Abstract

Abstract

3D printing of synthetic scaffolds mimicking natural bone chemical composition, structure, and mechanical properties is a promising approach for repairing bone injuries. Direct ink writing (DIW), a type of 3D printing, confers compatibility with a wide range of materials without exposing these materials to extreme heat. Optimizing ink properties such as filament formation capabilities, shear-thinning, and high storage modulus recovery would improve DIW fabrication characteristics. In this study, composite inks based on biodegradable polycaprolactone (PCL), reinforced with nano-hydroxyapatite (HAp), and loaded with vancomycin were designed and evaluated for their rheological properties, wettability, mechanical properties, and antimicrobial properties. The formulated composite inks displayed a shear-thinning behaviour exhibited storage modulus recovery percentages above 80% for all formulations, which is essential for extrusion deposition by DIW at room temperature. Ink formulations were able to form fully interconnected lattice scaffolds with porosities ranging from 42% to 65%. Increasing the HAp concentrations from 55% to 85% w/w increased the shear thinning behaviour and reduced the printed filament width to more closely match the nozzle diameter; this indicates higher HAp proportion reduces ink shrinkage. The scaffold had high wettability at HAp proportions above 65% w/w and the compressive elastic modulus of DIW printed scaffolds exhibited within the range of trabecular bone. Antimicrobial activity was apparent from the agar diffusion assay; zones of inhibition ranging from 15.82 ± 0.25 mm and 20.06 ± 0.25 mm were observed after 24 hr for composite scaffolds loaded with 3% and 9% w/w vancomycin respectively. Vancomycin-loaded PCL/HAp composite inks were developed, displaying good printability, wettability, mechanical properties, and antimicrobial properties, making them an attractive choice for bone repair and regeneration.