Abstract
Bone has the intrinsic capacity to regenerate itself, as long as the damage is small, through the sequential stimulation of specific phases, such as angiogenesis followed by osteogenesis. However, when the damage is extensive it is unable to regenerate and bone tissue engineering is used as an alternative. In this study, we developed a platform to allow the triple ion delivery with sequential delivery capacity to potentially stimulate antibacterial, angiogenic and osteogenic processes. The scaffold-based platform consisted of alginate/hydroxyapatite (HA) microparticles embedded in alginate fibers. Firstly, microparticles were developed using different ratios of alginate:HA using the spraying method, resulting in a high reproducibility of the technique. Microparticle size between 100–300 µm and ratio 1:40 resulted in a more spherical morphology and were selected for their incorporation into alginate fiber. Different amounts of copper and cobalt were added with the microparticles and alginate fiber, respectively, were used as model ions which could eventually modulate and mimic antimicrobial and angiogenic processes. Moreover, calcium ion was also incorporated in both, in order to provide the system with potential osteogenic properties together with HA. The multiple delivery of copper, cobalt and calcium released were in the therapeutic range as measured by induced coupled plasma (ICP), providing a promising delivery strategy for tissue engineering.
Highlights
The aim of this study is to develop a scaffold-based platform to allow multiple ion delivery and find different release patterns for future applications in bone regeneration
We aimed to develop a multiple ion delivery system platform to be used to allow the delivery of several cues from scaffold-based biomaterials
As a proof of concept, we introduced three therapeutic ions, used as model ions, within the ion delivery system to study if the material design was appropriate to control and deliver those ions
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Bone tissue has the ability of self-regeneration in response to small size damage, it is unable to regenerate tissue damage with a size higher than 2.5 cm [1]. In this last case, clinical intervention using autologous or allogeneic bone grafts have been the gold standard treatment for a long time, they possess some disadvantages such as availability of the graft, possible immune response and possible risk of disease transmission [2,3]. The development of synthetic grafts for bone tissue engineering (BTE)
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