Abstract

In recent years, the application of three-dimensional fabrication to fabricate customized porous scaffolds for cell culture has received much attention from the field of tissue engineering and plastic surgery. In this study, we applied a more publicly accessible 3D printer, Ultimaker 2+ with biodegradable polymer-polycaprolactone (PCL) to fabricate both three-dimensional bioscaffolds and auricular constructs (both solid and porous) prepared to fill the gap as potential solutions for both cartilage defects and microtia respectively by managing of the CAD-CAM workflow. As an overview, the modified CAD-CAM workflow was regarded as the uniform preparation fabricating types of scaffolds to identify the general printability of PCL with Ultimaker 2+. For bioscaffolds, limit test was performed on original scaffold, the resolution for printing scaffolds by PCL was identified as 600 microns by applying method of uniform scaling and limit approaching. For customized auricular constructs, we extract the model from MRI/CT scan and use its mirror image for the general shape of model building in a relatively customized way to fabricate solid auricular constructs. Boolean operation was then applied for fabricating the inner porous microstructure to fabricate porous auricular constructs. As there were no significant differences among three groups of filaments regarding the respective dimensions for both bioscaffolds (n=9 for each group: PCL, PLA and ABS) and customized auricular constructs(n=5 for both solid auricular constructs and porous auricular constructs) indicated by the P value(P>0.05) from ANOVA, The printing compatibility of PCL regarding each specific domain of scaffolds were identified. In Conclusion, our study had indicated a consistent CAD-CAM workflow for Ultimaker 2+ with PCL to fabricate three-dimensional bioscaffolds, solid auricular constructs and porous auricular constructs which could be potentially applied to fill the gap of cartilage engineering and microtia reconstruction through in-vitro cell culture, surgical simulation and in-situ cell culture respectively.