3D-Printed Medical Implants: Recent Trends and Challenges

Three-dimensional (3D)-printing, also known as additive manufacturing, has revolutionized various industries, including biomedical devices, by enabling the production of personalized implants tailored to individual patient anatomical variations. This review article provides an overview of the applications of 3D-Printed Medical Implants. By leveraging advanced imaging modalities and digital modeling software, clinicians can design and fabricate implants that ensure optimal fit, function, and biocompatibility for each patient. Additionally, 3D-printing has transformed cancer treatment as well as neurodegenerative disorders by facilitating the fabrication of patient-specific medical implants and devices used in surgical oncology, radiation therapy, and reconstructive surgery. These customized implants enhance treatment efficacy while minimizing adverse effects by precisely targeting cancerous tissues. Moreover, 3D-printing technology enables the development of 3D cell cultures, bridging the gap between traditional 2D cell cultures and in vivo models. This advancement enhances researchers' capabilities for studying cancer progression and evaluating responses to therapeutic interventions. Furthermore, 3D bioprinting shows promise as a therapeutic approach for neurological diseases, with preclinical studies demonstrating the efficacy of 3D-printed neural tissue scaffolds and implantable drug delivery platforms. Overall, 3D-printing holds significant potential in personalized medicine, offering innovative solutions to improve patient outcomes across various medical disciplines.