Parathyroid Hormone (1–34) Transiently Protects Against Radiation-Induced Bone Fragility

Oest, Megan E.; Mann, Kenneth A.; Zimmerman, Nicholas D.; Damron, Timothy A.

doi:10.1007/s00223-016-0111-0

Cited by 16 publications

(19 citation statements)

References 45 publications

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“…Using a mouse model of unilateral hindlimb limited field radiotherapy, we have previously demonstrated that therapeutic radiation results in loss of femoral metaphyseal trabecular structures (decreased trabecular bone volume fraction, decreased trabecular number, decreased connectivity density, and increased trabecular spacing) subsequent to increased osteoclastic activity, diminished bone strength (axial compression testing of distal femur, femoral diaphyseal bending strength), and decreased femoral diaphyseal fracture toughness without loss of bone density. [11][12][13][14] Work in other labs has supported these findings. [15][16][17] Furthermore, we have shown that the bone matrix (organic and collagen phases) becomes increasingly aligned post-RTx, accompanied by an increase in trivalent:divalent collagen crosslink ratio as measured by Raman spectroscopy, with only small transient changes in pathologic crosslinks and adducts such as advanced glycation end products (AGEs).…”

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confidence: 59%

Altered mechanical behavior of demineralized bone following therapeutic radiation

Bartlow

Mann

Damron

et al. 2020

Journal Orthopaedic Research

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Post-radiotherapy (RTx) bone fragility fractures are a late-onset complication occurring in bone within or underlying the radiation field. These fractures are difficult to predict, as patients do not present with local osteopenia. Using a murine hindlimb RTx model, we previously documented decreased mineralized bone strength and fracture toughness, but alterations in material properties of the organic bone matrix are largely unknown. In this study, 4 days of fractionated hindlimb irradiation (4 × 5 Gy) or Sham irradiation was administered in a mouse model (BALB/cJ, end points: 0, 4, 8, and 12 weeks, n = 15/group/end point). Following demineralization, the viscoelastic stress relaxation, and monotonic tensile mechanical properties of tibiae were determined. Irradiated tibiae demonstrated an immediate (day after last radiation fraction) and sustained (4, 8, 12 weeks) increase in stress relaxation compared to the Sham group, with a 4.4% decrease in equilibrium stress (p < .017). While tensile strength was not different between groups, irradiated tibiae had a lower elastic modulus (−5%, p = .027) and energy to failure (−12.2%, p = .012) with monotonic loading. Gel electrophoresis showed that therapeutic irradiation (4 × 5 Gy) does not result in collagen fragmentation, while irradiation at a common sterilization dose (25 kGy) extensively fragmented collagen. These results suggest that altered collagen mechanical behavior has a role in postirradiation bone fragility, but this can occur without detectable collagen fragmentation. Statement of Clinical Significance: Therapeutic irradiation alters bone organic matrix mechanics and which contribute to diminished fatigue strength, but this does not occur via collagen fragmentation. K E Y W O R D S bone biomechanics, demineralized bone, radiation therapy 1 | INTRODUCTION Radiation therapy (RTx) is a valuable clinical tool for management of cancers and metastatic bone pain. However, RTx is associated with increased risk for late-onset fragility fractures in bones within or underlying the irradiated tissue volume. Incidence of these fragility fractures varies by cancer type and treatment location, but may exceed 33% in some patient populations. 1-8 These fragility fractures are characterized by loss of trabecular bone, an abnormal transverse fracture pattern, and little-to-no decrease in bone density. 9,10 Collectively, these data indicate that postradiotherapy fragility fractures do not occur as a result of osteopenia, but rather embrittlement of the bone tissue.

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confidence: 59%

Altered mechanical behavior of demineralized bone following therapeutic radiation

Bartlow

Mann

Damron

et al. 2020

Journal Orthopaedic Research

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“…Work in mouse models (total body and limited field RTx) consistently demonstrates an early increase in osteoclast numbers at 1 to 2 weeks post‐RTx, followed by long‐term depletion of osteoclasts . This results in early loss of trabecular bone and persistence of highly cross‐linked, highly aligned bone matrix due to loss of remodeling activity . At this point, it is unknown whether loss of local osteoclasts after limited field irradiation is because of 1) the absence of osteoclast progenitor cells, or 2) an inability of osteoclast precursors to multinucleate, differentiate, or adhere.…”

Section: Discussionmentioning

confidence: 99%

“…(9,10) This results in early loss of trabecular bone and persistence of highly cross-linked, highly aligned bone matrix due to loss of remodeling activity. (16,17,21,33) At this point, it is unknown whether loss of local osteoclasts after limited field irradiation is because of 1) the absence of osteoclast progenitor cells, or 2) an inability of osteoclast precursors to multinucleate, differentiate, or adhere. Using this mouse model, we have previously shown that mineral apposition rate is not decreased post-RTx.…”

Section: Discussionmentioning

confidence: 99%

Longitudinal Effects of Single Hindlimb Radiation Therapy on Bone Strength and Morphology at Local and Contralateral Sites

Oest

Policastro

Mann

et al. 2017

Journal of Bone and Mineral Research

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Radiation therapy (RTx) is associated with increased risk for late-onset fragility fractures in bone tissue underlying the radiation field. Bone tissue outside the RTx field is often selected as a "normal" comparator tissue in clinical assessment of fragility fracture risk, but the robustness of this comparison is limited by an incomplete understanding of the systemic effects of local radiotherapy. In this study, a mouse model of limited field irradiation was used to quantify longitudinal changes in local (irradiated) and systemic (non-irradiated) femurs with respect to bone density, morphology, and strength. BALB/cJ mice aged 12 weeks underwent unilateral hindlimb irradiation (4 Â 5 Gy) or a sham procedure. Femurs were collected at endpoints of 4 days before treatment and at 0, 1, 2, 4, 8, 12, and 26 weeks post-treatment. Irradiated (RTx), Contralateral (non-RTx), and Sham (non-RTx) femurs were imaged by microcomputed tomography and mechanically tested in three-point bending. In both the RTx and Contralateral non-RTx groups, the longer-term (12-to 26-week) outcomes included trabecular resorption, loss of diaphyseal cortical bone, and decreased bending strength. Contralateral femurs generally followed an intermediate response compared with RTx femurs. Change also varied by anatomic compartment; post-RTx loss of trabecular bone was more profound in the metaphyseal than the epiphyseal compartment, and cortical bone thickness decreased at the mid-diaphysis but increased at the metaphysis. These data demonstrate that changes in bone quantity, density, and architecture occur both locally and systemically after limited field irradiation and vary by anatomic compartment. Furthermore, the severity and persistence of systemic bone damage after limited field irradiation suggest selection of control tissues for assessment of fracture risk or changes in bone density after radiotherapy may be challenging.

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“…Based on its use in severely osteoporotic patients, intermittent administration of parathyroid hormone may be a useful drug to decrease bone loss and reduce the risk of fracture. The use of PTH has been investigated in a series of studies by Oest and colleagues [51,75]. In the first, they investigated the impact of PTH on bone fragility in a mouse hind limb model.…”

Section: Pth and Blocking Sclerostinmentioning

confidence: 99%

Bench to Bedside: Animal Models of Radiation Induced Musculoskeletal Toxicity

Farris

Helis

Hughes

et al. 2020

Cancers

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Ionizing radiation is a critical aspect of current cancer therapy. While classically mature bone was thought to be relatively radio-resistant, more recent data have shown this to not be the case. Radiation therapy (RT)-induced bone loss leading to fracture is a source of substantial morbidity. The mechanisms of RT likely involve multiple pathways, including changes in angiogenesis and bone vasculature, osteoblast damage/suppression, and increased osteoclast activity. The majority of bone loss appears to occur rapidly after exposure to ionizing RT, with significant changes in cortical thickness being detectable on computed tomography (CT) within three to four months. Additionally, there is a dose–response relationship. Cortical thinning is especially notable in areas of bone that receive >40 gray (Gy). Methods to mitigate toxicity due to RT-induced bone loss is an area of active investigation. There is an accruing clinical trial investigating the use of risderonate, a bisphosphonate, to prevent rib bone loss in patients undergoing lung stereotactic body radiation therapy (SBRT). Additionally, several other promising therapeutic/preventative approaches are being explored in preclinical studies, including parathyroid hormone (PTH), amifostine, and mechanical loading of irradiated bones.

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Parathyroid Hormone (1–34) Transiently Protects Against Radiation-Induced Bone Fragility

Cited by 16 publications

References 45 publications

Altered mechanical behavior of demineralized bone following therapeutic radiation

Altered mechanical behavior of demineralized bone following therapeutic radiation

Longitudinal Effects of Single Hindlimb Radiation Therapy on Bone Strength and Morphology at Local and Contralateral Sites

Bench to Bedside: Animal Models of Radiation Induced Musculoskeletal Toxicity

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