Influence of fused deposition modelling printing parameters on tablet disintegration times: a design of experiments study

Despite the importance of process parameters in the printing of solid dosage forms using fused deposition modelling (FDM) technology, the field is still poorly explored. A design of experiment study was conducted to understand the complete set of process parameters of a custom developed FDM 3D print...

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Bibliographic Details
Published in:Acta Pharmaceutica 2023-09, Vol.73 (3), p.405-422
Main Authors: Kreft, Klemen, Stanić, Tijana, Perhavec, Petra, Dreu, Rok, Lavrič, Zoran
Format: Article
Language:English
Subjects:
3D printed tablets
Deposition
Design
Design of experiments
Disintegration
disintegration time
Fused deposition modeling
fused deposition modelling
Height
Mathematical models
Nozzles
Printing
printing parameters
Process parameters
Redevelopment
Statistical models
Three dimensional printing
uniformity of mass
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Summary:Despite the importance of process parameters in the printing of solid dosage forms using fused deposition modelling (FDM) technology, the field is still poorly explored. A design of experiment study was conducted to understand the complete set of process parameters of a custom developed FDM 3D printer and their influence on tablet disintegration time. Nine settings in the Simplify 3D printing process design software were evaluated with further experimental investigation conducted on the influence of infill percentage, infill pattern, nozzle diameter, and layer height. The percentage of infill was identified as the most impactful parameter, as increasing it parabolically affected the increase of disintegration time. Furthermore, a larger nozzle diameter prolonged tablet disintegration, since thicker extruded strands are generated through wider nozzles during the printing process. Three infill patterns were selected for in-depth analysis, demonstrating the clear importance of the geometry of the internal structure to resist mechanical stress during the disintegration test. Lastly, layer height did not influence the disintegration time. A statistical model with accurate fit ( = 0.928) and predictability ( = 0.847) was created. In addition, only the infill pattern and layer height influenced both the uniformity of mass and uniformity of the disintegration time, which demonstrates the robustness of the printing process.
ISSN:1846-9558
1330-0075
1846-9558
DOI:10.2478/acph-2023-0026