Biphasic calcium phosphate (BCP) is used as a bone substitute
and
bone tissue repair material due to its better control over bioactivity
and biodegradability. It is crucial to stabilize the implanted biomaterial
while promoting bone ingrowth. However, a lack of standard experimental
and theoretical protocols to characterize the physicochemical properties
of BCP limits the optimization of its composition and properties.
Computational simulations can help us better to learn BCP at a nanoscale
level. Here, the Voronoi tessellation method was combined with simulated
annealing molecular dynamics to construct BCP nanoparticle models
of different sizes, which were used to understand the physicochemical
properties of BCP (e.g., melting point, infrared spectrum, and mechanical
properties). We observed a ∼20 to 30 Å layer of calcium-deficient
hydroxyapatite at the HAP/β-TCP interface due to particle migration,
which may contribute to BCP stability. The BCP model may stimulate
further research into BCP ceramics and multiphasic ceramics. Moreover,
our study may facilitate the optimization of compositions of BCP-based
biomaterials.