Background/Objectives: Amorphous solid dispersions (ASDs) produced via hot-melt extrusion (HME) and fused deposition modeling (FDM) 3D printing represent a promising strategy for improving the performance of poorly water-soluble drugs. However, the integrated HME-FDM workflow is inherently energy-intensive, and sustainability considerations are rarely incorporated into formulation and process optimization. The present study aimed to develop and optimize indomethacin (IND) ASDs using a systematic Design of Experiment (DoE) framework that integrates electrical energy consumption as a quantitative response alongside pharmaceutical performance attributes. Methods: Polymer–plasticizer miscibility was screened using hot-stage microscopy, followed by filament preparation via HME. A factorial DoE was applied to optimize drug loading and extrusion temperature considering electrical energy consumption, extrusion yield, encapsulation efficiency, and residual crystallinity. Solid-state characterization was performed using DSC and XRD. The optimized filament was subsequently subjected to geometry screening and a second DoE to optimize platform temperature, nozzle temperature, and printing speed with respect to printing time, electrical energy consumption, and drug assay. Results: Complete drug amorphization was achieved within a defined thermal window, with residual crystallinity governed by kinetic dissolution constraints at lower extrusion temperatures. Electrical energy demand during both HME and FDM was strongly influenced by thermal setpoints and process duration. Multi-response overlay analysis identified sustainability-oriented operating windows for both stages. Experimental validation confirmed close agreement between predicted and observed responses, demonstrating simultaneous reduction in electrical demand and maintenance of dose accuracy and solid-state stability. Conclusions: This study demonstrates that electrical energy consumption can be systematically embedded as a quantitative design variable in pharmaceutical process optimization. The proposed dual-stage DoE strategy establishes a rational framework for developing 3D-printed ASD dosage forms that balance molecular performance and environmental efficiency.
Pantazos et al. (Wed,) studied this question.