Abstract
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.
Highlights
Half of the 1.7 million new annual cancer diagnoses will be treated with ionizing radiation therapy (RT)
We found no increased risk of any toxicity from concurrent Stereotactic body radiation therapy (SBRT) and they were treated with lung SBRT
Bone is a radiosensitive structure that is often unavoidably included in standard
Summary
Half of the 1.7 million new annual cancer diagnoses will be treated with ionizing radiation therapy (RT). Stereotactic body radiation therapy (SBRT), for example, when used in the treatment of lung tumors near the chest wall, unavoidably delivers high doses of radiation to the ribs or vertebrae, and it can predispose patients to significant risks of radiation-induced rib fractures (RIRF), vertebral fractures, and chest wall pain (CWP) [4,5,6]. These toxicities have been correlated with the dose received by the chest wall. We will: (i) review the preclinical studies that helped elucidate the relationship between irradiation and bone injury, (ii) focus on how these data have been applied to develop approaches for addressing clinical research questions related to radiation-induced bone loss, and (iii) review how the most recent rodent studies have helped generate multiple therapeutic approaches
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