Abstract
Critical-sized bone defects are critical healing conditions that, if left untreated, often lead to non-unions. To reduce the risk, critical-sized bone defects are often treated with recombinant human BMP-2. Although enhanced bone tissue formation is observed when BMP-2 is administered locally to the defect, spatial and temporal distribution of callus tissue often differs from that found during regular bone healing or in defects treated differently. How this altered tissue patterning due to BMP-2 treatment is linked to mechano-biological principles at the cellular scale remains largely unknown. In this study, the mechano-biological regulation of BMP-2-treated critical-sized bone defect healing was investigated using a multiphysics multiscale in silico approach. Finite element and agent-based modeling techniques were combined to simulate healing within a critical-sized bone defect (5 mm) in a rat femur. Computer model predictions were compared to in vivo microCT data outcome of bone tissue patterning at 2, 4, and 6 weeks postoperation. In vivo, BMP-2 treatment led to complete healing through periosteal bone bridging already after 2 weeks postoperation. Computer model simulations showed that the BMP-2 specific tissue patterning can be explained by the migration of mesenchymal stromal cells to regions with a specific concentration of BMP-2 (chemotaxis). This study shows how computational modeling can help us to further understand the mechanisms behind treatment effects on compromised healing conditions as well as to optimize future treatment strategies.
Highlights
We investigated potential mechanisms behind bone tissue formation patterning during BMP-2-enhanced bone healing in a critical-sized bone defect using a mechanobiological computational model
– Low mechanical signals within the healing region predicted by finite element analysis of critical-sized bone defects resulted in delayed healing
– the computer model predicted healing of critical-sized defects under BMP-2 treatment when a collagen spongedriven BMP-2 release was implemented in the model;
Summary
1.1 Bone healingBone fracture healing is a regenerative process that starts autonomously when the injury occurs and it ends, if satisfactory, with a complete restoration of the original bone structure and functionality within weeks. Therapeutic strategies that involve the use of recombinant human bone morphogenetic protein 2 (rhBMP-2) have been shown to be a suitable alternative to autograft, with analog healing success rates and comparable reduced incidence of revision (Tressler et al 2011). From a clinical point of view, the use of BMP-2 treatment is leading to inconsistent results, suggesting that its mode of action is influenced by factors related to the surgical approach. Among these factors, fixation stability might play a large role since it has been shown that mechanics strongly influence the regulation of the growth factor effectiveness (Schmidt-Bleek et al 2016). Understanding the mechano-biological mechanisms behind BMP-2-supported bone regeneration will likely provide valuable insight into how treatment can be optimized to reduce adverse effects
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