Abstract
Calcium phosphate (CaP)-based ceramic–biopolymer composites can be regarded as innovative bioresorbable coatings for load-bearing implants that can promote the osseointegration process. The carbonated hydroxyapatite (cHAp) phase is the most suitable CaP form, since it has the highest similarity to the mineral phase in human bones. In this paper, we investigated the effect of wet chemical preparation parameters on the formation of different CaP phases and compared their morphological and structural characteristics. The results revealed that the shape and crystallinity of CaP particles were strongly dependent on the post-treatment methods, such as heat or alkaline treatment of as-precipitated powders. In the next step, the optimised cHAp particles have been embedded into two types of biopolymers, such as polyvinyl pyrrolidone (PVP) and cellulose acetate (CA). The pure polymer fibres and the cHAp–biopolymer composites were produced using a novel electrospinning technique. The SEM images showed the differences between the morphology and network of CA and PVP fibres as well as proved the successful attachment of cHAp particles. In both cases, the fibres were partially covered with cHAp clusters. The SEM measurements on samples after one week of immersion in PBS solution evidenced the biodegradability of the cHAp–biopolymer composites.
Highlights
Published: 25 November 2021It is crucial to ensure the long-term success of implanted materials in all orthopaedic surgeries
Morphological and Structural Characterisation of Calcium Phosphate (CaP) Powders Prepared with Different Parameters
The morphology of calcium phosphate particles prepared by wet chemical precipitation and different post-treatment were investigated and compared
Summary
Published: 25 November 2021It is crucial to ensure the long-term success of implanted materials in all orthopaedic surgeries. A high level of biocompatibility and bioactivity are required from the implants. The materials used in bone repair are made of metals with high mechanical strength and ductility [1,2]. There has been intensive research to increase the biocompatible characteristics of implants. This can be best achieved by applying appropriate calcium phosphate-based coatings on their surface. The properties and biological performance of coatings can be adjusted to meet the standard requirements of biomedical applications [4,5]. Once the bones are repaired, the in vivo degradation of coatings is favourable from both clinical and biomedical points of view
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