Regulatory inhibition of biological tissue mineralization by calcium phosphate through post-nucleation shielding by fetuin-A
Document Type
Article
Publication Date
4-21-2016
Abstract
In vertebrates, insufficient availability of calcium and inorganic phosphate ions in extracellular fluids leads to loss of bone density and neuronal hyper-excitability. To counteract this problem, calcium ions are usually present at high concentrations throughout bodily fluids - at concentrations exceeding the saturation point. This condition leads to the opposite situation where unwanted mineral sedimentation may occur. Remarkably, ectopic or out-of-place sedimentation into soft tissues is rare, in spite of the thermodynamic driving factors. This fortunate fact is due to the presence of auto-regulatory proteins that are found in abundance in bodily fluids. Yet, many important inflammatory disorders such as atherosclerosis and osteoarthritis are associated with this undesired calcification. Hence, it is important to gain an understanding of the regulatory process and the conditions under which it can go awry. In this manuscript, we extend mean-field continuum classical nucleation theory of the growth of clusters to encompass surface shielding. We use this formulation to study the regulation of sedimentation of calcium phosphate salts in biological tissues through the mechanism of post-nuclear shielding of nascent mineral particles by binding proteins. We develop a mathematical description of this phenomenon using a countable system of hyperbolic partial differential equations. A critical concentration of regulatory protein is identified as a function of the physical parameters that describe the system.
Identifier
84966393641 (Scopus)
Publication Title
Journal of Chemical Physics
External Full Text Location
https://doi.org/10.1063/1.4946002
ISSN
00219606
PubMed ID
27389239
Issue
15
Volume
144
Grant
DMS-1021818
Fund Ref
National Institutes of Health
Recommended Citation
Chang, Joshua C. and Miura, Robert M., "Regulatory inhibition of biological tissue mineralization by calcium phosphate through post-nucleation shielding by fetuin-A" (2016). Faculty Publications. 10574.
https://digitalcommons.njit.edu/fac_pubs/10574
