Development of a Simple Mechanical Screening Method for Predicting the Feedability of a Pharmaceutical FDM 3D Printing Filament

Nasereddin, Jehad; Wellner, Nikolaus; Alhijjaj, Muqdad; Belton, Peter; Qi, Sheng

doi:10.1007/s11095-018-2432-3

Cited by 123 publications

(92 citation statements)

References 17 publications

(21 reference statements)

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“…In order for a filament to be compatible with the FDM 3D printing process, it requires critical mechanical and rheological criteria [15]. Previous studies have linked a filament's 3D printing compatibility with the rheological properties of the backbone polymers: poly methacrylate [8], PVA [16] and PVP-VA [16,17].…”

Section: Among Other Commercially Available Technologies Fused Deposmentioning

confidence: 99%

3D printed oral theophylline doses with innovative ‘radiator-like’ design: Impact of polyethylene oxide (PEO) molecular weight

Isreb

Baj

Wojsz

et al. 2019

International Journal of Pharmaceutics

135

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Despite the abundant use of polyethylene oxides (PEOs) and their integration as an excipient in numerous pharmaceutical products, there have been no previous reports of applying this important thermoplastic polymer species alone to fused deposition modelling (FDM) 3D printing. In this work, we have investigated the manufacture of oral doses via FDM 3D printing by employing PEOs as a backbone polymer in combination with polyethylene glycol (PEG). Blends of PEO (molecular weight 100K, 200K, 300K, 600K or 900K) with PEG 6K (plasticiser) and a model drug (theophylline) were hot-melt extruded. The resultant filaments were used as a feed for FDM 3D printer to fabricate oral dosage forms (ODFs) with innovative designs. ODFs were designed in a radiator-like geometry with connected paralleled plates and inter-plate spacing of either 0.5, 1, 1.5 or 2 mm. X-ray diffraction patterns of the filaments revealed the presence of two distinctive peaks at 2θ = 7° and 12°, which can be correlated to the diffraction pattern of theophylline crystals. Varying blends of PEO and PEG allowed the formation of mechanically resistant filaments (maximum load at break of 357, 608, 649, 882, 781 N for filament produced with PEO 100K, 200K, 300K, 600K or 900K, respectively). Filaments of PEO at a molecular weight of 200-600K were compatible with FDM 3D printing process. Further increase in PEO molecular weight resulted in elevated shear viscosity (>10 4 Pa.S) at the printing temperature and hindered material flow during FDM 3D printing process. A minimal spacing (1 mm) between parallel plates of the radiator-like design deemed essential to boost drug release from the structure. This is the first report of utilising this widely used biodegradable polymer species (PEOs and PEG) in FDM 3D printing.

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Section: Among Other Commercially Available Technologies Fused Deposmentioning

confidence: 99%

3D printed oral theophylline doses with innovative ‘radiator-like’ design: Impact of polyethylene oxide (PEO) molecular weight

Isreb

Baj

Wojsz

et al. 2019

International Journal of Pharmaceutics

135

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“…In contrast, when the filament is too brittle, it is broken by the feeding gear. 21,22) In this study, when the content of PVP was low, the filament was too soft, and when the content of PVP was high, it was too brittle to fabricate using FDM 3D printer. When the filaments contained drug and polymers above mentioned compounding ratio (20% ITZ, 65% HPC, 15% PVP), they were feedable and used for further study.…”

Section: Methodsmentioning

confidence: 84%

Fabrication of Zero-Order Sustained-Release Floating Tablets <i>via</i> Fused Depositing Modeling 3D Printer

et al. 2019

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A three-dimensional (3D) printer is a powerful tool that can be used to enhance personalized medicine. A fused deposition modeling (FDM) 3D printer can fabricate 3D objects with different internal structures that provides the opportunity to introduce one or more specific functionalities. In this study, zero-order sustained-release floating tablet was fabricated using FDM 3D printer. Filaments comprising poorly watersoluble weak base drug, itraconazole (ITZ) and polymers (hydroxypropyl cellulose and polyvinylpyrrolidone) were prepared, and tablets with a hollow structure and different outside shell thicknesses were fabricated. In the 3D printed tablets, ITZ existed as an amorphous state and its solubility improved markedly. As the outside shell thickness of the tablet increased, drug release was delayed and floating time was prolonged. In the tablets with 0.5 mm of the upper and bottom layer thickness and 1.5 mm of the side layer thickness, holes were not formed in the tablets during the dissolution test, and the tablets floated for a long period (540 min) and showed nearly zero-order drug release for 720 min. These findings may be useful for improving the bioavailability of several drugs by effective absorption from the upper small intestine, with floating gastric retention system.

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“…Furthermore, the production of custom-made filaments introduces a more complex step to the relatively easy 3D printing process, requiring several optimisation studies to assess properties such as stiffness, toughness, melt viscosity and moisture uptake, usually altered by high drug loading [52,54]; filaments with unsuited mechanical properties can cause nozzle blockage and, therefore, printing failures [55].…”

Section: Fused Deposition Modellingmentioning

confidence: 99%

Current formulation approaches in design and development of solid oral dosage forms through three-dimensional printing

2020

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printing technologies are continuously applied to novel fields, laying the foundations for a new industrial revolution. With regard to pharmaceutical sciences, 3D printed drug products are emerging as attractive and innovative tools in personalised medicine. For example, solid oral dosage forms (e.g. tablets) can be printed in a wide range of dosages, release profiles, geometries and sizes by simply modifying a digital model, thus providing patients with tailored therapies. Various 3D printing technologies have been applied to pharmaceutical manufacture in recent years, and different materials have been investigated to fabricate solid oral dosage forms in a broad range of properties. Therefore, the aim of this review is to describe the state of the art of 3D printing oral pharmaceuticals, with the view to provide formulation scientists with essential information to approach the development of 3D printed drug products, from digital design to final product quality control. Short-to long-term potential areas of application of 3D printed drug products and their relative regulatory pathway challenges are also presented.

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Development of a Simple Mechanical Screening Method for Predicting the Feedability of a Pharmaceutical FDM 3D Printing Filament

Cited by 123 publications

References 17 publications

3D printed oral theophylline doses with innovative ‘radiator-like’ design: Impact of polyethylene oxide (PEO) molecular weight

3D printed oral theophylline doses with innovative ‘radiator-like’ design: Impact of polyethylene oxide (PEO) molecular weight

Fabrication of Zero-Order Sustained-Release Floating Tablets <i>via</i> Fused Depositing Modeling 3D Printer

Current formulation approaches in design and development of solid oral dosage forms through three-dimensional printing

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