Osteoporosis is characterised by trabecular bone loss resulting from increased osteoclast activation and unbalanced coupling between resorption and formation, which induces a thinning of trabeculae and trabecular perforations. Bisphosphonates are the frontline therapy for osteoporosis, which act by reducing bone remodelling, and are thought to prevent perforations and maintain microstructure. However, bisphosphonates may oversuppress remodelling resulting in accumulation of microcracks. This paper aims to investigate the effect of bisphosphonate treatment on microstructure and mechanical strength. Assessment of microdamage within the trabecular bone core was performed using synchrotron X-ray micro-CT linked to image analysis software. Bone from bisphosphonate-treated fracture patients exhibited fewer perforations but more numerous and larger microcracks than both fracture and non-fracture controls. Furthermore, bisphosphonate-treated bone demonstrated reduced tensile strength and Young’s Modulus. These findings suggest that bisphosphonate therapy is effective at reducing perforations but may also cause microcrack accumulation, leading to a loss of microstructural integrity and consequently, reduced mechanical strength.
Osteoporosis is a metabolic bone disorder affecting 200 million people worldwide, with a high prevalence in the ageing population1. Osteoporosis increases the risk of fragility fracture2,3,4,5,6, and is estimated to contribute to 8.9 million fractures annually7. Fractures, which commonly occur at the hip and spine8,9 result in disability, mortality and high healthcare costs, thereby placing a huge strain on the healthcare system10. The treatment of osteoporosis costs nearly $17 billion per year in the United States11 and €37 billion per year in the European Union12. With the rise in life expectancy, the incidence and cost of fragility fractures are projected to increase even further in the future.
Osteoporosis is characterised by a loss of bone mass and can be defined clinically using dual X-ray absorptiometry (DXA) as a T-score less than 2.5 standard deviations below the mean bone mineral density (BMD) in young adults13,14. Although osteoporosis causes bone to become fragile, studies have shown a poor correlation between osteoporosis, as defined by DXA, and the occurrence of fractures in the ageing population15,16. It is evident that more than half of these individuals who suffer from fractures do not meet the clinical diagnosis of osteoporosis17. These findings have led to the emergence of the concept of bone quality, which is now widely accepted as a key element in understanding bone fragility, in addition to bone mass18,19. Bone quality refers to the material and structural properties of bone that make it resistant to fracture including bone turnover, collagen and mineral matrix, microarchitecture and accumulated microdamage6. These factors are all thought to play a significant role in the development of fragility fractures20,21,22,23 and are therefore relevant for understanding the efficacy of treatment.
Bisphosphonates such as alendronate, risedronate and zoledronate are potent antiresorptive agents that form the first-line pharmacotherapy for the treatment of osteoporosis, with over 190 million prescriptions issued each year24,25. In osteoporosis, there is increased osteoclast activity leading to excessive thinning of trabeculae and the formation of perforations, which contributes to increased bone fragility26. Trabecular perforation is caused by osteoclasts resorbing a cavity so deep that it cannot be refilled by osteoblasts27. Consequently, there is loss of trabecular connectivity which is one of the key determinants of the mechanical strength of bone28. Bisphosphonates are known to inhibit osteoclasts and increase BMD, thereby conferring a reduction in fracture risk29,30,31,32. It has also been suggested that bisphosphonate-inhibition of osteoclasts will restrict the formation of perforations33. Studies have shown bisphosphonates to be capable of reducing bone turnover by up to 90%, which persists throughout the duration of treatment and may reduce the risk of hip fractures by between 30–50%34,35,36.
Over the past decade, concerns have been raised by clinicians and researchers regarding the oversuppresion of remodelling caused by long-term bisphosphonate therapy, which may predispose the patient to fractures37,38,39,40,41,42. Indeed, there have been reports of spontaneous non-vertebral fractures associated with a substantial reduction in bone turnover in patients on long-term bisphosphonate therapy43. It has been suggested that bisphosphonate treatment causes an oversuppression of remodeling, resulting in the accumulation of microdamage, which compromises the mechanical properties of bone43,44. This is evident in both animal and human studies, where concurrent bisphosphonate therapy is associated with microdamage45,46,47. Research on the micro- and nano-structure of bone have reported an inverse relationship between the amount of microdamage and the mechanical strength48,49,50. Recently, Zimmermann et al. found bisphosphonate-treated bone to have reduced tissue strength compared to healthy bone6. However, no studies in humans have directly correlated the microstructural changes following bisphosphonate therapy with the mechanical properties. Thus, the present study aims to investigate the effect of bisphosphonate therapy on trabecular microstructure, including perforations and microcracks, and correlate this with the mechanical strength of bone.
Materials and Methods
Trabecular bone samples were harvested from the femoral heads of three individual cohorts: a bisphosphonate-treated fracture group, an untreated fracture control group and a healthy ageing non-fracture control group. The fracture group samples were obtained from patients who underwent hip arthroplasty surgery for femoral neck fractures at Imperial College Healthcare National Health Service Trust in London, United Kingdom, while the non-fracture group samples were acquired from cadavers. All individuals with a history of primary bone disease or an underlying disorder such as cancer, which could lead to secondary bone disease were excluded from this study. The Imperial College Tissue Bank (R13004) granted ethical approval for the study and patients consented to the use of their tissue for research. All procedures performed in studies involving human participants were in accordance with the ethical standards of the institutional and/or national research committee and with the 1964 Helsinki Declaration and its later amendments or comparable ethical standards. A total of 21 samples were attained; eight from bisphosphonate-treated fracture patients (seven females; one male) (Table 1), eight from untreated fracture patients (seven females; one male) and five from cadavers of healthy ageing non-fracture individuals (four females; one male). The mean age of individuals was 79.3 ± 6.4 years in the bisphosphonate-treated group, 77.8 ± 3.4 years in the untreated fracture group and 77.8 ± 4.9 years in the healthy ageing non-fracture group. There was no significant difference present between the groups (One-Way ANOVA F = 0.5236, p = 0.644). Twenty-one cylindrical cores, 10 mm in height and 7 mm in diameter were taken from the region directly superior to the trabecular chiasma in the primary compressive trabecular arcade of the femoral heads. The cores were stored at −80 °C and only removed from storage for testing.
Synchrotron X-ray micro-CT Experiment
Due to the limited experiment time with the synchrotron, imaging was carried out on only 16 of the cylindrical cores (Fig. 1a). This was done with synchrotron X-ray micro-CT using Beamline I1251 at Diamond Light Source, United Kingdom. Six cores were from the bisphosphonate-treated group, five from the untreated fracture group and five from the healthy ageing non-fracture group. The key setting parameters used were: X-ray beam 53 KeV, image volume 23.3 mm3, voxel size 1.3 μm/voxel, 6400 projections, 180° rotation. Tomographic images were reconstructed using the in-house software, DAWN52,53 (Fig. 1b), which were linked to the image analysis software packages ImageJ (National Institutes of Health, Bethesda, United States of America) and VGStudio MAX (Heidelberg, Germany) for quantification of the trabecular microstructure (Fig. 1c,d).
Mechanical Uni-Axial Tensile Experiment
Twenty-one rectangular-shaped standard tensile testing samples were obtained from the region immediately adjacent to the harvest region of the aforementioned cylindrical cores. The specimens were 11 mm in height, 2.8 mm in width, and 1 mm depth. The ends of each sample were potted in bone cement, which served as clamps and stored at −80° C till testing. During tensile testing, the samples were kept hydrated in the fluid chamber built into the micromechanical device54. All 21 specimens underwent load-controlled tensile testing with a fixed strain rate at 0.001 s−1 using a custom-built micromechanical test rig, which was designed as part of earlier work54. The tests were conducted at room temperature. After loading, the stress-strain curves were examined to identify the Young’s Modulus and ultimate tensile strength, which were normalised according to trabecular bone volume. Tensile testing was considered more effective for assessing microcracks.
The features of microdamage visualised on synchrotron X-ray micro-CT scans were classified as either perforations27 or microcracks55,56. Perforations27 are regions of complete breakage in the bone trabeculae, which are due to osteoclastic activity (Fig. 2a,b). In contrast, microcracks55 are microscopic fractures with a typical linear shape and sharp edges ranging between 30–100 μm in length (Fig. 2c,d).
The volume analysed was 3.28 mm in diameter and 2.76 mm in height. This was done to avoid artefactual damage caused by the drilling process57. The region of interest was identified with an automated segmentation technique using a global threshold as described by Larrue et al.18. The scans were inspected to qualify and quantify the microdamage present in both 2D and 3D. In total, 1000 continuous slices were individually examined in three planes (Fig. 1c). Regions of microdamage were then segmented manually with localised threshold values for 3D assessment of volume as determined by the assessors who were blinded to the groups. To account for interindividual error when assessing microdamage, two independent assessors examined the CT slices (E.L.G. and B.P.). There was very high reproducibility, with an r2 value of 0.920 for the correlation between both assessors (Pearson’s correlation coefficient p = 0.010). Assessment of the scans was repeated three times by both assessors to minimise intraindividual error and data from the final assessment was used. In case of disagreement, a consensual decision between the two assessors was reached, with involvement of a third independent assessor (S.M.).
Trabecular bone volume fraction, microdamage density, microdamage volume, microdamage volume fraction, Young’s Modulus and ultimate tensile strength of the samples were calculated. Microdamage density and microdamage volume fraction were calculated as the frequency of microdamage and the volume of microdamage divided by the trabecular bone volume respectively. Microdamage density was used to compare the amount of microcracks and perforations across the non-fracture control, fracture control and bisphosphonate-treated groups. Meanwhile, microdamage volume was used to compare the size of microcracks and perforations across the three groups. The apparent mechanical data were divided by trabecular bone volume fraction to normalise the Young’s Modulus and ultimate tensile strength, which was to ensure a fair and valid comparison.
There were no relevant assumptions to construct a hypothesis for the effect size of long-term bisphosphonate treatment on microdamage accumulation in the femoral head trabecular bone cores in this study. Statistical analyses were performed using IBM SPSS Statistics 23 (Armonk, New York) and the graphs were generated with GraphPad Prism 7 (San Diego, California). The data were assessed for normality using a Q-Q plot and Shapiro-Wilk test, and were found to follow a non-Gaussian distribution. Consequently, the results were presented as median and interquartile range. Non-parametric descriptive statistics and tests used included the Kruskal-Wallis and Mann-Whitney U tests.
The fracture control group had the highest density of perforations across all groups (p = 0.040). This was significantly higher than the non-fracture group but was not significant compared to the bisphosphonate-treated group (Fig. 3a). Similarly, the fracture control group displayed the largest volume of perforations, followed by the bisphosphonate-treated and the non-fracture control group (p = 0.030). These differences were all statistically significant (Fig. 3c). The fracture group also had the highest perforation volume fraction, which was statistically significant compared to the other two groups (p = 0.0150) (Fig. 3e).
The bisphosphonate-treated group had the highest density of microcracks compared to the fracture and non-fracture control groups, which was statistically significant (p = 0.010) (Fig. 3b). Both the fracture and non-fracture control groups had a comparable density of microcracks. Moreover, the bisphosphonate-treated group had the largest volume of microcracks, followed by the fracture and non-fracture control groups (p = 0.001). This difference was significant compared to the non-fracture control group but not the fracture control group. The volume of microcracks in the bisphosphonate-treated group was also significantly greater compared to the non-fracture control group (p = 0.004) (Fig. 3d). Meanwhile, the bisphosphonate-treated group had the highest microcrack volume fraction compared to the fracture and non-fracture groups (p = 0.020) (Fig. 3f).
The trabecular bone volume fraction in the healthy aging non-fracture group was 0.344 ± 0.030. This was significantly higher than the untreated fracture group at 0.241 ± 0.025 (p = 0.001) but not compared to the bisphosphonate-treated fracture group at 0.288 ± 0.069. The overall stress-strain curves with the 95% confidence intervals across the three groups were generated (Fig. 4). Data for the apparent (Fig. 5a,b) and normalised (Fig. 5c,d) ultimate tensile strength and Young’s Modulus displayed a similar trend. The bone volume normalised ultimate tensile strength was the highest in the non-fracture group, followed by the fracture and bisphosphonate-treated groups. Statistically significant differences were present between all the groups (p = 0.001) (Fig. 5c). Additionally, the bisphosphonate therapy group showed a significantly lower normalised Young’s Modulus compared to the fracture and non-fracture groups (p = 0.030) (Fig. 5d).
This is the first study to investigate and compare the morphology of microdamage in healthy, osteoporotic and bisphosphonate-treated bone using synchrotron X-ray micro-CT and image segmentation technology. Trabecular microdamage and mechanical strength were compared across the three groups. Bone from the fracture control group exhibited the highest density of perforations across the three groups. Meanwhile, bone from the bisphosphonate-treated group demonstrated the highest density of microcracks. Microcracks were typically larger in bone from the bisphosphonate-treated group, while perforations were larger in bone from the fracture control group. Accordingly, the bisphosphonate-treated and fracture control groups had the highest microcrack and perforation volume fractions, respectively. Bone from the non-fracture control group had the highest normalised Young’s Modulus and tensile strength, followed by bone from the fracture control and bisphosphonate-treated groups.
A limitation of the study was the small sample size: 16 trabecular bone cores and 21 rectangular tensile samples were investigated. In addition, synchrotron X-ray micro-CT has the potential to cause radiation damage, which may lead to artefacts in the scans. To account for this, the energy settings were calibrated to be lower than 30–35 kGy (safe level) and the exposure time of the scan was kept under 30 seconds per frame58. Another limitation of the study was that the bones cores in the bisphosphonate-treated and fracture-control groups were harvested from femoral heads following hip fracture, which should be kept in mind when generalising the results. To do so, further studies of bone from patients treated with bisphosphonates without fracturing should be performed. Finally, the duration of bisphosphonate treatment was not controlled in this study. However, all samples were obtained from patients receiving treatment for a minimum of one year59.
In the present study, bone from the fracture control group exhibited the highest density and volume of perforations across all groups. Bone from healthy ageing individuals demonstrated a comparable density of microcracks with bone from fracture controls, although the volume of microcracks was significantly larger in the latter group. In healthy bone, sustained loading and fatigue caused by normal physical activity leads to microdamage formation, which results in a loss of mechanical integrity47. In order to maintain the mechanical integrity of bone, the remodelling process is targeted at sites of microdamage to initiate repair55,60. In osteoporosis, osteoclast activity is markedly elevated, which explains the high density and volume of perforations observed in this study61. Thus, the reduction in the normalised Young’s Modulus and ultimate tensile strength of untreated fracture bone compared to healthy bone can be attributed to a loss of structural integrity caused by perforations. Given that more than half of patients suffering from fragility fractures do not fit a DXA-based clinical diagnosis of osteoporosis15,16, these findings suggest that osteoporosis may not solely be a disorder characterised by loss of bone mass, but also the disruption of bone microstructure17 due to perforations.
Bisphosphonate-treated bone from fracture patients had the highest density and volume of microcracks compared to bone from the untreated fracture patients and healthy ageing individuals. Correspondingly, bisphosphonate-treated samples also had reduced ultimate tensile strength and Young’s Modulus compared to the control groups. Our results, therefore, suggest that the reduced bone strength in the bisphosphonate group is due to the accumulation of microcracks. In this subgroup of bisphosphonate-treated patients that suffered a fracture, the accumulation of microcracks following treatment with bisphosphonates may have compromised the trabecular microstructure. As a result, there may have been weakening of the bone and consequently, an increased risk of fracture. Bisphosphonate-treated bone also demonstrated a lower density and volume of perforations compared to osteoporotic bone, which may be reflective of the protective effects of bisphosphonates in limiting the development of perforations through osteoclastic inhibition27. However, it is the oversuppression of remodelling that has detrimental effects, as this predisposes to microcrack accumulation and propagation43.
Bone from healthy ageing individuals demonstrated a comparable density of microcracks with bone from fracture patients although the volume was substantially lower. The accumulation of microcracks can potentially weaken bone and reduce tensile strength but microcracks are a part of normal physiological toughening mechanisms2,49,62. Bone is a hierarchical structure with energy-dissipating mechanisms at each level63. At the microstructural level, the formation of small microcracks can be an effective strategy for dissipating energy. Healthy bone has mechanisms to sustain microcrack accumulation, by limiting propagation and inducing an appropriate remodelling response to initiate repair. The toughness of bone is therefore maintained through the balance between the protective effects conferred by the fracture toughening mechanisms in bone and the formation of microcracks64. Disruption of this balance leads to a loss of heterogeneity of the trabecular composition, which is strongly correlated with a reduction in fracture toughness35,65,66. Thus, the dysregulation of the remodelling process that occurs in osteoporosis and with bisphosphonate therapy predisposes to the formation and propagation of microcracks, which may occur through cracking of bone mineral crystallites, debonding at the mineral organic interface or shear between and within collagen fibrils67.
Consistent with the findings of the present study, Zimmermann et al. noted that cortical bone samples from osteoporotic and bisphosphonate-treated individuals displayed reduced bending modulus, yield stress and maximum bending stress compared to healthy adults6. Similarly, Lambers et al. reported an inverse relationship between bone microdamage volume fraction and Young’s Modulus caused by fatigue loading. Additionally, the authors observed that samples with microdamage were able to withstand 92% fewer cycles before failure compared to the same tissue without microdamage in their study49. These findings suggest that even small quantities of microdamage can have a significant effect on the biomechanical performance of bone. Using nanoindentation techniques, Wang et al. noted a reduction in bone stiffness and elasticity following the formation of microdamage, which was maintained even after repair had occurred68. Our findings corroborate and build on previous analyses by establishing the differences in microdamage in healthy ageing, diseased and treated bone and correlating these with the mechanical properties.
In humans, there is limited evidence regarding the effects of long-term (>5 years) bisphosphonate therapy and microcrack accumulation. Clinical trials report a reduction in fracture risk but data available is limited to the duration of the trials, which typically last between 3–4 years29,30,69,70. This is very important clinically, as patients with osteoporosis are usually placed on treatment lasting more than five years. A recent nested case-control study by Erviti et al., who followed a cohort of 12054 individuals, reported patients on bisphosphonate therapy for longer than 3 years to be at significantly elevated risk of hip fracture compared to the control group. Furthermore, fracture risk was found to be independently associated with the duration of treatment71. Thus, the occurrence of hip fractures in bisphosphonate-treated patients may not be due to the inefficacy of the drug but rather a consequence of its effectiveness. Pooled analysis of three long-term extension trials on alendronate, risedronate and zoledronate revealed marginally lower hip fracture rates in patients switching to the placebo compared to those persisting with treatment72. The BMD in the femoral neck of patients who persisted with treatment was maintained but declined in those that had switched to the placebo. Given these findings, it is unlikely that these differences in risk can be reliably attributed to BMD. The increased incidence of fractures noted in these studies may be due to the accumulation of microcracks in the femoral neck, which can impair the mechanical properties of the bone, thereby predisposing to fracture. Moving forwards, our findings will form the groundwork for studies investigating the structure of bone at a micro- and nanostructural level, which will provide us with a more complete picture.
In this study, bone from bisphosphonate-treated fracture patients exhibited fewer perforated trabeculae compared to bone from untreated fracture patients, which suggests successful suppression of the remodelling process. However, more microcracks were present, which were larger in volume compared to untreated fracture and healthy ageing non-fracture controls. Given the reduced mechanical strength noted in the bone samples from the bisphosphonate-treated group, these microstructural changes may explain the mechanism by which fractures occur in patients treated with bisphosphonates. Thus, it is plausible that there may be a population of patients in whom bisphosphonate therapy does not confer protective effects in resisting fractures, but is associated with microstructural damage and increased bone fragility instead. For patients on long-term therapy, if this microcrack accumulation critical time-point could be predicted, bisphosphonate treatment duration could be optimised. Bisphosphonates could be prescribed for long enough to increase bone volume and reduce perforations, whilst stopping the medication before a critical accumulation of microcracks. Whilst it may be premature to rethink current fracture prevention strategy, caution should be exercised when prescribing bisphosphonates to all patients deemed at risk of fracture and the duration of treatment should be carefully considered.
How to cite this article: Ma, S. et al. Long-term effects of bisphosphonate therapy: perforations, microcracks and mechanical properties. Sci. Rep. 7, 43399; doi: 10.1038/srep43399 (2017).
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Kanis, J. A. Assessment of osteoporosis at the primary health-care level. Technical Report (2007).
Zimmermann, E. A. et al. Age-related changes in the plasticity and toughness of human cortical bone at multiple length scales. Proceedings of the National Academy of Sciences 108, 14416–14421 (2011).
Busse, B. et al. Vitamin D Deficiency Induces Early Signs of Aging in Human Bone, Increasing the Risk of Fracture. Science Translational Medicine 5, 193ra88–193ra88 (2013).
Carriero, A. et al. How Tough Is Brittle Bone? Investigating Osteogenesis Imperfecta in Mouse Bone. Journal of Bone and Mineral Research 29, 1392–1401 (2014).
Zimmermann, E. A. et al. Modifications to Nano- and Microstructural Quality and the Effects on Mechanical Integrity in Paget’s Disease of Bone. Journal of Bone and Mineral Research 30, 264–273 (2015).
Zimmermann, E. A. et al. Intrinsic mechanical behavior of femoral cortical bone in young, osteoporotic and bisphosphonate-treated individuals in low- and high energy fracture conditions. Scientific Reports 6, 21072 (2016).
Johnell, O. & Kanis, J. A. An estimate of the worldwide prevalence and disability associated with osteoporotic fractures. Osteoporosis Int 17, 1726–1733 (2006).
Seeley, D. G. et al. Which Fractures Are Associated with Low Appendicular Bone Mass in Elderly Women? Ann. Intern. Med. 115, 837–842 (1991).
Ngugyen, T. V., Eisman, J. A., Kelly, P. J. & Sambroak, P. N. Risk Factors for Osteoporotic Fractures in Elderly Men. American Journal of Epidemiology 144, 255–263 (1996).
Hernlund, E. et al. Osteoporosis in the European Union: medical management, epidemiology and economic burden: A report prepared in collaboration with the International Osteoporosis Foundation (IOF) and the European Federation of Pharmaceutical Industry Associations (EFPIA). Archives of Osteoporosis 8, 136 (2013).
Burge, R. et al. Incidence and economic burden of osteoporosis‐related fractures in the United States, 2005–2025. Journal of bone and mineral research 22, 465–475 (2007).
Svedbom, A. et al. Osteoporosis in the European Union: a compendium of country-specific reports. Archives of osteoporosis 8, 1–218 (2013).
Melton, L. J. & Wahner, H. W. Defining osteoporosis. Calcif. Tissue Int. 45, 263–264 (1989).
Bouillon, R. et al. Consensus development conference: prophylaxis and treatment of osteoporosis. Am. J. Med. 90, 107–110 (1991).
Burr, D. B. et al. Bone Microdamage and Skeletal Fragility in Osteoporotic and Stress Fractures. Journal of Bone and Mineral Research 12, 6–15 (1997).
Siris, E. S. et al. Bone mineral density thresholds for pharmacological intervention to prevent fractures. Arch. Intern. Med. 164, 1108–1112 (2004).
Sanders, K. M. et al. Half the burden of fragility fractures in the community occur in women without osteoporosis. When is fracture prevention cost-effective? Bone 38, 694–700 (2006).
Larrue, A., Rattner, A., Peter, Z.-A., Olivier, C., Laroche, N., Vico, L. & Peyrin, F. Synchrotron Radiation Micro-CT at the Micrometer Scale for the Analysis of the Three-Dimensional Morphology of Microcracks in Human Trabecular Bone. PLoS ONE 6, 1–12 (2011).
Seeman, E. & Delmas, P. D. Bone Quality - The Material and Structural Basis of Bone Strength and Fragility. N. Engl. J. Med. 354, 2250–2261 (2006).
Kanis, J. A. Diagnosis of osteoporosis and assessment of fracture risk. The Lancet 359, 1929–1936 (2002).
Elliot-Gibson, V., Bogoch, E. R., Jamal, S. A. & Beaton, D. E. Practice patterns in the diagnosis and treatment of osteoporosis after a fragility fracture: a systematic review. Osteoporosis Int. 15, 767–778 (2004).
Center, J. R., Bliuc, D., Nguyen, T. V. & Eisman, J. A. RIsk of subsequent fracture after low-trauma fracture in men and women. JAMA 297, 387–394 (2007).
Greenspan, S. L. et al. Predictors of Treatment with Osteoporosis Medications After Recent Fragility Fractures in a Multinational Cohort of Postmenopausal Women. J. Am. Geriatr. Soc. 60, 455–461 (2012).
Advisory Task Force on Bisphosphonate-Related Ostenonecrosis of the Jaws. American Association of Oral and Maxillofacial Surgeons Position Paper on Bisphosphonate-Related Osteonecrosis of the Jaws. Journal of Oral and Maxillofacial Surgery 65, 369–376 (2007).
Huang, Y. F. et al. Impact of Bisphosphonate-related Osteonecrosis of the Jaw on Osteoporotic Patients after Dental Extraction: A Population-Based Cohort Study. PLoS ONE 10, e0120756 (2015).
Thürlimann, B. In Bisphosphonates in Clinical Oncology: The Development of Pamidronate (Springer Science & Business Media, 2012).
McNamara, L. M. & Prendergast, P. J. Perforation of cancellous bone trabeculae by damage-stimulated remodelling at resorption pits: a computational analysis. Eur. J. Morphol. 42, 99 (2005).
Boivin, G. & Meunier, P. Effects of bisphosphonates on matrix mineralization. Journal of Musculoskeletal and Neuronal Interactions 2, 538–543 (2002).
Liberman, U. A. et al. Effect of Oral Alendronate on Bone Mineral Density and the Incidence of Fractures in Postmenopausal Osteoporosis. N. Engl. J. Med. 333, 1437–1444 (1995).
Black, D. M. et al. Randomised trial of effect of alendronate on risk of fracture in women with existing vertebral fractures. The Lancet 348, 1535–1541 (1996).
Li, J., Mashiba, T. & Burr, D. B. Bisphosphonate Treatment Suppresses Not Only Stochastic Remodeling but Also the Targeted Repair of Microdamage. Calcif. Tissue Int. 69, 281–286 (2001).
McClung, M. R. et al. Effect of Risedronate on the Risk of Hip Fracture in Elderly Women. N. Engl. J. Med. 344, 333–340 (2001).
Ott, S. M. Long-term safety of bisphosphonates. The Journal of Clinical Endocrinology & Metabolism 90, 1897–1899 (2005).
Chavassieux, P. M. et al. Histomorphometric assessment of the long-term effects of alendronate on bone quality and remodeling in patients with osteoporosis. J. Clin. Invest. 100, 1475–1480 (1997).
Boivin, G. Y., Chavassieux, P. M., Santora, A. C., Yates, J. & Meunier, P. J. Alendronate increases bone strength by increasing the mean degree of mineralization of bone tissue in osteoporotic women. Bone 27, 687–694 (2000).
Bone, H. G. et al. Ten Years’ Experience with Alendronate for Osteoporosis in Postmenopausal Women. N. Engl. J. Med. 350, 1189–1199 (2004).
Neviaser, A. S., Lane, J. M., Lenart, B. A., Edobor-Osula, F. & Lorich, D. G. Low-energy femoral shaft fractures associated with alendronate use. Orthop Trauma J 22, 346–350 (2008).
Kwek, E. B. K., Goh, S. K., Koh, J. S. B., Png, M. A. & Howe, T. S. An emerging pattern of subtrochanteric stress fractures: A long-term complication of alendronate therapy? Injury 39, 224–231 (2008).
Lenart, B. A. et al. Association of low-energy femoral fractures with prolonged bisphosphonate use: a case control study. Osteoporosis international: a journal established as result of cooperation between the European Foundation for Osteoporosis and the National Osteoporosis Foundation of the USA 20, 1353–1362 (2008).
Shane, E. et al. 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, 2267–2294 (2010).
El Rachkidi, R. M., Sari-Leret, M. M. & Wolff, S. M. Atypical Bilateral Pedicle Fracture in Long-Term Bisphosphonate Therapy. Spine 36, 1769–1773 (2011 December).
Shane, E. et al. Atypical Subtrochanteric and Diaphyseal Femoral Fractures: Second Report of a Task Force of the American Society for Bone and Mineral Research. Journal of Bone and Mineral Research 29, 1–23 (2014).
Odvina, C. V. et al. Severely Suppressed Bone Turnover: A Potential Complication of Alendronate Therapy. The Journal of Clinical Endocrinology & Metabolism 90, 1294–1301 (2005).
Odvina, C. V., Levy, S., Rao, S., Zerwekh, J. E. & Rao, D. S. Unusual mid‐shaft fractures during long‐term bisphosphonate therapy. Clin. Endocrinol. (Oxf) 72, 161–168 (2010).
Mashiba, T. et al. Suppressed Bone Turnover by Bisphosphonates Increases Microdamage Accumulation and Reduces Some Biomechanical Properties in Dog Rib. Journal of Bone and Mineral Research 15, 613–620 (2000).
Stepan, J. J. et al. Low bone mineral density is associated with bone microdamage accumulation in postmenopausal women with osteoporosis. Bone 41, 378–385 (2007).
Chapurlat, R. D. et al. Microcrack Frequency and Bone Remodeling in Postmenopausal Osteoporotic Women on Long‐Term Bisphosphonates: A Bone Biopsy Study. Journal of Bone and Mineral Research 22, 1502–1509 (2007).
Burr, D. B. et al. Does microdamage accumulation affect the mechanical properties of bone? J. Biomech. 31, 337–345 (1998).
Lambers, F. M., Bouman, A. R., Rimnac, C. M. & Hernandez, C. J. Microdamage caused by fatigue loading in human cancellous bone: relationship to reductions in bone biomechanical performance. PLoS One 8, e83662 (2013).
Brock, G. R. et al. Nanoscale examination of microdamage in sheep cortical bone using synchrotron radiation transmission x-ray microscopy. PloS one 8, e57942 (2013).
Drakopoulos, M. et al. I12: the Joint Engineering, Environment and Processing (JEEP) beamline at Diamond Light Source. Journal of Synchrotron Radiation 22, 828–838 (2015).
Titarenko, V., Bradley, R., Martin, C., Withers, P. J. & Titarenko, S. Regularization methods for inverse problems in X-ray tomography (SPIE Optical Engineering Applications, International Society for Optics and Photonics, 2010).
Basham, M. et al. Data Analysis WorkbeNch (DAWN). Journal of synchrotron radiation 22, 853–858 (2015).
Karunaratne, A. et al. Significant deterioration in nanomechanical quality occurs through incomplete extrafibrillar mineralization in rachitic bone: Evidence from in-situ synchrotron X-ray scattering and backscattered electron imaging. Journal of Bone and Mineral Research 27, 876–890 (2012).
Frost, H. M. Measurement of osteocytes per unit volume and volume components of osteocytes and canaliculae in man. Henry Ford Hosp. Med. Bull. 8, 208–211 (1960).
Donahue, S. W., Sharkey, N. A., Modanlou, K. A., Sequeira, L. N. & Martin, R. B. Bone strain and microcracks at stress fracture sites in human metatarsals. Bone 27, 827–833 (2000).
Ma, S. et al. Synchrotron Imaging Assessment of Bone Quality. Clinical Reviews in Bone and Mineral Metabolism, 1–11 (2016).
Barth, H. D. et al. Characterization of the effects of x-ray irradiation on the hierarchical structure and mechanical properties of human cortical bone. Biomaterials 32, 8892–8904 (2011).
O’Neal, J. M. et al. One year of alendronate treatment lowers microstructural stresses associated with trabecular microdamage initiation. Bone 47, 241–247 (2010).
Schaffler, M. Role of bone turnover in microdamage. Osteoporosis Int. 14, 73–80 (2003).
Garnero, P., Sornay‐Rendu, E., Chapuy, M. & Delmas, P. D. Increased bone turnover in late postmenopausal women is a major determinant of osteoporosis. Journal of Bone and Mineral Research 11, 337–349 (1996).
Akkus, O. & Rimnac, C. M. Cortical bone tissue resists fatigue fracture by deceleration and arrest of microcrack growth. J. Biomech. 34, 757–764 (2001).
Vashishth, D. Hierarchy of bone microdamage at multiple length scales. Int. J. Fatigue 29, 1024–1033 (2007).
Seref-Ferlengez, Z., Kennedy, O. D. & Schaffler, M. B. Bone microdamage, remodeling and bone fragility: how much damage is too much damage. BoneKEy Rep 4 (2015).
Roschger, P. et al. Alendronate increases degree and uniformity of mineralization in cancellous bone and decreases the porosity in cortical bone of osteoporotic women. Bone 29, 185–191 (2001).
Gourion-Arsiquaud, S. et al. Bisphosphonate treatment modifies canine bone mineral and matrix properties and their heterogeneity. Bone 46, 666–672 (2010).
Mohsin, S., O’Brien, F. & Lee, T. Microcracks in compact bone: a three‐dimensional view. J. Anat. 209, 119–124 (2006).
Wang, G., Qu, X. & Yu, Z. Changes in the mechanical properties and composition of bone during microdamage repair. PloS one 9, e108324 (2014).
Lyles, K. W. et al. Zoledronic acid and clinical fractures and mortality after hip fracture. N. Engl. J. Med. 357, 1799–1809 (2007).
Black, D. M. et al. Once-Yearly Zoledronic Acid for Treatment of Postmenopausal Osteoporosis. N. Engl. J. Med. 356, 1809–1822 (2007).
Erviti, J., Alonso, Á., Gorricho, J. & López, A. Oral bisphosphonates may not decrease hip fracture risk in elderly Spanish women: a nested case–control study. BMJ Open 3 (2013).
Whitaker, M., Guo, J., Kehoe, T. & Benson, G. Bisphosphonates for osteoporosis—where do we go from here? N. Engl. J. Med. 366, 2048–2051 (2012).
We wish to thank the direct care teams at St Mary’s Hospital for consenting patients and collecting tissue samples. The authors would also like to thank the patients who agreed to donate tissue for research and the Imperial College Healthcare National Health Service (NHS) staff and Imperial Tissue Bank staff who helped with the collection of the samples. The research was funded by the Wellcome Trust and Engineering and Physical Sciences Research Council (EPSRC) Osteoarthritis Centre of Excellence (088844/Z/09/Z), the Michael Uren Foundation and the Science and Technology Facilities Council (STFC) Impact Acceleration Grant. The Diamond Light Source funded beam time allocations (EE0852, EE9811, SM10458, EE11204, SM13337). The authors are very grateful for the help of the Diamond Light Source staff at Harwell, UK.
The authors declare no competing financial interests.
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Ma, S., Goh, E., Jin, A. et al. Long-term effects of bisphosphonate therapy: perforations, microcracks and mechanical properties. Sci Rep 7, 43399 (2017). https://doi.org/10.1038/srep43399
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