In spite of having excellent biocompatibility and osteogenic property of hydroxyapatite (HAp) and β-tricalcium phosphate (β-TCP), concerns have been raised regarding their degradation kinetics. Complete in vivo degradation of HAp takes years because of its slow degradation rate, and fast degradation rate of β-TCP limits its application. Biphasic calcium phosphates (BCPs) composed of both HAp and β-TCP have controlled degradation to some extent. Here, we have prepared three different BCPs composed of β-TCP and HAp. These BCP composites are successfully electrically polarized to generate surfaces with positive (P-poled) and negative (N-poled) charges. Thermally stimulated depolarized current measurement (TSDC) exhibits increased stored charge density with the increase in HAp percentage in the composites. Our study focuses on understanding the effect of composition variation as well as electrical polarization of these composites on early stage osteoblast-cell adhesion, proliferation, and extracellular matrix (ECM) formation capability. No matter what the composition is, N-poled (Negatively poled) surfaces show early stage osteoblast-cell adhesion, proliferation, and ECM formation when compared with U-poled (unpoled) and P-poled (positively poled) surfaces. Irrespective of the surface charge, an improved cell-material interactions are observed as the percentage of HAp content in the composites is increased. These electrically polarized BCP composites can have potential use in the area of orthopedics and dentistry.
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