Abstract
The surface microstructures of calcium phosphate ceramics play an essential role in determining bone regeneration. However, it is difficult to produce micro/nano-structures on the surface of the porous hydroxyapatite (HA) scaffolds. In this study, we successfully developed and fabricated various micro/nano-structured surfaces on the HA scaffolds in copper ion (Cu2+)-containing solutions under hydrothermal conditions. The micro/nano-structures on the surface of the HA scaffolds were controlled by modulating the Cu2+ concentrations during the hydrothermal process. With an increase in the Cu2+ concentration, the surface morphology of the HA scaffolds changed significantly from sphere-like to flower-like, before becoming nano-structures. These findings indicated that the Cu2+ concentration affects the morphologies of calcium phosphate coatings that grow on the HA scaffolds. In vitro endothelial cell (EC) cultures showed that the cell proliferation was significantly enhanced when cultured on the flower-like morphology compared with other morphologies. Furthermore, an in vivo test in New Zealand rabbits demonstrated that the HA scaffold with the flower-like surface resulted in more angiogenesis compared with the control scaffold. This copper-assisted hydrothermal deposition process provides a simple and controllable route for engineering a micro/nano-structured surface on the HA scaffolds, which has benefits in terms of angiogenesis and bone regeneration.
Highlights
As the common mineral component of human bones, hydroxyapatite (HA, Ca10 (PO4 )6 (OH)2 )has been widely used in bone repair due to its excellent biocompatibility and bioactivity [1]
We investigated the formation of micro/nano-structures on the HA scaffolds under
We investigated the formation of micro/nano-structures on the HA scaffolds under hydrothermal hydrothermal conditions
Summary
As the common mineral component of human bones, hydroxyapatite (HA, Ca10 (PO4 ) (OH)2 )has been widely used in bone repair due to its excellent biocompatibility and bioactivity [1]. As the common mineral component of human bones, hydroxyapatite (HA, Ca10 (PO4 ) (OH) ). Many studies have shown that the surface properties of bone scaffolds are important for cell response and tissue formation [2]. The surface microstructure of calcium phosphate has been proven to affect cell attachment, proliferation and differentiation [3]. In addition to the hierarchical micro/nano-structure of bone, the mineral in human bone is not pure stoichiometric HA as it is partially substituted by elements, such as Na, K, Sr, Cu and F [4]. The substituted elements affect the physical structure of apatite, and strengthen its biological function [5]. Mimicking bone structures is a good choice for scaffold design
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