Abstract
There has been substantial interest in research aimed at conductive carbon-based supports since the discovery that the electrical stimulus can have dramatic effect on cell behavior. Among these carbon-aerogels decorated with biocompatible polymers were suggested as future materials for tissue engineering. However, high reaction temperatures required for the synthesis of the aerogels tend to impair the stability of the polymeric networks. Herein, we report a synthetic route towards carbon-aerogel scaffolds decorated with biocompatible ceramic nanoparticles of tricalcium phosphate. The composites can be prepared at temperature as high as 1100 °C without significant effect on the morphology of the composite which is comparable with the original aerogel framework. Although the conductivity of the composites tends to decrease with the increasing ceramic content the measured conductivity values are similar to those previously reported on polymer-functionalized carbon-aerogels. The cell culture study revealed that the developed constructs support cell proliferation and provide good cell attachment suggesting them as potentially good candidates for tissue-engineering applications.
Highlights
The phenomenon that the electrical current can have a detrimental effect on differentiation and proliferation capacity of the cells has triggered recent research interest towards quest for biocompatible and conductive substrates[1,2,3,4]
We report the synthesis of β-tricalcium phosphate (β-TCP) carbon-aerogel composite material (Graphical Abstract)
The higher magnification images (Fig. 1D,E) confirm that the carbon aerogel sample consists of fibers with a diameter of ca. 8–10 μm, suggesting a porous material was prepared
Summary
The phenomenon that the electrical current can have a detrimental effect on differentiation and proliferation capacity of the cells has triggered recent research interest towards quest for biocompatible and conductive substrates[1,2,3,4]. We report the synthesis of β-tricalcium phosphate (β-TCP) carbon-aerogel composite material (Graphical Abstract). In order to reveal the potential of the obtained materials for tissue engineering applications, the cytotoxicity and the cell attachment studies were conducted.
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