AI Article Synopsis
- Thromboprophylaxis is important for preventing deep vein thrombosis after surgery, but anticoagulants like rivaroxaban can lead to systemic osteoporosis, impacting fracture healing.
- Rivaroxaban specifically inhibits factor Xa, which is crucial in blood clotting, and this study assesses its direct effects on osteoblastic cells from humans.
- Results showed that rivaroxaban significantly reduced DNA synthesis and energy metabolism in these cells, but it had a minor effect on alkaline phosphatase activity and did not hinder bone mineralization, suggesting it affects initial bone formation stages without interfering with later mineralization.
Article Abstract
Thromboprophylaxis reduces the risk of surgery-related deep vein thrombosis, but anticoagulants were associated with systemic osteoporosis, a known risk factor for poor fracture healing. Rivaroxaban (XARELTO(®)) is a novel anticoagulant with specific ability to inhibit factor Xa, a serine endopeptidase, which plays a key role in coagulation. This study investigated the direct effects of rivaroxaban on bone biology using an in vitro cell culture model from the human female osteoblastic cell line SaOS2. Cells at subconfluence were treated for 24 hr with different concentrations of rivaroxaban and analyzed for DNA synthesis and creatine kinase- and alkaline phosphatase-specific activities, and were treated 21 days for analyzing mineralization. Rivaroxaban (0.01-50 μg/ml) dose-dependently inhibited up to 60% DNA synthesis of the cells. Creatine kinase-specific activity was also inhibited dose-dependently to a similar extent by the same concentrations. Alkaline phosphatase-specific activity was dose-dependently inhibited but only up to 30%. Cell mineralization was unaffected by 10 μg/ml rivaroxaban. This model demonstrated a significant rivaroxaban-induced reduction in osteoblastic cell growth and energy metabolism, and slight inhibition of the osteoblastic marker, alkaline phosphatase, while osteoblastic mineralization was unaffected. These findings might indicate that rivaroxaban inhibits the first stage of bone formation but does not affect later stages (i.e., bone mineralization).
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| http://dx.doi.org/10.3109/03008207.2012.711867 | DOI Listing |
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