Abstract
This work is focused on integrating nanotechnology with bone tissue engineering (BTE) to fabricate a bilayer scaffold with enhanced biological, physical and mechanical properties, using polycaprolactone (PCL) and gelatin (Gt) as the base nanofibrous layer, followed by the deposition of a bioactive glass (BG) nanofibrous layer via the electrospinning technique. Electrospun scaffolds were characterized using scanning electron microscopy (SEM), transmission electron microscopy (TEM) and Fourier transform infrared spectroscopy. Surface area and porosity were evaluated using the nitrogen adsorption method and mercury intrusion porosimetry. Moreover, scaffold swelling rate, degradation rate and in vitro bioactivity were examined in simulated body fluid (SBF) for up to 14 days. Mechanical properties of the prepared scaffolds were evaluated. Cell cytotoxicity was assessed using MRC-5 cells. Analyses showed successful formation of bead-free uniform fibers and the incorporation of BG nanoparticles within fibers. The bilayer scaffold showed enhanced surface area and total pore volume in comparison to the composite single layer scaffold. Moreover, a hydroxyapatite-like layer with a Ca/P molar ratio of 1.4 was formed after 14 days of immersion in SBF. Furthermore, its swelling and degradation rates were significantly higher than those of pure PCL scaffold. The bilayer’s tensile strength was four times higher than that of PCL/Gt scaffold with greatly enhanced elongation. Cytotoxicity test revealed the bilayer’s biocompatibility. Overall analyses showed that the incorporation of BG within a bilayer scaffold enhances the scaffold’s properties in comparison to those of a composite single layer scaffold, and offers potential avenues for development in the field of BTE.
Highlights
One of the main concerns that precede the placement of dental implants is an inadequacy of bone tissue at the implant site [1]
The addition of Gt to PCL led to a 20.2% increase in viscosity, while the addition of bioactive glass (BG) nanoparticles only led to 5% increase in viscosity
It is worth remarking that these nanostructures could not be seen in the transmission electron microscopy (TEM) images of the pure PCL nanofibers (Fig. 3a)
Summary
One of the main concerns that precede the placement of dental implants is an inadequacy of bone tissue at the implant site [1]. The quality of life of such patients is affected as a result of pain, disfigurement or loss of function. Journal of Materials Science: Materials in Medicine (2021) 32:111 good clinical outcomes, decreasing the risk of rejection that is commonly seen when using allografts; the ability to harvest large amounts of bone from patients is limited [3]. To overcome the drawbacks of traditional bone grafting materials, bone tissue engineering (BTE) was introduced, offering biodegradable scaffolds which could be fabricated from a wide variety of materials such as polymers, bioceramics, metals, etc. These scaffolds act as supporting structures for cell adhesion, infiltration, proliferation and differentiation [1]
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