos. (2011) Atypical fractures and bisphosphonate therapy: A cohort study of patients with femoral fracture with radiographic adjudication of fracture site and features. Bone 48:5, 966-971
    CrossRef

53. 53

    Paul A. Meyers, John H. Healey, Alexander J. Chou, Leonard H. Wexler, Pamela R. Merola, Carol D. Morris, Michael P. Laquaglia, Michael G. Kellick, Sara J. Abramson, Richard Gorlick. (2011) Addition of pamidronate to chemotherapy for the treatment of osteosarcoma. Cancer 117:8, 1736-1744
    CrossRef

54. 54

    Gerald W. Smetana, Jane S. Sillman. (2011) Update in New Medications for Primary Care. Journal of General Internal Medicine 26:4, 427-432
    CrossRef

55. 55

    E. Michael Lewiecki. (2011) Safety of Long-Term Bisphosphonate Therapy for the Management of Osteoporosis. Drugs 71:6, 791-814
    CrossRef

56. 56

    Linda Brewer, David Williams, Alan Moore. (2011) Current and future treatment options in osteoporosis. European Journal of Clinical Pharmacology 67:4, 321-331
    CrossRef

57. 57

    Chris Recknor. (2011) Zoledronic acid for prevention and treatment of osteoporosis. Expert Opinion on Pharmacotherapy 12:5, 807-815
    CrossRef

58. 58

    R. Rizzoli. (2011) Bisphosphonates for post-menopausal osteoporosis: are they all the same?. QJM 104:4, 281-300
    CrossRef

59. 59

    Sigrun Ressler, Brigitte Mlineritsch, Richard Greil. (2011) Zoledronic acid for adjuvant use in patients with breast cancer. Expert Review of Anticancer Therapy 11:3, 333-349
    CrossRef

60. 60

    Khashayar Sakhaee. (2011) Osteoporosis following organ transplantation: pathogenesis, diagnosis and management. Expert Review of Endocrinology & Metabolism 6:2, 157-176
    CrossRef

61. 61

    Zhong Wang, Timothy Bhattacharyya. (2011) Trends in Incidence of Subtrochanteric Fragility Fractures and Bisphosphonate Use Among the US Elderly, 1996-2007. Journal of Bone and Mineral Research 26:3, 553-560
    CrossRef

62. 62

    Kaiya Osugi, Shigeki Miwa, Shinobu Marukawa, Kouhei Marukawa, Yoshiharu Kawaguchi, Shinichi Nakato. (2011) Diaphyseal femoral fatigue fracture associated with bisphosphonate therapy – 3 more cases. Acta Orthopaedica 82:1, 112-113
    CrossRef

63. 63

    R. Rizzoli, K. Åkesson, M. Bouxsein, J. A. Kanis, N. Napoli, S. Papapoulos, J.-Y. Reginster, C. Cooper. (2011) Subtrochanteric fractures after long-term treatment with bisphosphonates: a European Society on Clinical and Economic Aspects of Osteoporosis and Osteoarthritis, and International Osteoporosis Foundation Working Group Report. Osteoporosis International 22:2, 373-390
    CrossRef

64. 64

    Andrew E. Horvai, Brendan F. Boyce. (2011) Metabolic bone diseases. Seminars in Diagnostic Pathology 28:1, 13-25
    CrossRef

65. 65

    Socrates E. Papapoulos. (2011) Use of bisphosphonates in the management of postmenopausal osteoporosis. Annals of the New York Academy of Sciences 1218:1, 15-32
    CrossRef

66. 66

    Tero Yli-Kyyny. (2011) Bisphosphonates and Atypical Fractures of Femur. Journal of Osteoporosis 2011, 1-5
    CrossRef

67. 67

    Frederick R. Singer. (2011) Metabolic bone disease: Atypical femoral fractures. Journal of Biomechanics 44:2, 244-247
    CrossRef

68. 68

    E. Michael Lewiecki, John P. Bilezikian, Sundeep Khosla, Robert Marcus, Michael R. McClung, Paul D. Miller, Nelson B. Watts, Michael Maricic. (2011) Osteoporosis Update From the 2010 Santa Fe Bone Symposium. Journal of Clinical Densitometry 14:1, 1-21
    CrossRef

69. 69

    J. Christopher Gallagher, Jeffrey P. Levine. (2011) Preventing osteoporosis in symptomatic postmenopausal women. Menopause 18:1, 109-118
    CrossRef

70. 70

    Luis Arboleya, Mercedes Alperi, Sara Alonso. (2011) Adverse effects of bisphosphonates. Reumatolog ía Cl ínica (English Edition) 7:3, 189-197
    CrossRef

71. 71

    D.M. Black, I.R. Reid, S. Boonen, C. Bucci-Rechtweg, J.A. Cauley, F. Cosman, S.R. Cummings, T.F. Hue, K. Lippuner, P. Lakatos, P.C. Leung, Z. Man, R. Martinez, M. Tan, M.E. Ruzycky, G. Su, R. Eastell. (2011) The effect of 3 versus 6 years of zoledronic acid treatment of osteoporosis: a randomized extension to the HORIZON-Pivotal Fracture Trial (PFT). Journal of Bone and Mineral Researchn/a-n/a
    CrossRef

72. 72

    B. N. Savani, M. L. Griffith, S. Jagasia, S. J. Lee. (2010) How I treat late effects in adults after allogeneic stem cell transplantation. Blood
    CrossRef

73. 73

    S. J. Gallacher, T. Dixon. (2010) Impact of Treatments for Postmenopausal Osteoporosis (Bisphosphonates, Parathyroid Hormone, Strontium Ranelate, and Denosumab) on Bone Quality: A Systematic Review. Calcified Tissue International 87:6, 469-484
    CrossRef

74. 74

    Arodi Alvarez, Richard Kremer, Deborah R. Weiss, Andrea Benedetti, Muriel Haziza, Daria A. Trojan. (2010) Response of Postpoliomyelitis Patients to Bisphosphonate Treatment. PM&R 2:12, 1094-1103
    CrossRef

75. 75

    Joel A. Horning, John Czajka, Richard L. Uhl, David J. Hak, Philip F. Stahel. (2010) Atypical Diaphyseal Femur Fractures in Patients with Prolonged Administration of Bisphosphonate Medication for Osteoporosis. Orthopedics 33:12, 902-905
    CrossRef

76. 76

    Yong-Chan Ha, Myung-Rae Cho, Ki Hong Park, Shin-Yoon Kim, Kyung-Hoi Koo. (2010) Is Surgery Necessary for Femoral Insufficiency Fractures after Long-term Bisphosphonate Therapy?. Clinical Orthopaedics and Related Research® 468:12, 3393-3398
    CrossRef

77. 77

    Nadia Mehsen, Julien Paccou, Cyrille B. Confavreux, Claire David, Ariane Leboime, Michel Laroche. (2010) Management of patients with incident fractures during osteoporosis treatment. Joint Bone Spine 77, S133-S138
    CrossRef

78. 78

    Favus, Murray J., . (2010) Bisphosphonates for Osteoporosis. New England Journal of Medicine 363:21, 2027-2035
    Full Text

79. 79

    Elizabeth Shane, David Burr, Peter R Ebeling, Bo Abrahamsen, Robert A Adler, Thomas D Brown, Angela M Cheung, Felicia Cosman, Jeffrey R Curtis, Richard Dell, David Dempster, Thomas A Einhorn, Harry K Genant, Piet Geusens, Klaus Klaushofer, Kenneth Koval, Joseph M Lane, Fergus McKiernan, Ross McKinney, Alvin Ng, Jeri Nieves, Regis O'Keefe, Socrates Papapoulos, Howe Tet Sen, Marjolein CH van der Meulen, Robert S Weinstein, Michael Whyte. (2010) Atypical subtrochanteric and diaphyseal femoral fractures: Report of a task force of the american society for bone and mineral Research. Journal of Bone and Mineral Research 25:11, 2267-2294
    CrossRef

80. 80

    (2010) Bisphosphonates and Atypical Femoral Fractures. New England Journal of Medicine 363:11, 1083-1085
    Full Text

81. 81

    Andrea Giusti, Neveen A.T. Hamdy, Socrates E. Papapoulos. (2010) Atypical fractures of the femur and bisphosphonate therapy. Bone 47:2, 169-180
    CrossRef

82. 82

    Carol Wilson. (2010) Bone: Bisphosphonate use and atypical femur fractures. Nature Reviews Endocrinology 6:8, 420-420
    CrossRef

83. 83

    Shane, Elizabeth, . (2010) Evolving Data about Subtrochanteric Fractures and Bisphosphonates. New England Journal of Medicine 362:19, 1825-1827
    Full Text

84. 84

    José Luis Pérez-Castrillón, Florentino Pinacho, Daniel De Luis, María Lopez-Menendez, Antonio Dueñas Laita. (2010) Odanacatib, a New Drug for the Treatment of Osteoporosis: Review of the Results in Postmenopausal Women. Journal of Osteoporosis 2010, 1-5
    CrossRef

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