Delivery of letrozole-encapsulated niosomes via a 3D bioprinting gelatin–alginate scaffold for potential breast cancer treatment

Abstract 3D printing technology is a powerful tool in scaffold engineering for biomedical applications, especially in anticancer activities and drug delivery. The present study developed a 3D-printed gelatin–alginate scaffold incorporating letrozole-loaded niosomes (Let/Nio@Gel-AL-SC) as a more effective drug delivery system. The findings showed that the fabricated niosomes appeared spherical. 3D-printed scaffolds exhibited biodegradability and sustained drug-release properties. The drug release from the scaffold was less prominent under acidic conditions than physiological ones. Cytotoxicity analysis showed that the engineered Let/Nio@Gel-AL-SC scaffold exhibited significant cytotoxicity against MCF-7 cancer cells. Gene expression analysis demonstrated a significant decrease in the expression of BCL2, CCND1, MMP2, and CDK4 genes and a notable increase in the expression of BAX and P53 genes, as well as the activity of Caspase 3/7 enzyme following treatment with Let/Nio@Gel-AL-SC. In addition, flow cytometry analysis revealed that Let/Nio@Gel-AL-SC significantly reduced necrosis and dramatically increased apoptosis. Also, the Let/Nio@Gel-AL-SC formulation exhibited a significantly greater increase in ROS values. The incorporation of letrozole-loaded niosomes into 3D printing gelatin/alginate scaffold has enhanced the efficacy of anticancer therapy. This is demonstrated by the sustained release of drugs, which indicates a promising potential for effective anticancer activity. Consequently, this combination holds promise as a potential future cancer therapy strategy. Graphical abstract