Abstract
Bone multicellular units (BMUs) maintain the viability of the skeletal tissue by coordinating locally the sequence of bone resorption and bone formation performed by cells of the osteoclastic and osteoblastic lineage. Understanding the emergence and the net bone balance of such structured microsystems out of the complex network of biochemical interactions between bone cells is fundamental for many bone-related diseases and the evaluation of fracture risk. Based on current experimental knowledge, we propose a spatio-temporal continuum model describing the interactions of osteoblastic and osteoclastic cells. We show that this model admits travelling-wave-like solutions with well-confined cell profiles upon specifying external conditions mimicking the environment encountered in cortical bone remodelling. The shapes of the various cell concentration profiles within this travelling structure are intrinsically linked to the parameters of the model such as differentiation, proliferation, and apoptosis rates of bone cells. The internal structure of BMUs is reproduced, allowing for experimental calibration. The spatial distribution of the key regulatory factors can also be exhibited, which in diseased states could give hints as to the biochemical agent most accountable for the disorder.
Highlights
The physiological process by which our bones are continuously renewed throughout our lifetime is commonly referred to as “bone remodelling” [1]
We present below a detailed spatio-temporal continuum model focusing on a single cortical bmu, extended from the cell-population model proposed by Pivonka et al [10]
Concluding Remarks We have developed a continuum spatio-temporal mathematical model to study cell profiles in a cortical bmu
Summary
Theoretical analysis of the spatio-temporal structure of bone multicellular units. This content has been downloaded from IOPscience. 10 012132 (http://iopscience.iop.org/1757-899X/10/1/012132) View the table of contents for this issue, or go to the journal homepage for more. Download details: IP Address: 134.115.74.65 This content was downloaded on 11/11/2016 at 03:33. You may be interested in: Force-induced bone growth and adaptation: A system theoretical approach to understanding bone mechanotransduction Solvey Maldonado and Rolf Findeisen Radiation dose to trabecular bone marrow stem cells Huiling Nie and Richard B Richardson Monte Carlo simulation of age-dependent radiation dose from alpha- and beta-emitting radionuclides to critical trabecular bone and bone marrow targets James T Dant, Richard B Richardson and Linda H Nie Osteogenic gene expression of murine osteoblastic (MC3T3-E1) cells under cyclic tension C T Kao, C C Chen, U-I Cheong et al Inter-dependent tissue growth and Turing patterning in a model for long bone development Simon Tanaka and Dagmar Iber Investigation of nutrient transport mechanisms in the lacunae-canaliculi system S Scheiner, A Théoval, P Pivonka et al
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