Electrophotographic 3D printing of pharmaceutical films

Kopp SP, Medvedev V, Tangermann-Gerk K, Wöltinger N, Rothfelder R, Graßl F, Heinrich M, Januskaite P, Goyanes A, Basit AW, Roth S, Schmidt M (2023)

Publication Type: Journal article

Publication year: 2023

Journal

Additive Manufacturing Elsevier

Article Number: 103707

DOI: 10.1016/j.addma.2023.103707

Abstract

The usage of three-dimensional (3D) printing in pharmaceutical applications offers significant advantages compared to conventional manufacturing approaches such as tableting or encapsulation. Laser sintering (LS), also referred to as powder bed fusion – laser beam (PBF-LB), formerly also known as selective laser sintering (SLS), offers the production of pharmaceuticals directly from a powder mixture with high geometrical flexibility and adjustable release profiles. However, due to limitations of conventional powder application methods for PBF-LB, neither the material composition nor the material distribution can be tailored within a printed layer. To overcome these restrictions, electrophotographic powder application (EPA), a novel method for selective powder application, was utilized in this study. EPA allows the deposited layer thickness to be reduced to values between 12 and 76 µm, depending on the used pharmaceutical powder blend. Thus, the laser energy input required for interlayer connection can be reduced, enabling the use of a CO2 laser. In this study, for the first time, EPA in combination with powder bed fusion – laser beam of polymers (EPA-PBF-LB/P) was utilized to successfully deposit and print three different model drugs: paracetamol, nicotinamide, and caffeine, mixed with Eudragit L 100–55, a pharmaceutical grade polymer. Through the use of EPA, thin layers of powder blends were successfully deposited in the build chamber, leading to no thermal degradation of the polymer or drugs from the use of a CO2 laser. Single- and multi-material pharmaceutical films were successfully printed via EPA-PBF-LB, utilizing EPA to selectively as well as precisely apply different powders within a single layer into the build chamber. This introduces a novel method of printing pharmaceuticals using SLS with a CO2 laser and without the use of additional colorants.

Authors with CRIS profile

Sebastian-Paul Kopp Lehrstuhl für Photonische Technologien Vadim Medvedev Lehrstuhl für Photonische Technologien Richard Rothfelder Sonderforschungsbereich 814/3 Additive Fertigung Fabian Graßl Lehrstuhl für Pharmazeutische Chemie Markus Heinrich Professur für Pharmazeutische Chemie Michael Schmidt Lehrstuhl für Photonische Technologien

Additional Organisation(s)

Erlangen Graduate School in Advanced Optical Technologies Lehrstuhl für Photonische Technologien Sonderforschungsbereich 814/3 Additive Fertigung

Related research project(s)

Efficient additive manufacturing of multi-material parts (B6) (SFB 814 (B6)) CRC 814 - Additive Manufacturing (SFB 814) July 1, 2011 - June 30, 2023

Involved external institutions

FabRx Ltd. GB United Kingdom (GB) Universidade de Santiago Compostela (USC) ES Spain (ES) University College London (UCL) GB United Kingdom (GB) Bayerisches Laserzentrum gemeinnützige Forschungsgesellschaft mbH (BLZ) DE Germany (DE)

How to cite

APA:

Kopp, S.-P., Medvedev, V., Tangermann-Gerk, K., Wöltinger, N., Rothfelder, R., Graßl, F.,... Schmidt, M. (2023). Electrophotographic 3D printing of pharmaceutical films. Additive Manufacturing. https://dx.doi.org/10.1016/j.addma.2023.103707

MLA:

Kopp, Sebastian-Paul, et al. "Electrophotographic 3D printing of pharmaceutical films." Additive Manufacturing (2023).

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