Mechanical Performance of 3D-Printed Biocompatible Polycarbonate for Biomechanical Applications

Additive manufacturing has experienced remarkable growth in recent years due to the customisation, precision, and cost savings compared to conventional manufacturing techniques. In parallel, materials with great potential have been developed, such as PC-ISO polycarbonate, which has biocompatibility certifications for use in the biomedical industry. However, many of these synthetic materials are not capable of meeting the mechanical stresses to which the biological structure of the human body is naturally subjected. In this study, an exhaustive characterisation of the PC-ISO was carried out, including an investigation on the influence of the printing parameters by fused filament fabrication on its mechanical behaviour. It was found that the effect of the combination of the printing parameters does not have a notable impact on the mass, cost, and manufacturing time of the specimens; however, it is relevant when determining the tensile, bending, shear, impact, and fatigue strengths. The best combinations for its application in biomechanics are proposed, and the need to combine PC-ISO with other materials to achieve the necessary strengths for functioning as a bone scaffold is demonstrated.

Automated summary

Additive manufacturing has seen significant growth due to its customization, precision, and cost-effectiveness compared to traditional methods. New materials like PC-ISO polycarbonate have potential for use in the biomedical industry, but may not meet the mechanical stresses of the human body. This study provides a comprehensive characterization of PC-ISO and investigates how printing parameters affect its mechanical behavior, showing that parameter combinations are crucial for determining strength in various applications, including biomechanics where PC-ISO may need to be combined with other materials for bone scaffolds.