Development of immediate release tablet formulations of lornoxicam with hot melt extrusion-based three-dimensional printing technology.

Abstract

Introduction: This study aims to develop immediate release tablet formulations of lornoxicam (LRX) using hot melt extrusion (HME)-based fused deposition modeling (FDM) focusing on the adjustment of drug release by arranging infill densities and evaluating microcrystalline cellulose II (MCC II) as a disintegrating agent for HME-FDM purposes. LRX is a poorly soluble drug that exhibits pH-dependent solubility with a high thermal degradation temperature. These characteristics make it an ideal model drug for the HME-based FDM technique.

Methods: Various filament formulations were extruded using an extruder, and suitable filaments were used to produce 3D-printed tablets. Filaments and tablets were characterized. Dissolution studies were performed on tablets with different infill densities. DSC, FTIR, XRD, and SEM analyses were conducted.

Results: Although the solubility of LRX increases with pH, disintegrating agents such as MCC II had a more significant effect on the dissolution of LRX than sodium bicarbonate, which was used as the alkalinizing pore-forming agent. Dissolution studies revealed that the dissolution of LRX was enhanced by tablet erosion. Tablet erosion increased as the infill density decreased, and an immediate release profile was reached with tablets having 25% infill density. Despite the availability of conventional immediate release LRX tablets, this newly developed formulation offers the potential to be modulated for personalized therapy via the 3D printing technique.

Conclusion: This study demonstrates the feasibility of HME-based FDM printing technology for producing immediate-release LRX tablets with consistent quality, highlighting the utilization of MCC II as a disintegrating agent that enhances LRX dissolution in this process.